The open science movement has expanded the uses of scientific output beyond specialized academic circles.
Non-academic audience of journals and other scientific outputs
has always been significant but was not recorded by the leading metrics
of scientific reception, which favor citation data. In the late 1990s,
the first open-access online publications started to attract a large
number of individual visits. This transformation has renewed the
theories of scientific dissemination, as direct access to publications
curtailed the classic model of scientific popularization. Social impact
and potential uses by lay readers have become focal points of discussion
in the development of open science platforms and infrastructures.
Analysis of open science uses has required the development of new methods, including log analysis, crosslinking analysis or altmetrics, as the standard bibliometric approach failed to record the non-academic reception of scientific productions.
In the 2010s, several detailed studies were devoted to the
reception of specific open science platforms due to the increasing
availability of use data. Log analysis and surveys showed that
professional academics do not make up the majority of the audience, as
recurrent reader profiles include students, non-academic professionals
(policy makers, industrial R&D, knowledge workers) and "private
citizens" with various motivations (personal health, curiosity, hobby).
Traffic on open science platforms is stimulated by a larger ecosystem of
knowledge sharing and popularization, which includes non-academic
productions like blogs. Non-academic audiences tend to prefer the use of
local language, which has created new incentives in favor of linguistic
diversity in science.
Concepts and definition
Bibliometrics and its limitations
After the Second World War,
the reception of scientific publications has been increasingly measured
by quantitative counts of citations. The field of bibliometrics
coalesced in parallel to the development of the first computed search
engine, the Science Citation Index, originally established by Eugene Garfield in 1962. Founding figures of the field, like the British historian of science Derek John de Solla Price, were proponents of bibliometric reductionism, i.e., the reduction of all possible bibliometric indicators to citation
data and citation graphs. Bibliometric indicators, like the Impact Factor, have had a significant influence over research policy and research evaluation since the 1970s.
Academic search engine, citation data collection and the related
metrics were intentionally designed to favor English-speaking journals. Until the development of open science platforms, "very little [was]
actually known about the impact of Latin American journals overall". The use of standard bibliometric indicators like the impact factor
yielded a very limited outlook on the breadth and diversity of the academic publishing
ecosystem in this region and other non-Western areas: "Putting aside
issues of equity, the underrepresentation and shear low number of
journals from developing countries mean that journals that are geared
towards the developing world will have less of its citations counted
than one geared towards journals that are in the dataset."
In the early developments, the open science movement partly
coopted the standard tools of bibliometrics and quantitative evaluation:
"the fact that no reference was made to metadata in the main OA
declarations (Budapest, Berlin, Bethesda) has led to a paradoxical
situation (…) it was through the use of the Web of Science that OA
advocates were eager to show how much accessibility led to a citation
advantage compared to paywalled articles." After 2000, an important bibliometric literature was devoted to the citation advantage of open access publications.
By the end of the 2000s, the impact factor and other metrics had been increasingly held responsible for a systemic lock-in of prestigious non-accessible sources. Key figures of the open science movement, such as Stevan Harnad,
called for the creation of "open access scientometrics" that would take
"advantage of the wealth of usage and impact metrics enabled by the
multiplication of online, full-text, open access digital archives." As the public of open science expanded beyond academic circles, new
metrics should aim for "measuring the broader societal impacts of
scientific research."
Non-academic audience
Academic journals have always had a significant non-academic
audience, be they students, professionals, or amateurs. In 2000,
one-third of these readers had never authored a scientific publication. This rate may be higher for social science journals, which may also act
as intellectual periodicals. During the second half of the 20th
century, the non-academic audience may have continuously expanded in Western countries,
along with the increasing prevalence of high school education: "the
percentage of U.S. adults with a minimal level of understanding of the
meaning of scientific study has increased from 12 percent in 1957 to 21
percent in 1999".
The prevalence of non-academic audience raises additional issues
on the relevance and scope of classic bibliometric measures, as they
would "never appear in citation data". The infrastructures and business models put in place by leading
scientific publishers do not consider non-academic uses. Following the periodical crisis
of the 1980s and the inflation of subscription prices, major journals
have largely become unattainable for lay readers or independent
researchers not affiliated with a large research institution. Search
engines and bibliographic databases developed since the 1960s and the
1970s were meant to be used by professional librarians. Leading
scientific publishers tacitly rely on a "gap" model of scientific
reception, where specialized scientific knowledge is not directly
accessible but mediated and popularized.
The shift of academic journals to electronic publishing
and open access has underlined the significant discrepancy between the
measures of citation counts. By the late 1990s, online journals and
archive repositories had evidently attracted a very large audience:
"Within individual disciplines the change has been nearly instantaneous.
As an example, in mid-1997 the number of papers downloaded from
astronomy's digital library, the Smithsonian/NASA Astrophysics Data System (ADS; ads.harvard.edu) exceeded the sum of all the papers read in all of astronomy's print libraries". Log studies have regularly underlined that publication of open access
has a much higher rate of use and downloading than publications behind a
paywall.
The enlargement of the audience of scientific work to
non-academic has always been a key objective of the open access
movement: "even the earliest formulations of the concept of open access
included the general public as a potential audience for open access". The Budapest Open Access Initiative of 2001 includes among the beneficiaries of open access "scientists, scholars, teachers, students, and other curious minds".
In an open science context, non-academic audience has been associated with a wider figure: the lay reader or unexpected reader. Once universally accessible, an academic work can have unplanned readers or users. In 2006, John Willinsky
conjectured that "it is not difficult to imagine occasions when a
dedicated history teacher, an especially keen high school student, an
amateur astronomer, or an ecologically concerned citizen might welcome
the opportunity to browse the current and relevant literature pertaining
to their interests." Unexpected forms of reception did happen as the Editor in chief of PLOS
once received a promising research on the modelling of pandemics, which
turned out to be written by "a fifteen-year old high school student". The lay reader is not necessarily part of a non-academic audience, as a
professional scientist may become one if "the information sought is
outside his or her area of expertise". Not all unexpected readers behave similarly or have the same capacity
of using academic resources. Even where they are not dealing with their
main domain of expertise, academic researchers or some professionals
(the knowledge workers) have acquired some generic skills for bibliographic analysis, such as following citations in the literature.
Unanticipated academic uses
Paywalled journals did not satisfy a larger range of unanticipated
academic uses, as the costs of subscription access have been conditioned
on the field of work or the available resources at the institutional
level. In 2011, Michael Carroll introduced a typology of five
"unanticipated readers" which are beyond the scope of the reading
expectations of online academic journals: serendipitous readers (who discover the publication through complex reading paths), the under-resourced readers (presumably uninitiated, like high school students) interdisciplinary readers (scientists that belong to a different field) international readers (scientist that work within a different national frame) and machine readers (bots that retrieve a corpus, for instance as part of a text mining project).
The development of academic pirate platforms like Sci-Hub or Libgen
highlighted structural inequalities on a global scale: "The geography
of Sci-Hub usage generally looks like a map of scientific productivity,
but with some of the richer and poorer science-focused nations flipped." High rates of sci-hub use have been especially found in Russia,
Algeria, Brazil, Turkey, Mexico and India, which are all countries with
significant local academic productions despite having fewer resources
than OECD
countries: "relatively to their national scientific production,
middle-income countries had the more intensive use of pirated academic
works". The audience of pirate academic platforms remains significant even in
North American and European universities endowed with large library
subscriptions, as access is commonly perceived as more straightforward
than in paywalled libraries: "even for journals to which the university
has access, Sci-Hub is becoming the go-to resource".
From impact factor to social impact
The development of large open science platforms and infrastructure
after 2010 entailed a shift in the measurement of scientific impact,
from a strong focus on highly quoted English-speaking journals to an
expanded analysis of the social circulation of scientific publications.
This transformation has been especially noticeable in Latin America, due
to the early development of public-funded international publishing
platforms like Redalyc, or Scielo:
"There is a definite sense in Latin America that the investment in
science will result in development in a more broadly defined
sense—beyond simply innovation and economic growth."
In 2015, Juan Pablo Alperin introduced a systematic measure of
social impact by relying on a diverse set of indicators (log analysis,
survey and altmetrics). This approach entailed a conceptual redefinition
of key concepts of scientific reception, such as impact, reach or reader:
I turn our attention to these
alternative, public forms of research impact and reach by examining the
Latin American case. In this study, impact will be assessed
through evidence of the research literature being saved, discussed,
forwarded, recommended, mentioned, or cited, both within and beyond the
academic community (…) Reach refers, in this study, to the extent
to which the research literature is viewed or downloaded by members of
various audiences, beginning with the traditional academic readership
and extending outward through related professions, and perhaps
journalists, teachers, enthusiasts, and members of the public (…) By
looking at a broad range of indicators of impact and reach, far beyond
the typical measures of one article citing another, I argue, it is
possible to gain a sense of the people that are using Latin American
research, thereby opening the door for others to see the ways in which
it has touched those individuals and communities.
The unprecedented focus on the social impact of science fits with
alternative models of scientific popularization. In 2009, Alesia Zuccala
introduced a radiant model of open science dissemination with a
variety of mediated and unmediated connections between non-academic
audience and academic production: "Sometimes [research] engages the lay
public—this is the co-production model of science communication—and
sometimes self-selected intermediaries tell members of the public what
they should know—the education model of science communication".
Methods
While open science has been largely theorized to have a significant
impact on academic and non-academic access to literature, research
investigation in this area has proven challenging: it has "the subject
of many discussions and indeed was the basis for a lot of the advocacy
work and many funding agencies' OA policies, but rarely so in formal
published studies" By definition, open science productions are non-transactional and as
such their use leave much less traces than the distribution of
commercialized scientific outputs. Overall, it is very difficult to retrieve "data on user demographics
from currently available information sources (e.g., repositories and
publisher platforms)".
The classic methods of bibliometric studies, including citation analysis,
are largely unable to capture the new forms of reception created by
open science. Alternative approaches had to be developed in the 2000s
and the 2010s, and for a long time, open science advocates and
policy-makers had to rely on limited evidence.
Survey
Surveys have been the primary method of analyzing scientific reception before the development of bibliometrics.
After the development of electronic publishing and open access, survey methods have also migrated online. Pop-up
surveys were introduced for academic publications in the early 2000s:
they made it possible to query the user at the exact moment when the
resource was retrieved and could be correlated with log data. Yet, "response rates of pop-up surveys tend to be low", which may ultimately distort the representativeness of the survey.
Since 2002, large international surveys of the uses of academic
resources have been conducted by Simon Inger and Tracy Gardner with the
support of several major scientific organizations and publishers. While not specifically focused on open science, the survey strived to
include a more diverse subset of potential users beyond academic
authors.
Log Analysis
Academic publications have been among the earliest corpora used for
log analysis. The first applied studies in the area long predate the
web, as interconnected scientific infrastructures were already widely
used in North America and Europe by the 1970s and 1980s.
In 1983, several studies, pioneered by the Online Computer Library Center, analyzed "transaction logs" left by database users. Logs were stored on magnetic tapes at the time, and a large part of the
analysis was devoted to the reformatting and standardization of the
data. Standard methods of log analysis were already implemented in these
early studies, such as the use of probabilistic approaches based on
Markov Chains, in order to identify the more regular patterns of user
behavior or the comparison with more user surveys.
The use of logs and other reader metrics to measure the reception
of academic work has remained marginal. Large commercial databases,
like the Web of Science and Scopus,
had no incentives to divulge reading statistics and mostly use them for
internal purposes. Bibliometric indices based on aggregated citation
counts, like the impact factor or the h-index, have been favored as the leading measures of academic impact.
Beyond the restrictions imposed by leading publishers, log
analysis has raised significant methodological issues. Data logging
processes differ significantly depending on the structure of the
interface: "The number of full-text downloads may be artificially
inflated when publishers require users to view HTML versions before
accessing PDF versions or when linking mechanisms". Automated access, including search engine indexers or robots, can also
largely distort aggregated visit counts. This uncertainty impedes the
comparability of data: "issues such as journal interfaces continue to
affect how users interact with content users, making even standardized
reports difficult, if not impossible, to compare."
Log analysis has been revived in the 2010s due to technological
developments and the emergence of large open science platforms.
Standards for the retrieval of academic log data have been introduced in
the early 2010s, such as COUNTER, PIRUS or MESUR. These standards were, by design, limited to specialized research use due to their integration into academic infrastructures.
The development of open-source web analytics software like Matomo
has established an emerging standard for log collection. During the
same period, publicly funded scientific platforms have started to share
use data openly, as part of their enlarged commitment to open science.
In Latin America, both Redalyc and SciELO "provide such usage statistics
to the public", although they have remained largely underused: "It is
surprising that given the availability of these data, nobody has
conducted a study analyzing different dimensions of downloads, beyond
the overall view counts and "top 10" lists of articles available from
time to time on the respective Web portals."
In 2011, Michael J. Kurtz and Johan Bollen called for the development of usage bibliometrics, an emerging field that "provides unique opportunities to address the known shortcomings of citation analysis". Increased access to log data from open science platforms has made it
possible to publish extensive case studies on SciELO and Redalyc, Érudit, OpenEdition.org, Journal.fi or The Conversation
Crosslinking
The web itself and some of its key components (such as search
engines) were partly a product of bibliometrics theory. In its original
form, it was derived from a bibliographic scientific infrastructure
commissioned to Tim Berners-Lee by the CERN for the specific needs of high energy physics, ENQUIRE. The onset of the World Wide Web
in the mid-1990s made Garfield's citationist dream more likely to come
true. In the world network of hypertexts, not only is the bibliographic
reference one of the possible forms taken by a hyperlink inside the
electronic version of a scientific article, but the Web itself also
exhibits a citation structure, links between web pages being formally
similar to bibliographic citations." Consequently, bibliometrics concepts have been incorporated in major
communication technologies the search algorithm of Google: "the
citation-driven concept of relevance applied to the network of
hyperlinks between web pages would revolutionize the way Web search
engines let users quickly pick useful materials out of the anarchical
universe of digital information."
While the web immediately affected reading practices, by creating
seamless connections between texts, it did not transform to a similar
extent the quantitative analysis of citation data, which remained mostly
focused on academic connections. Global analysis of hyperlinking and
backlinks makes it possible to extend the citation analysis beyond
scholarly publications and recover the expanding scope of open science
circulations: "We have witnessed a proliferation of means of
disseminating scholarly publications via academic blogs, scientific
magazines destined to a wider audience." In 2011, a log analysis of the Kyoto University website identified a
highly diversified set of links to scientific publications. In 2019, a study supported by the Aix-Marseille University of crosslinkings to the French open science platform OpenEdition
highlighted that "scientific literature from a largely open access
hosting platform is re-appropriated and repurposed for various uses in
the public arena."
Altmetrics
During the 2000s and 2010s, the web was increasingly dominated by
very large social media platforms that curate and shape a significant
part of the digital public sphere. The public reception of scientific literature has also largely migrated
to these platforms. This evolution has prompted the development of new
metrics and quantitative methods aiming to map the circulation of
publications on social media: the altmetrics.
The concept of alt-metrics was introduced in 2009 by Cameron Neylon and Shirly Wu as article-level metrics. In contrast with the focus of leading metrics on journals (impact
factor) or, more recently, on individual researchers (h-index), the
article-level metrics makes it possible to track the circulation of
individual publications: "article that used to live on a shelf now lives
in Mendeley, CiteULike, or Zotero – where we can see and count it" As such they are more compatible with the diversity of publication
strategies that has characterized open science: preprints, reports or
even non-textual outputs like dataset or software may also have
associated metrics. In their original research proposition, Neylon and Wu favored the use of data from reference management software like Zotero or Mendeley. The concept of altmetrics evolved and came to cover data extracted "from social media applications, like blogs, Twitter, ResearchGate and Mendeley." Social media sources proved especially to be more reliable on a
long-term basis, as specialized academic tools like Mendeley came to be
integrated into a proprietary ecosystem developed by leading scientific
publishers. Major altmetrics indicators that emerged in the 2010s
include Altmetric.com, PLUMx and ImpactStory.
As the meaning of altmetrics shifted, the debate over the
positive impact of the metrics evolved toward their redefinition in an
open science ecosystem: "Discussions on the misuse of metrics and their
interpretation put metrics themselves in the center of open science
practices." Social media altmetrics are limited to a specific subset of social
media platforms and, within the platforms, to numeric metrics of
reception let by users such as likes, shares or comments: "However,
'altmetrics' has continued in the same tradition as the older
biblio/scientometrics by basing its indicators on numerical trace, i.e.,
computing the number of likes, posts, downloads, tweets or retweets a
scholarly publication gets on the web with the result that neither of
these fields provide information on the actual use of the scholarly
publications cited nor the reasons for which they were cited."
While altmetrics were initially conceived for open science
publications and their expanded circulation beyond academic circles,
their compatibility with the emerging requirements for open metrics has
been brought into question: social network data, in particular, is far
from transparent and readily accessible. The conversation tracked on social media may not be that representative
of the social impact of research, as researchers are overly represented
in these spaces: "about half of the tweets mentioning journal articles
are from academics". In 2016, Ulrich Herb
published a systematic assessment of the leading publications' metrics
in regard to open science principles and concluded that "neither
citation-based impact metrics nor alternative metrics can be labeled
open metrics. They all lack scientific foundation, transparency and
verifiability."
Current uses
Most empirical information retrieved on open science use is platform-specific.
User demographics
Distribution of the user demographics of SciELO in the survey of Juan Pablo Alperin
Studies of the use of open science resources have generally
highlighted the diversity of user profiles, with academic researchers
only representing a minor segment of the audience. In 2015, the two leading Latin American platforms, Redalyc and SciELO,
had mostly an audience of university students (with 50% and 55%
respectively) and professionals in non-academic sectors (20% in SciELO
and 17% in Redalyc). Once discounted from other university employees, "researchers only make up 5–6% of the total users". On the Finnish platform journal.fi,
students are also the main demographic group (with 40% of users), but
academic researchers still make up for a large group (36%).
Convergent estimations of lay readers have been given by the
different open science platform studies: 9% of amateur/personal uses in
SciELO and 6% in Redalyc, 8% of "private citizens" in the reader survey of journal.fi.
Open science platforms have a balanced gender distribution. The
two Latin American platforms, Redalyc and Scielo, tend to have a
relative "predominance of women users" (about 60%).
The discipline of the resources' impact has a varying impact on
uses. Personal interest is more prevalent in the humanities in SciELO. In contrast, "little variability between disciplines" has been observed in Redalyc. Analysis of the bookmark data left by the readers of F1000Prime on Mendeley highlighted a significant share of uses by disciplines totally distinct from the expected audience.
User practices and motivations
Studies of user practices have mostly focused on specific user
profiles. Few general surveys have been undertaken. In Japan, a 2011
poll of 800 adults showed that a "majority of respondents (55%) claimed
that Open Access is useful or slightly useful to them", which suggests a rather large awareness of open science in a population with a significant share of high school education.
The issues facing medical patients have been especially highlighted. An important field of research on health-information-seeking behavior (HISB) emerged prior to the development of open science. In a 2003 survey, half of American Internet users had attempted to find
qualified information about their health, but regularly faced access
issues: "Many current Internet health users want to expand access to
information-laden sites that are currently closed to non-subscribers". A qualitative research on English medical patients, subscription
paywalls were cited as the main barrier to access to scientific
knowledge, along with the complexity of scientific terminology. While the specific needs patients make a strong case for open science,
they have also overshadowed the variety of potential uses of academic
research: "open access is not just a public health matter: It has a much
more general research-enhancing mission".
Research has also focused on professional non-academic uses, due
to their potential economic impact. In 2011, a JISC report estimated
that there were 1.8 million knowledge workers in the United Kingdom
working in R&D, IT, and engineering services, most of whom were
"unaffiliated, without corporate library or information center support." Among a representative set of English knowledge workers, 25% stated that access to the literature was fairly difficult or very difficult and 17% had a recent access problem that had never been resolved. A 2011 survey of Danish businesses highlighted a significant dependence
of R&D to academic research: "Forty-eight per cent rated research
articles as very or extremely important". The non-profit sector is also significantly impacted by increasing
access to literature, as a survey of 101 NGOs from the United Kingdom
showed that "73% reported using journal articles and 54% used conference
proceedings". In 2018, a log analysis on OpenEdition
highlighted corporate access as a significant source of readership,
especially among "the aircraft industry, the bank, insurance, car
selling and energy sectors and, even more significantly for the further
circulation of science in the public sphere, media organizations." These results showed that open access had a direct commercial impact on small and large companies.
Language diversity
Scientific publications in languages other than English have been
marginalized in large commercial databases: they represent less than 5%
of the publications indexed in the Web of Science.
The development of open science platforms has gradually shifted
the focus, with local-language publications becoming acknowledged as
important actors in the social dissemination of scientific knowledge. In
the 2010s, quantitative studies have started to highlight the positive
impact of local languages on the reuse of open access resources in
varied national contexts such as Finland, Québec, Croatia or Mexico.
Measures of social impact tend to reverse the incentives of
international academic metrics like the impact factors: while they are
less featured in academic indices, publications in a local language fare
better on an enlarged audience. In Finland, a majority of the audience
of the academic platform journal.fi favors publications in Finnish (67%). Yet, the linguistic practices of the visitors vary significantly depending on their academic status. Lay readers (private citizens)
and students have a clear preference for the local language (81% and
78% of publications accessed). In contrast, professional researchers
slightly favor English over Finnish (55%).
Due to the ease of access, open science platforms in a local
language can also achieve a broader reach. The French-Canadian journal
consortium Érudit has mostly an international audience, with less than one-third of the readers coming from Canada.
Sharing ecosystem
Open science resources are more likely to be shared in non-scientific settings such as "Twitter, News, Blogs and Policies". In 2011, a log analysis study in Japan highlighted "a remarkable
variety of websites linked to these OA papers, including blogs about
personal hobbies, websites by patients or their families, Q&A
website and Wikipedia."
The diversity of the open science ecosystem has been hypothesized to affect the life cycle pattern. In the classic framework of bibliometrics, most publications are
expected to experience an exponential decline in citations over the year
(also characterized as "half-life", by assimilation with the decay of
radioactive elements). In contrast, open science publications "have the feature of keeping sustained and steady downloads for a long time". This sustained reception on a longer timeframe may be partially caused
by recurrent episodes of "unexpected access": where old publications
attract a new wave of readers suddenly due to a newfound relevance.
Reuse of data and software
In contrast with publications, open scientific data and software
frequently require a higher level of technical skills: "access is not
enough to guarantee that Open Data can be reused effectively because
reuse requires not only access, but other resources such as skills,
money and computing power".Even firms and organizations may lack the "necessary skills such as information literacy to fully benefit from open resources".
Yet, recent developments like the growth of data analytics
services across a large variety of economic sectors have created further
needs for research data: "There are many other values (…) that are
promoted through the longterm stewardship and open availability of
research data. The rapidly expanding area of artificial intelligence
(AI) relies to a great extent on saved data." In 2019, the combined data market of the 27 countries of the European
Union and the United Kingdom was estimated at 400 billion euros and had a
sustained growth of 7.6% per year. although no estimation was given of the specific value of research
data, research institutions were identified as important stakeholders in
the emerging ecosystem of "data commons".
The GEBCO Gazetteer of Undersea Feature Names indicates that the feature is situated at 11°22.4′N142°35.5′E and has an approximated maximum depth of 5,962 to 6,020 fathoms (10,903 to 11,009 m; 35,772 to 36,120 ft) below sea level. A 2011 study placed the depth at 5,971 ± 5 fathoms (10,920 ± 9 m; 35,826 ± 30 ft) with a 2021 study revising the value to 10,935 ± 6 m (35,876 ± 20 ft) at a 95% confidence level.
Sonar mapping of the Challenger Deep by the DSSV Pressure Drop employing a Kongsberg SIMRAD EM124 multibeam echosounder system (26 April – 4 May 2019)
The Challenger Deep is a relatively small slot-shaped depression in the bottom of a considerably larger crescent-shaped oceanic trench, which itself is an unusually deep feature in the ocean floor. The Challenger Deep consists of three basins, each six to ten kilometres (3.7 to 6.2 mi)
long, 2 kilometres (1.2 mi) wide, and over 5,930 fathoms (10,840 m;
35,580 ft) in depth, oriented in echelon from west to east, separated by
mounds between the basins 200 to 300 metres (660 to 980 ft) higher. The
three basins feature extends about 48 kilometres (30 mi) west to east
if measured at the 10,650-metre (34,940 ft) isobath. Both the western and eastern basins have recorded depths (by sonar
bathymetry) in excess of 10,920 metres (35,827 ft), while the center
basin is slightly less deep. The closest land to the Challenger Deep is Fais Island (one of the outer islands of Yap), 155 nautical miles (287 km; 178 mi) southwest, and Guam, 164 nautical miles (304 km; 189 mi) to the northeast. Detailed sonar mapping of the western, center and eastern basins in June 2020 by the DSSV Pressure Drop combined with manned descents revealed that they undulate with slopes and piles of rocks above a bed of pelagic ooze.
This conforms with the description of Challenger Deep as consisting of
an elongated seabed section with distinct sub-basins or sediment-filled
pools.
Surveys and bathymetry
Over many years, the search for, and investigation of, the location
of the maximum depth of the world's oceans has involved many different
vessels, and continues into the twenty-first century.
The accuracy of determining geographical location, and the
beamwidth of (multibeam) echosounder systems, limits the horizontal and
vertical bathymetric sensor resolution
that hydrographers can obtain from onsite data. This is especially
important when sounding in deep water, as the resulting footprint of an
acoustic pulse gets large once it reaches a distant sea floor. Further,
sonar operation is affected by variations in sound speed, particularly in the vertical plane. The speed is determined by the water's bulk modulus, mass, and density. The bulk modulus is affected by temperature, pressure, and dissolved impurities (usually salinity).
1875 – HMS Challenger
In 1875, during her transit from the Admiralty Islands in the Bismarck Archipelago to Yokohama in Japan, the three-masted sailing corvette HMS Challengerattempted to make landfall at Spanish Marianas (now Guam), but was set to the west by "baffling winds" preventing her crew from "visiting either the Carolines or the Ladrones." Their altered path took them over the undersea canyon which later became known as the Challenger Deep. Depth soundings were taken by Baillie-weighted marked rope, and geographical locations were determined by celestial navigation
(to an estimated accuracy of two nautical miles (3.7 km; 2.3 mi)). One
of their samples was taken within fifteen miles of the deepest spot in
all of Earth's oceans. On 23 March 1875, at sample station number #225,
HMS Challenger recorded the bottom at 4,475 fathoms (26,850 ft; 8,184 m) deep, (the deepest sounding of her three-plus-year eastward circumnavigation of the Earth) at 11°24′N143°16′E – and confirmed it with a second sounding at the same location. The serendipitous discovery of Earth's deepest depression by history's first major scientific expedition devoted entirely to the emerging science of oceanography, was incredibly good fortune, and especially notable when compared to the Earth's third deepest site (the Sirena Deep only 150 nautical miles east of the Challenger Deep), which would remain undiscovered for another 122 years.
Seventy-five years later, the 1,140-ton British survey vessel HMS Challenger II, on her three-year westward circumnavigation of Earth, investigated the extreme depths southwest of Guam reported in 1875 by her predecessor, HMS Challenger. On her southbound track from Japan to New Zealand (May–July 1951), Challenger II conducted a survey of the Marianas Trench between Guam and Ulithi atoll, using seismic-sized bomb-soundings and recorded a maximum depth of 5,663 fathoms (33,978 ft; 10,356 m). The depth was beyond Challenger II'secho sounder
capability to verify, so they resorted to using a taut wire with
"140 lbs of scrap iron", and documented a depth of 5,899 fathoms
(35,394 ft; 10,788 m). The Senior Scientist aboard Challenger II, Thomas Gaskell, recalled:
[I]t
took from ten past five in the evening until twenty to seven, that is
an hour and a half, for the iron weight to fall to the sea-bottom. It
was almost dark by the time the weight struck, but great excitement
greeted the reading...
In New Zealand, the Challenger II
team gained the assistance of the Royal New Zealand Dockyard, "who
managed to boost the echo sounder to record at the greatest depths". They returned to the "Marianas Deep" (sic) in October 1951. Using their newly improved echo sounder, they ran
survey lines at right angles to the axis of the trench and discovered "a
considerable area of a depth greater than 5,900 fathoms (35,400 ft;
10,790 m)" – later identified as the Challenger Deep's western basin. The greatest depth recorded was 5,940 fathoms (35,640 ft; 10,863 m), at 11°19′N142°15′E. Navigational accuracy of several hundred meters was attained by celestial navigation and LORAN-A. As Gaskell explained, the measurement
was not more than 50 miles from the spot where the nineteenth-century Challenger found her deepest depth [...] and it may be thought fitting that a ship with the name Challenger should put the seal on the work of that great pioneering expedition of oceanography.
The term "Challenger Deep" came into use after this 1951–52 Challenger
circumnavigation, and commemorates both British ships of that name
involved with the discovery of the deepest basin of the world's oceans.
Research vessel Vityaz in Kaliningrad "Museum of world ocean"
1957–1958 – RV Vityaz
In August 1957, the Soviet 3,248-ton Vernadsky Institute of Geochemistry research vessel Vityaz recorded a maximum depth of 6,033 ± 27 fathoms (36,198 ± 162 ft; 11,033 ± 49 m) at 11°20.9′N142°11.5′E
in the western basin of the Challenger Deep during a brief transit of
the area on Cruise #25. She returned in 1958, Cruise #27, to conduct a
detailed single beam bathymetry survey involving over a dozen transects
of the Deep, with an extensive examination of the western basin and a
quick peek into the eastern basin. Fisher records a total of three Vityaz sounding locations on Figure 2 "Trenches" (1963), one within yards of the 142°11.5' E location, and a third at 11°20.0′N142°07′E, all with a 6,033 ± 27-fathom (36,198 ± 162 ft; 11,033 ± 49 m) depth. The depths were considered statistical outliers, and a depth greater than 11,000 metres has never been proven. Taira reports that if Vityaz's depth was corrected with the same methodology used by the Japanese RV Hakuho Maru expedition of December 1992, it would be presented as 10,983 ± 50 metres (36,033 ± 164 ft), as opposed to modern depths from multibeam echosounder systems greater
than 10,900 metres (35,800 ft) with the NOAA accepted maximum of
10,995 ± 10 metres (36,073 ± 33 ft) in the western basin.
1959 – RV Stranger
The first definitive verification of both the depth and location of
the Challenger Deep (western basin) was determined by Dr. R. L. Fisher
from the Scripps Institution of Oceanography, aboard the 325-ton research vessel Stranger. Using explosive soundings, they recorded 10,850 ± 20 metres (35,597 ± 66 ft) at/near 11°18′N142°14′E in July 1959. Stranger used celestial and LORAN-C for navigation. LORAN-C navigation provided geographical accuracy of 460 m (1,509 ft) or better. According to another source RV Stranger using bomb-sounding surveyed a maximum depth of 10,915 ± 10 metres (5,968.4 ± 5.5 fathoms; 35,810 ± 33 ft) at 11°20.0′N142°11.8′E. Discrepancies between the geographical location (lat/long) of Stranger's deepest depths and those from earlier expeditions (Challenger II 1951; Vityaz 1957 and 1958) "are probably due to uncertainties in fixing the ships' positions". Stranger's
north-south zig-zag survey passed well to the east of the eastern basin
southbound, and well to the west of the eastern basin northbound, thus
failed to discover the eastern basin of the Challenger Deep. The maximum depth measured near longitude 142°30'E was 10,760 ± 20 m
(35,302 ± 66 ft), about 10 km west of the eastern basin's deepest point.
This was an important gap in information, as the eastern basin was
later reported as deeper than the other two basins.
Stranger crossed the center basin twice, measuring a maximum
depth of 10,830 ± 20 m (35,531 ± 66 ft) in the vicinity of 142°22'E. At
the western end of the central basin (approximately 142°18'E), they
recorded a depth of 10,805 ± 20 m (35,449 ± 66 ft). The western basin received four transects by Stranger, recording depths of 10,830 ± 20 m (35,531 ± 66 ft) toward the central basin, near where Trieste dived in 1960 (vicinity 11°18.5′N142°15.5′E, and where Challenger II, in 1950, recorded 10,863 ± 35 m (35,640 ± 115 ft). At the far western end of the western basin (about 142°11'E), the Stranger recorded 10,850 ± 20 m (35,597 ± 66 ft), some 6 km south of the location where Vityaz recorded 11,034 ± 50 m (36,201 ± 164 ft) in 1957–1958. Fisher stated: "differences in the Vitiaz [sic] and Stranger–Challenger II depths can be attributed to the [sound] velocity correction function used". After investigating the Challenger Deep, Stranger proceeded to the Philippine Trench
and transected the trench over twenty times in August 1959, finding a
maximum depth of 10,030 ± 10 m (32,907 ± 33 ft), and thus established
that the Challenger Deep was about 800 metres (2,600 ft) deeper than the
Philippine Trench. The 1959 Stranger surveys of the Challenger Deep and of the Philippine Trench informed the U.S. Navy as to the appropriate site for Trieste's record dive in 1960.
1962 – RV Spencer F. Baird
The Proa Expedition, Leg 2, returned Fisher to the Challenger Deep on 12–13 April 1962 aboard the Scripps research vessel Spencer F. Baird (formerly the steel-hulled US Army large tug LT-581)
and employed a Precision Depth Recorder (PDR) to verify the extreme
depths previously reported. They recorded a maximum depth of 10,915
metres (35,810 ft) (location not available). Additionally, at location "H-4" in the Challenger Deep, the expedition
cast three taut-wire soundings: on 12 April, the first cast was to 5,078
fathoms (corrected for wire angle) 9,287 metres (30,469 ft) at 11°23′N142°19.5′E
in the central basin (Up until 1965, US research vessels recorded
soundings in fathoms). The second cast, also on 12 April, was to 5,000+ fathoms at 11°20.5′N142°22.5′E
in the central basin. On 13 April, the final cast recorded 5,297
fathoms (corrected for wire angle) 9,687 metres (31,781 ft) at 11°17.5′N142°11′E (the western basin). They were chased off by a hurricane after only two days on-site. Once
again, Fisher entirely missed the eastern basin of the Challenger Deep,
which later proved to contain the deepest depths.
1975–1980 – RV Thomas Washington
The Scripps Institution of Oceanography deployed the 1,490-ton Navy-owned, civilian-crewed research vessel Thomas Washington (AGOR-10) to the Mariana Trench on several expeditions from 1975 to 1986. The first of these was the Eurydice Expedition, Leg 8 which brought Fisher back to the Challenger Deep's western basin from 28–31 March 1975. Thomas Washington established geodetic positioning by (SATNAV) with Autolog Gyro and EM Log. Bathymetrics
were by a 12 kHz Precision Depth Recorder (PDR) with a single 60° beam.
They mapped one, "possibly two", axial basins with a depth of
10,915 ± 20 m (35,810 ± 66 ft). Five dredges were hauled 27–31 March, all into or slightly north of the
deepest depths of the western basin. Fisher noted that this survey of
the Challenger Deep (western basin) had "provided nothing to support and
much to refute recent claims of depths there greater than 10,915 ± 20 m
(35,810 ± 66 ft)." While Fisher missed the eastern basin of the Challenger Deep (for the
third time), he did report a deep depression about 150 nautical miles
east of the western basin. The 25 March dredge haul at 12°03.72′N142°33.42′E encountered 10,015 metres (32,858 ft), which pre-shadowed by 22 years the discovery of HMRG Deep/Sirena Deep in 1997. The deepest waters of the HMRG Deep/Sirena Deep at 10,714 ± 20 m (35,151 ± 66 ft) are centered at/near 12°03.94′N142°34.866′E, approximately 2.65 km from Fisher's 25 March 1975 10,015 metres (32,858 ft) dredge haul.
On Scripps Institution of Oceanography's INDOPAC Expedition Leg 3, the chief scientist, Dr. Joseph L. Reid, and oceanographer Arnold W. Mantyla made a hydrocast of a free vehicle (a special-purpose benthic lander
(or "baited camera") for measurements of water temperature and
salinity) on 27 May 1976 into the western basin of the Challenger Deep,
"Station 21", at 11°19.9′N142°10.8′E at about 10,840 metres (35,560 ft) depth. On INDOPAC Expedition Leg 9, under chief scientist A. Aristides Yayanos, Thomas Washington
spent nine days from 13–21 January 1977 conducting an extensive and
detailed investigation of the Challenger Deep, mainly with biological
objectives. "Echo soundings were carried out primarily with a 3.5 kHz single-beam
system, with a 12 kHz echosounder operated in addition some of the time"
(the 12 kHz system was activated for testing on 16 January). A benthic lander was put into the western basin (11°19.7′N142°09.3′E)
on 13 January, bottoming at 10,663 metres (34,984 ft) and recovered 50
hours later in damaged condition. Quickly repaired, it was again put
down on the 15th to 10,559 metres (34,642 ft) depth at 11°23.3′N142°13.8′E. It was recovered on the 17th with excellent photography of amphipods (shrimp) from the Challenger Deep's western basin. The benthic lander was put down for the third and last time on the 17th, at 11°20.1′N142°25.2′E,
in the central basin at a depth of 10,285 metres (33,743 ft). The
benthic lander was not recovered and may remain on the bottom in the
vicinity of 11°20.1′N142°25.2′E.
Free traps and pressure-retaining traps were put down at eight
locations from 13 to 19 January into the western basin, at depths
ranging from 7,353 to 10,715 metres (24,124–35,154 ft). Both the free
traps and the pressure-retaining traps brought up good sample amphipods
for study. While the ship briefly visited the area of the eastern basin,
the expedition did not recognize it as potentially the deepest of the
three Challenger Deep basins.
Thomas Washington returned briefly to the Challenger Deep on 17–19 October 1978 during Mariana Expedition Leg 5 under chief scientist James W. Hawkins. The ship tracked to the south and west of the eastern basin, and
recorded depths between 5,093 and 7,182 metres (16,709–23,563 ft).
Another miss. On Mariana Expedition Leg 8, under chief scientist Yayanos, Thomas Washington
was again involved, from 12–21 December 1978, with an intensive
biological study of the western and central basins of the Challenger
Deep. Fourteen traps and pressure-retaining traps were put down to depths
ranging from 10,455 to 10,927 metres (34,301–35,850 ft); the greatest
depth was at 11°20.0′N142°11.8′E.
All of the 10,900-plus m recordings were in the western basin. The
10,455 metres (34,301 ft) depth was furthest east at 142°26.4' E (in the
central basin), about 17 km west of the eastern basin. Again, focused
efforts on the known areas of extreme depths (the western and central
basins) were so tight that the eastern basin again was missed by this
expedition.
From 20 to 30 November 1980, Thomas Washington was on site at the western basin of the Challenger Deep, as part of Rama Expedition Leg 7, again with chief-scientist Dr. A. A. Yayanos. Yayanos directed Thomas Washington
in arguably the most extensive and wide-ranging of all single-beam
bathymetric examinations of the Challenger Deep ever undertaken, with
dozens of transits of the western basin, and ranging far into the backarc
of the Challenger Deep (northward), with significant excursions into
the Pacific Plate (southward) and along the trench axis to the east. They hauled eight dredges in the western basin to depths ranging from
10,015 to 10,900 metres (32,858–35,761 ft), and between hauls, cast
thirteen free vertical traps. The dredging and traps were for biological
investigation of the bottom. In the first successful retrieval of a
live animal from the Challenger Deep, on 21 November 1980 in the western
basin at 11°18.7′N142°11.6′E, Yayanos recovered a live amphipod from about 10,900 meters depth with a pressurized trap. Once again, other than a brief look into the eastern basin, all
bathymetric and biological investigations were into the western basin.
1976–1977 – RV Kana Keoki
Pacific plate subduction at the Challenger Deep
On Leg 3 of the Hawaii Institute of Geophysics' (HIG) expedition 76010303, the 156-foot (48 m) research vessel Kana Keoki departed Guam primarily for a seismic investigation of the Challenger Deep area, under chief scientist Donald M. Hussong. The ship was equipped with air guns (for seismic reflection soundings deep into the Earth's mantle), magnetometer, gravimeter,
3.5 kHz and 12 kHz sonar transducers, and precision depth recorders.
They ran the Deep from east to west, collecting single beam bathymetry,
magnetic and gravity measurements, and employed the air guns along the
trench axis, and well into the backarc and forearc, from 13 to 15 March 1976. Thence they proceeded south to the Ontong Java Plateau. All three deep basins of the Challenger Deep were covered, but Kana Keoki recorded a maximum depth of 7,800 m (25,591 ft). Seismic information developed from this survey was instrumental in gaining an understanding of the subduction of the Pacific Plate under the Philippine Sea Plate. In 1977, Kana Keoki returned to the Challenger Deep area for wider coverage of the forearc and backarc.
1984 – SV Takuyo
The Hydrographic Department, Maritime Safety Agency, Japan (JHOD) deployed the newly commissioned 2,600-ton survey vessel Takuyo (HL 02) to the Challenger Deep 17–19 February 1984. Takuyo was the first Japanese ship to be equipped with the new narrowbeam SeaBeammulti-beam sonar echosounder, and was the first survey ship
with multi-beam capability to survey the Challenger Deep. The system
was so new that JHOD had to develop their own software for drawing
bathymetric charts based on the SeaBeam digital data. In just three days, they tracked 500 miles of sounding lines, and covered about 140 km2 of the Challenger Deep with multibeam ensonification. Under chief scientist Hideo Nishida, they used CTD temperature and salinity data from the top 4,500 metres (14,764 ft) of the water column to correct depth measurements, and later conferred with Scripps Institution of Oceanography (including Fisher), and other GEBCO experts to confirm their depth correction methodology. They employed a combination of NAVSAT, LORAN-C and OMEGA
systems for geodetic positioning with accuracy better than 400 metres
(1,300 ft). The deepest location recorded was 10,920 ± 10 m
(35,827 ± 33 ft) at 11°22.4′N142°35.5′E; for the first time documenting the eastern basin as the deepest of the three en echelon pools. In 1993, GEBCO recognized the 10,920 ± 10 m (35,827 ± 33 ft) report as the deepest depth of the world's oceans. Technological advances such as improved multi-beam sonar would be the driving force in uncovering the mysteries of the Challenger Deep into the future.
1986 – RV Thomas Washington
The Scripps research vessel Thomas Washington's returned to the Challenger Deep in 1986 during the Papatua Expedition, Leg 8,
mounting one of the first commercial multi-beam echosounders capable of
reaching into the deepest trenches, i.e. the 16-beam Seabeam "Classic".
This allowed chief scientist Yayanos an opportunity to transit the
Challenger Deep with the most modern depth-sounding equipment available.
During the pre-midnight hours of 21 April 1986, the multibeam
echosounder produced a map of the Challenger Deep bottom with a swath
of about 5–7 miles wide. The maximum depth recorded was 10,804 metres
(35,446 ft) (location of depth is not available). Yayanos noted: "The
lasting impression from this cruise comes from the thoughts of the
revolutionary things that Seabeam data can do for deep biology."
1988 – RV Moana Wave
On 22 August 1988, the U.S. Navy-owned 1,000-ton research vessel Moana Wave (AGOR-22), operated by the Hawaii Institute of Geophysics (HIG), University of Hawaiʻi, under the direction of chief scientist Robert C. Thunell from the University of South Carolina,
transited northwesterly across the central basin of the Challenger
Deep, conducting a single-beam bathymetry track by their 3.5 kHz narrow
(30-degs) beam echosounder with a Precision Depth Recorder. In addition
to sonar bathymetry, they took 44 gravity cores and 21 box cores
of bottom sediments. The deepest echosoundings recorded were 10,656 to
10,916 metres (34,961–35,814 ft), with the greatest depth at 11°22′N
142°25′E in the central basin. This was the first indication that all three basins contained depths in excess of 10,900 metres (35,800 ft).
The RV Hakuhō Maru
1992 – RV Hakuhō Maru
The 3,987-ton Japanese research vessel Hakuhō Maru [ja], an Ocean Research Institute – University of Tokyo sponsored ship, on cruise KH-92-5 cast three Sea-Bird SBE-9 ultra-deep CTD
(conductivity-temperature-depth) profilers in a transverse line across
the Challenger Deep on 1 December 1992. The center CTD was located at 11°22.78′N142°34.95′E,
in the eastern basin, at 10,989 metres (36,053 ft) by the SeaBeam depth
recorder and 10,884 metres (35,709 ft) by the CTD. The other two CTDs
were cast 19.9 km to the north and 16.1 km to the south. Hakuhō Maru
was equipped with a narrow beam SeaBeam 500 multi-beam echosounder for
depth determination, and had an Auto-Nav system with inputs from NAVSAT/NNSS, GPS, Doppler Log, EM log and track display, with a geodetic positioning accuracy approaching 100 metres (330 ft). When conducting CTD operations in the Challenger deep, they used the SeaBeam as a single beam depth recorder. At 11°22.6′N142°35.0′E the corrected depth was 10,989 metres (36,053 ft), and at 11°22.0′N142°34.0′E the depth was 10,927 metres (35,850 ft); both in the eastern basin. This may demonstrate that the basins might not be flat sedimentary pools but rather undulate with a difference of 50 metres (160 ft) or more. Taira revealed, "We considered that a trough deeper than Vitiaz's
record by 5 metres (16 ft) was detected. There is a possibility that a
depth exceeding 11,000 metres (36,089 ft) with a horizontal scale less
than the beam width of measurements exists in the Challenger Deep. Since each SeaBeam 2.7-degree beam width sonar ping expands to cover a
circular area about 500 metres (1,640 ft) in diameter at 11,000 metres
(36,089 ft) depth, dips in the bottom that are less than that size would
be difficult to detect from a sonar-emitting platform seven miles
above.
RV Yokosuka was used as the support ship for ROV Kaikō.
1996 – RV Yokosuka
For most of 1995 and into 1996, the Japan Agency for Marine-Earth Science and Technology (JAMSTEC) employed the 4,439-ton Research Vessel Yokosuka to conduct the testing and workup of the 11,000-meter remotely-operated vehicle (ROV) Kaikō, and the 6,500 meter ROV Shinkai. It was not until February 1996, during Yokosuka's cruise Y96-06, that Kaikō
was ready for its first full depth dives. On this cruise, JAMSTEC
established an area of the Challenger Deep (11°10'N to 11°30'N, by
141°50'E to 143°00'E – which later was recognized as containing three
separate pools/basins en echelon, each with depths in excess of 10,900 m
(35,761 ft)) toward which JAMSTEC expeditions would concentrate their
investigations for the next two decades. The Yokosuka employed a 151-beam SeaBeam 2112 12 kHz multibeam
echosounder, allowing search swaths 12–15 km in width at 11,000 metres
(36,089 ft) depth. The depth accuracy of Yokosuka's
Seabeam was about 0.1% of water depth (i.e. ± 110 metres (361 ft) for
11,000 metres (36,089 ft) depth). The ship's dual GPS systems attained
geodetic positioning within double digit meter (100 metres (328 ft) or
better) accuracy.
1998, 1999 and 2002 – RV Kairei
Cruise KR98-01 sent JAMSTEC's two-year-old 4,517-ton Deep Sea Research Vessel RV Kairei
south for a quick but thorough depth survey of the Challenger Deep,
11–13 January 1998, under chief scientist Kantaro Fujioka. Tracking
largely along the trench axis of 070–250° they made five 80-km
bathymetric survey tracks, spaced about 15 km apart, overlapping their
SeaBeam 2112-004 (which now allowed sub-bottom profiling penetrating as
much as 75 m below the bottom) while gaining gravity and magnetic data
covering the entire Challenger Deep: western, central, and eastern
basins.
The Deep Sea Research Vessel RV Kairei was also used as the support ship for the ROV Kaikō.
Kairei returned in May 1998, cruise KR98-05, with ROV Kaikō,
under the direction of chief scientist Jun Hashimoto with both
geophysical and biological goals. Their bathymetric survey from 14–26
May was the most intensive and thorough depth and seismic survey of the
Challenger Deep performed to date. Each evening, Kaikō deployed
for about four hours of bottom time for biological-related sampling,
plus about seven hours of vertical transit time. When Kaikō was onboard for servicing, Kairei conducted bathymetric surveys and observations. Kairei gridded a survey area about 130 km N–S by 110 km E–W. Kaikō
made six dives (#71–75) all to the same location, (11°20.8' N,
142°12.35' E), near the 10,900 metres (35,800 ft) bottom contour line in
the western basin.
The regional bathymetric map made from the data obtained in 1998
shows that the greatest depths in the eastern, central, and western
depressions are 10,922 ± 74 m (35,833 ± 243 ft), 10,898 ± 62 m
(35,755 ± 203 ft), and 10,908 ± 36 m (35,787 ± 118 ft), respectively,
making the eastern depression the deepest of the three.
In 1999, Kairei revisited the Challenger Deep during
cruise KR99-06. The results of the 1998–1999 surveys include the first
recognition that the Challenger Deep consists of three "right-stepping
en echelon individual basins bounded by the 10,500 metres (34,400 ft)
depth contour line. The size of [each of] the deeps are almost
identical, 14–20 km long, 4 km wide". They concluded with the proposal
"that these three individual elongated deeps constitute the 'Challenger
Deep', and [we] identify them as the East, Central and West Deep. The
deepest depth we obtained during the swath mapping is 10,938 metres
(35,886 ft) in the West Deep (11°20.34' N, 142°13.20 E)." The depth was "obtained during swath mapping ... confirmed in both N–S
and E-W swaths." Speed of sound corrections were from XBT to 1,800
metres (5,900 ft), and CTD below 1,800 metres (5,900 ft).
The cross track survey of the 1999 Kairei cruise shows
that the greatest depths in the eastern, central, and western
depressions are 10,920 ± 10 m (35,827 ± 33 ft), 10,894 ± 14 m
(35,741 ± 46 ft), and 10,907 ± 13 m (35,784 ± 43 ft), respectively,
which supports the results of the previous survey.
In 2002 Kairei revisited the Challenger Deep 16–25 October
2002, as cruise KR02-13 (a cooperative Japan-US-South Korea research
program) with chief scientist Jun Hashimoto in charge; again with
Kazuyoshi Hirata managing the ROV Kaikō team. On this survey, the
size of each of the three basins was refined to 6–10 km long by about
2 km wide and in excess of 10,850 m (35,597 ft) deep. In marked contrast
to the Kairei surveys of 1998 and 1999, the detailed survey in
2002 determined that the deepest point in the Challenger Deep is located
in the eastern basin around 11°22.260′N142°35.589′E,
with a depth of 10,920 ± 5 m (35,827 ± 16 ft), located about 290 m
(950 ft) southeast of the deepest site determined by the survey vessel Takuyo
in 1984. The 2002 surveys of both the western and eastern basins were
tight, with especially meticulous cross-gridding of the eastern basin
with ten parallel tracks N–S and E–W less than 250 meters apart. On the
morning of 17 October, ROV Kaikō dive #272 began and recovered
over 33 hours later, with the ROV working at the bottom of the western
basin for 26 hours (vicinity of 11°20.148' N, 142°11.774 E at 10,893 m
(35,738 ft)). Five Kaikō dives followed on a daily basis into the
same area to service benthic landers and other scientific equipment,
with dive #277 recovered on 25 October. Traps brought up large numbers
of amphipods (sea fleas), and cameras recorded holothurians (sea cucumbers), White polychaetes (bristle worms), tube worms, and other biological species. During its 1998, 1999 surveys, Kairei was equipped with a GPS satellite-based radionavigation system. The United States government lifted the GPS selective availability in 2000, so during its 2002 survey, Kairei had access to non-degraded GPS positional services and achieved single-digit meter accuracy in geodetic positioning.
2001 – RV Melville
The RV Melville was operated by the Scripps Institution of Oceanography.
The 2.516-ton research vessel Melville,
at the time operated by the Scripps Institution of Oceanography, took
the Cook Expedition, Leg 6 with chief scientist Patricia Fryer of the
University of Hawaiʻi from Guam on 10 February 2001 to the Challenger
Deep for a survey titled "Subduction Factory Studies in the Southern
Mariana", including HMR-1 sonar mapping, magnetics, gravity
measurements, and dredging in the Mariana arc region. They covered all three basins, then tracked 120-nautical-mile-long
(222.2 km) lines of bathymetry East-West, stepping northward from the
Challenger Deep in 12 km (7.5 mi) sidesteps, covering more than 90 nmi
(166.7 km) north into the backarc with overlapping swaths from their
SeaBeam 2000 12 kHz multi-beam echosounder and MR1 towed system. They
also gathered magnetic and gravity information, but no seismic data. Their primary survey instrument was the MR1 towed sonar, a shallow-towed 11/12 kHz bathymetric sidescan sonar
developed and operated by the Hawaii Mapping Research Group (HMRG), a
research and operational group within University of Hawaiʻi's School of
Ocean and Earth Science and Technology (SOEST) and the Hawaii Institute
of Geophysics and Planetology (HIGP). The MR1 is full-ocean-depth
capable, providing both bathymetry and sidescan data.
Leg 7 of the Cook Expedition continued the MR-1 survey of the
Mariana Trench backarc from 4 March to 12 April 2001 under chief
scientist Sherman Bloomer of Oregon State University.
2009 – RV Kilo Moana
The RV Kilo Moana was used as the support ship of the HROV Nereus.
In May/June 2009, the US Navy-owned 3,064-ton twin-hulled research vessel Kilo Moana (T-AGOR 26) was sent to the Challenger Deep area to conduct research. Kilo Moana
is civilian-crewed and operated by SOEST. It is equipped with two
multibeam echosounders with sub-bottom profiler add-ons (the 191-beam
12 kHz Kongsberg Simrad EM120 with SBP-1200, capable of accuracies of 0.2–0.5% of water depth across the entire swath), gravimeter, and magnetometer.
The EM-120 uses 1 by 1 degree sonar-emissions at the sea surface. Each 1
degree beam width sonar ping expands to cover a circular area about 192
metres (630 ft) in diameter at 11,000 metres (36,089 ft) depth. Whilst
mapping the Challenger Deep the sonar equipment indicated a maximum
depth of 10,971 m (35,994 ft) at an undisclosed position. Navigation equipment includes the Applanix POS MV320 V4, rated at accuracies of 0.5–2 m. RV Kilo Moana was also used as the support ship of the hybrid remotely operated underwater vehicle (HROV) Nereus
that dived three times to the Challenger Deep bottom during the
May/June 2009 cruise and did not confirm the sonar established maximum
depth by its support ship.
2009 – RV Yokosuka
Cruise YK09-08 brought the JAMSTEC 4,429-ton research vessel Yokosuka back to the Mariana Trough and to the Challenger Deep June–July 2009. Their mission was a two-part program: surveying three hydrothermal vent
sites in the southern Mariana Trough backarc basin near 12°57'N,
143°37'E about 130 nmi northeast of the central basin of the Challenger
Deep, using the autonomous underwater vehicle Urashima. AUV Urashima
dives #90–94, were to a maximum depth of 3500 meters, and were
successful in surveying all three sites with a Reson SEABAT7125AUV
multibeam echosounder for bathymetry, and multiple water testers to
detect and map trace elements spewed into the water from hydrothermal
vents, white smokers, and hot spots. Kyoko OKINO from the Ocean Research
Institute, University of Tokyo, was principal investigator for this aspect of the cruise.
The second goal of the cruise was to deploy a new "10K free fall camera system" called Ashura,
to sample sediments and biologics at the bottom of the Challenger Deep.
The principal investigator at the Challenger Deep was Taishi Tsubouchi
of JAMSTEC. The lander Ashura made two descents: on the first, 6 July 2009, Ashura bottomed at 11°22.3130′N142°25.9412′E at 10,867 metres (35,653 ft). The second descent (on 10 July 2009) was to 11°22.1136′N142°25.8547′E at 10,897 metres (35,751 ft). The 270 kg Ashura
was equipped with multiple baited traps, a HTDV video camera, and
devices to recover sediment, water, and biological samples (mostly
amphipods at the bait, and bacteria and fungus from the sediment and
water samples).
2010 – USNS Sumner
On 7 October 2010, further sonar mapping of the Challenger Deep area was conducted by the US Center for Coastal & Ocean Mapping/Joint Hydrographic Center (CCOM/JHC) aboard the 4,762-ton Sumner. The results were reported in December 2011 at the annual American Geophysical Union
fall meeting. Using a Kongsberg Maritime EM 122 multi-beam echosounder
system coupled to positioning equipment that can determine latitude and
longitude up to 50 cm (20 in) accuracy, from thousands of individual
soundings around the deepest part the CCOM/JHC team preliminary
determined that the Challenger Deep has a maximum depth of 10,994 m
(36,070 ft) at 11.326344°N 142.187248°E, with an estimated vertical uncertainty of ±40 m (131 ft) at two standard deviations (i.e. ≈ 95.4%) confidence level. A secondary deep with a depth of 10,951 m (35,928 ft) was located at approximately 23.75 nmi (44.0 km) to the east at 11.369639°N 142.588582°E in the eastern basin of the Challenger Deep.
2010 – RV Yokosuka
JAMSTEC returned Yokosuka to the Challenger Deep with cruise
YK10-16, 21–28 November 2010. The chief scientist of this joint
Japanese-Danish expedition was Hiroshi Kitazato of the Institute of
Biogeosciences, JAMSTEC. The cruise was titled "Biogeosciences at the
Challenger Deep: relict organisms and their relations to biogeochemical
cycles". The Japanese teams made five deployments of their 11,000-meter
camera system (three to 6,000 meters – two into the central basin of the
Challenger Deep) which returned with 15 sediment cores, video records
and 140 scavenging amphipod specimens. The Danish Ultra Deep Lander
System was employed by Ronnie Glud et al on four casts, two into the
central basin of the Challenger Deep and two to 6,000 m some 34 nmi west
of the central basin. The deepest depth recorded was on 28 November
2010 – camera cast CS5 – 11°21.9810′N142°25.8680′E}, at a corrected depth of 10,889.6 metres (35,727 ft) (the central basin).
2013 – RV Yokosuka
With JAMSTEC Cruises YK13-09 and YK13-12, Yokosuka hosted
chief scientist Hidetaka Nomaki for a trip to New Zealand waters
(YK13-09), with the return cruise identified as YK13-12. The project
name was QUELLE2013; and the cruise title was: "In situ experimental
& sampling study to understand abyssal
biodiversity and biogeochemical cycles". They spent one day on the
return trip at the Challenger Deep to obtain DNA/RNA on the large
amphipods inhabiting the Deep (Hirondellea gigas). Hideki
Kobayashi (Biogeos, JAMSTEC) and the team deployed a benthic lander on
23 November 2013 with eleven baited traps (three bald, five covered by
insulating materials, and three automatically sealed after nine hours)
into the central basin of the Challenger Deep at 11°21.9082′N142°25.7606′E, depth 10,896 metres (35,748 ft). After an eight-hour, 46-minute stay at the bottom, they recovered some 90 individual Hirondellea gigas.
RV Kairei is used as the support ship for deep-diving ROVs.
2014 – RV Kairei
JAMSTEC deployed Kairei to the Challenger Deep again 11–17
January 2014, under the leadership of chief scientist Takuro Nunora. The
cruise identifier was KR14-01, titled: "Trench biosphere
expedition for the Challenger Deep, Mariana Trench". The expedition
sampled at six stations transecting the central basin, with only two
deployments of the "11-K camera system" lander for sediment cores and
water samples to "Station C" at the deepest depth, i.e. 11°22.19429′N142°25.7574′E,
at 10,903 metres (35,771 ft). The other stations were investigated with
the "Multi-core" lander, both to the backarc northward, and to the
Pacific Plate southward. The 11,000-meter capable crawler-driven ROV ABIMSO
was sent to 7,646 m depth about 20 nmi due north of the central basin
(ABISMO dive #21) specifically to identify possible hydrothermal
activity on the north slope of the Challenger Deep, as suggested by
findings from Kairei cruise KR08-05 in 2008. AMISMO's
dives #20 and #22 were to 7,900 meters about 15 nmi north of the
deepest waters of the central basin. Italian researchers under the
leadership of Laura Carugati from the Polytechnic University of Marche, Italy (UNIVPM) were investigating the dynamics in virus/prokaryotes interactions in the Mariana Trench.
2014 – RV Falkor
From 16–19 December 2014, the Schmidt Ocean Institute's 2,024-ton research vessel Falkor,
under chief scientist Douglas Bartlett from the Scripps Institution of
Oceanography, deployed four different untethered instruments into the
Challenger Deep for seven total releases. Four landers were deployed on
16 December into the central basin: the baited video-equipped lander Leggo for biologics; the lander ARI to 11°21.5809′N142°27.2969′E for water chemistry; and the probes Deep Sound 3 and Deep Sound 2. Both Deep Sound probes recorded acoustics floating at 9,000 metres (29,528 ft) depth, until Deep Sound 3 imploded at the depth of 8,620 metres (28,281 ft) (about 2,200 metres (7,218 ft) above the bottom) at 11°21.99′N142°27.2484′E. The Deep Sound 2 recorded the implosion of Deep Sound 3, providing a unique recording of an implosion within the Challenger Deep depression. In addition to the loss of the Deep Sound 3 by implosion, the lander ARI failed to respond upon receiving its instruction to drop weights, and was never recovered. On 16/17 December, Leggo was returned to the central basin baited for amphipods. On the 17th, RV Falkor relocated 17 nms eastward to the eastern basin, where they again deployed both the Leggo (baited and with its full camera load), and the Deep Sound 2. Deep Sound 2
was programmed to drop to 9,000 metres (29,528 ft) and remain at that
depth during its recording of sounds within the trench. On 19 December Leggo landed at 11°22.11216′N142°35.250996′E
at a uncorrected depth of 11,168 metres (36,640 ft) according to its
pressure sensor readings. This reading was corrected to 10,929 metres
(35,856 ft) depth.Leggo returned with good photography of amphipods feeding on the lander's mackerel bait and with sample amphipods. Falknor departed the Challenger Deep on 19 December en route the Marianas Trench Marine National Monument to the Sirena Deep. RV Falkor
had both a Kongsberg EM302 and EM710 multibeam echosounder for
bathymetry, and an Oceaneering C-Nav 3050 global navigation satellite
system receiver, capable of calculating geodetic positioning with an
accuracy better than 5 cm (2.0 in) horizontally and 15 cm (5.9 in)
vertically.
2015 – USCGC Sequoia
US Coast Guard Cutter Sequoia (WLB 215)
From 10 to 13 July 2015, the Guam-based 1,930-ton US Coast Guard Cutter Sequoia (WLB 215) hosted a team of researchers, under chief scientist Robert P. Dziak, from the NOAA Pacific Marine Environmental Laboratory (PMEL), the University of Washington, and Oregon State University, in deploying PMEL's "Full-Ocean Depth Mooring", a 45-meter-long moored deep-ocean hydrophone and pressure sensor array
into the western basin of the Challenger Deep. A 6-hour descent into
the western basin anchored the array at 10,854.7 ± 8.9 m
(35,613 ± 29 ft) of water depth, at 11°20.127′N142°12.0233′E, about 1 km northeast of Sumner's deepest depth, recorded in 2010. After 16 weeks, the moored array was recovered on 2–4 November 2015.
"Observed sound sources included earthquake signals (T phases), baleen
and odontocete cetacean vocalizations, ship propeller sounds, airguns,
active sonar and the passing of a Category 4 typhoon." The science team
described their results as "the first multiday, broadband record of
ambient sound at Challenger Deep, as well as only the fifth direct depth
measurement".
2016 – RV Xiangyanghong 09
The 3,536-ton research vessel Xiangyanghong 09 deployed on Leg
II of the 37th China Cruise Dayang (DY37II) sponsored by the National
Deep Sea Center, Qingdao and the Institute of Deep-Sea Science and
Engineering, Chinese Academy of Sciences
(Sanya, Hainan), to the Challenger Deep western basin area (11°22' N,
142°25' E) 4 June – 12 July 2016. As the mother ship for China's manned
deep submersible Jiaolong,
the expedition carried out an exploration of the Challenger Deep to
investigate the geological, biological, and chemical characteristics of
the hadal zone.
The diving area for this leg was on the southern slope of the
Challenger Deep, at depths from about 6,300 to 8,300 metres (20,669 to
27,231 ft). The submersible completed nine piloted dives on the northern
backarc and south area (Pacific plate) of the Challenger Deep to depths from 5,500 to 6,700 metres (18,045 to 21,982 ft). During the cruise, Jiaolong regularly deployed gas-tight samplers to collect water near the sea bottom. In a test of navigational proficiency, Jiaolong used an Ultra-Short Base Line (USBL) positioning system at a depth more than 6,600 metres (21,654 ft) to retrieve sampling bottles.
2016 – RV Tansuo 01
From 22 June to 12 August 2016 (cruises 2016S1 and 2016S2), the Chinese Academy of Sciences' 6,250-ton submersible support ship Tansuo 1
(meaning: to explore) on her maiden voyage deployed to the Challenger
Deep from her home port of Sanya, Hainan Island. On 12 July 2016, the
ROV Haidou-1 dived to a depth of 10,767 metres (35,325 ft) in the
Challenger Deep area. They also cast a free-drop lander, 9,000 metres
(29,528 ft) rated free-drop ocean-floor seismic instruments (deployed to
7,731 metres (25,364 ft)), obtained sediment core samples, and
collected over 2000 biological samples from depths ranging from 5,000 to
10,000 metres (16,404–32,808 ft). The Tansuo 01 operated along the 142°30.00' longitude line, about 30 nmi east of the earlier DY37II cruise survey (see Xiangyanghong 09 above).
In November 2016 sonar mapping of the Challenger Deep area was conducted by the Royal Netherlands Institute for Sea Research (NIOZ)/GEOMAR Helmholtz Centre for Ocean Research Kiel aboard the 8,554-ton Deep Ocean Research Vessel Sonne.
The results were reported in 2017. Using a Kongsberg Maritime EM 122
multi-beam echosounder system coupled to positioning equipment that can
determine latitude and longitude the team determined that the Challenger
Deep has a maximum depth of 10,925 m (35,843 ft) at 11°19.945′N142°12.123′E (11.332417°N 142.20205°E),
with an estimated vertical uncertainty of ±12 m (39 ft) at one standard
deviation (≈ 68.3%) confidence level. The analysis of the sonar survey
offered a 100 by 100 metres (328 ft × 328 ft) grid resolution at bottom
depth, so small dips in the bottom that are less than that size would be
difficult to detect from the 0.5 by 1 degree sonar-emissions at the sea
surface. Each 0.5-degree beam width sonar ping expands to cover a
circular area about 96 metres (315 ft) in diameter at 11,000 metres
(36,089 ft) depth. The horizontal position of the grid point has an uncertainty of ±50 to
100 m (164 to 328 ft), depending on along-track or across-track
direction. This depth (59 m (194 ft)) and position (about 410 m
(1,345 ft) to the northeast) measurements differ significantly from the
deepest point determined by the Gardner et al. (2014) study. The observed depth discrepancy with the 2010 sonar mapping and Gardner
et al 2014 study are related to the application of differing sound
velocity profiles, which are essential for accurate depth determination.
Sonne used CTD casts about 1.6 km west of the deepest sounding to near the bottom of the Challenger Deep that were used for sound velocity profile
calibration and optimization. Likewise, the impact of using different
projections, datum and ellipsoids during data acquisition can cause
positional discrepancies between surveys.
2016 – RV Shyian 3
In December 2016, the CAS 3,300-ton research vessel Shiyan 3
deployed 33 broadband seismometers onto both the backarc northwest of
the Challenger Deep, and onto the near southern Pacific Plate to the
southeast, at depths of up to 8,137 m (26,696 ft). This cruise was part
of a $12 million Chinese-U.S. initiative, led by co-leader Jian Lin of
the Woods Hole Oceanographic Institution; a 5-year effort (2017–2021) to image in fine detail the rock layers in and around the Challenger Deep.
2016 – RV Zhang Jian
The newly launched 4,800-ton research vessel (and mothership for the Rainbow Fish series of deep submersibles), the Zhang Jian departed Shanghai on 3 December. Their cruise was to test three new deep-sea landers, one uncrewed search submersible and the new Rainbow Fish
11,000-meter manned deep submersible, all capable of diving to 10,000
meters. From 25 to 27 December, three deep-sea landing devices descended
into the trench. The first Rainbow Fish lander took photographs, the
second took sediment samples, and the third took biological samples. All
three landers reached over 10,000 meters, and the third device brought
back 103 amphipods. Cui Weicheng, director of Hadal Life Science
Research Center at Shanghai Ocean University,
led the team of scientists to carry out research at the Challenger Deep
in the Mariana Trench. The ship is part of China's national marine
research fleet but is owned by a Shanghai marine technology company.
2017 – RV Tansuo-1
CAS' Institute of Deep-sea Science and Engineering sponsored Tansuo-1's
return to the Challenger Deep 20 January – 5 February 2017 (cruise
TS03) with baited traps for the capture of fish and other macrobiology
near the Challenger and Sirena Deeps. On 29 January they recovered
photography and samples of a new species of snailfish from the Northern
slope of the Challenger Deep at 7,581 metres (24,872 ft), newly
designated Pseudoliparis swirei. They also placed four or more CTD casts into the central and eastern basins of the Challenger Deep, as part of the World Ocean Circulation Experiment (WOCE).
2017 – RV Shinyo Maru
Tokyo University of Marine Science and Technology dispatched the research vessel Shinyo Maru
to the Mariana Trench from 20 January to 5 February 2017 with baited
traps for the capture of fish and other macrobiology near the Challenger
and Sirena Deeps. On 29 January they recovered photography and samples
of a new species of snailfish from the Northern slope of the Challenger
Deep at 7,581 metres (24,872 ft), which has been newly designated Pseudoliparis swirei.
2017 – RV Kexue 3
Water samples were collected at Challenger Deep from 11 layers of the
Mariana Trench in March 2017. Seawater samples from 4 to 4,000 m were
collected by Niskin bottles mounted to a Seabird SBE25 CTDs; whereas
water samples at depths from 6,050 m to 8,320 m were collected by a
self-designed acoustic-controlled full ocean depth water samplers. In
this study, scientists studied the RNA of pico- and nano-plankton from
the surface to the hadal zone.
2017 – RV Kairei
JAMSTEC deployed Kairei to the Challenger Deep in May 2017 for the express purpose of testing the new full-ocean depth ROV UROV11K
(Underwater ROV 11,000-meter-capable), as cruise KR 17-08C, under chief
scientist Takashi Murashima. The cruise title was: "Sea trial of a full
depth ROV UROV11K system in the Mariana Trench". UROV11K carried a new 4K High Definition
video camera system, and new sensors to monitor the hydrogen-sulfide,
methane, oxygen, and hydrogen content of the water. Unfortunately, on UROV11K's ascent from 10,899 metres (35,758 ft) (at about 11°22.30'N 142°35.8 E, in the eastern
basin) on 14 May 2017, the ROV's buoyancy failed at 5,320 metres
(17,454 ft) depth, and all efforts to retrieve the ROV were
unsuccessful. The rate of descent and drift is not available, but the
ROV bottomed to the east of the deepest waters of the eastern basin as
revealed by the ship's maneuvering on 14 May. Murashima then directed
the Kairei to a location about 35 nmi east of the eastern basin of the
Challenger Deep to test a new "Compact Hadal Lander" which made three
descents to depths from 7,498 to 8,178 m for testing the Sony 4K camera
and for photography of fish and other macro-biologics.
2018 – RV Shen Kuo
On its maiden voyage, the 2,150-ton twin-hulled scientific research vessel Shen Kuo (also Shengkuo, Shen Ko, or Shen Quo),
departed Shanghai on 25 November 2018 and returned on 8 January 2019.
They operated in the Mariana Trench area, and on 13 December tested a
system of underwater navigation at a depth exceeding 10,000 metres,
during a field trial of the Tsaihungyuy (ultra-short baseline)
system. Project leader Tsui Veichen stated that, with the Tsaihungyuy
equipment at depth, it was possible to obtain a signal and determine
exact geolocations. The research team from Shanghai Ocean University and Westlake University was led by Cui Weicheng, director of Shanghai Ocean University's Hadal Science and Technology Research Center (HSRC). The equipment to be tested included a piloted submersible (not full
ocean depth – depth achieved not available) and two deep-sea landers,
all capable of diving to depths of 10,000 meters, as well as an ROV that
can go to 4,500 meters. They took photographs and obtained samples from
the trench, including water, sediment, macro-organisms and
micro-organisms. Cui says, "If we can take photos of fish more than
8,145 meters under water, ... we will break the current world record. We
will test our new equipment including the landing devices. They are
second generation. The first generation could only take samples in one
spot per dive, but this new second generation can take samples at
different depths in one dive. We also tested the ultra short baseline
acoustic positioning system on the manned submersible, the future of
underwater navigation."
2019 – RV Sally Ride
General Oceanographic RV Sally Ride
In November 2019, as cruise SR1916, a NIOZ team led by chief scientist Hans van Haren, with Scripps technicians, deployed to the Challenger Deep aboard the 2,641-ton research vessel Sally Ride,
to recover a mooring line from the western basin of the Challenger
Deep. The 7 km (4.3 mi) long mooring line in the Challenger Deep
consisted of top-floatation positioned around 4 km (2.5 mi) depth, two
sections of Dyneema neutrally buoyant 6 mm (0.2 in) line, two Benthos
acoustic releases and two sections of self-contained instrumentation to
measure and store current, salinity and temperature. Around the 6 km
(3.7 mi) depth position two current meters were mounted below a 200 m
(656 ft) long array of 100 high-resolution temperature sensors. In the
lower position starting 600 m (1,969 ft) above the sea floor 295
specially designed high-resolution temperature sensors were mounted, the
lowest of which was 8 m (26 ft) above the trench floor. The mooring
line was deployed and left by the NIOZ team during the November 2016 RV Sonne expedition with the intention to be recovered in late 2018 by Sonne. The acoustic commanded release mechanism near the bottom of the Challenger Deep failed at the 2018 attempt. RV Sally Ride was made available exclusively for a final attempt to retrieve the mooring line before the release mechanism batteries expired. Sally Ride arrived at the Challenger Deep on 2 November. This time a 'deep release unit' lowered by one of Sally Ride's
winch-cables to around 1,000 m depth pinged release commands and
managed to contact the near-bottom releases. After being submerged for
nearly three years, mechanical problems occurred in 15 of the 395
temperature sensors. The first results indicate the occurrence of internal waves in the Challenger Deep.
Study of the depth and location of the Challenger Deep
Since May 2000, with the help of non-degraded signal satellite navigation,
civilian surface vessels equipped with professional dual-frequency
capable satellite navigation equipment can measure and establish their
geodetic position with an accuracy in the order of meters to tens of
meters whilst the western, central and eastern basins are kilometers
apart.
GEBCO 2019 bathymetry of the Challenger Deep and Sirena Deep. (a)
Mariana Trench multibeam bathymetry data gridded at 75 m acquired
on-board the DSSV Pressure Drop overtop the GEBCO 2019 source grid (as
shown in Figure 1) and the complete GEBCO 2019 grid with hillshade. EM
124 black contours at 500 m intervals, GEBCO 2019 grey contours at 1,000
m intervals. The white circle indicates the deepest point and
submersible dive location, the white triangle indicates the submersible
dive location from Sirena Deep, the red spot was the deepest point
derived by van Haren et al., (2017). (b) Challenger Deep. (c) Sirena Deep. Bathymetric cross sections A'–A" and B'–B" over Challenger Deep and Sirena Deep displayed in (d) and (e), respectively.
In 2014, a study was conducted regarding the determination of the
depth and location of the Challenger Deep based on data collected
previous to and during the 2010 sonar mapping of the Mariana Trench with
a Kongsberg Maritime EM 122 multibeam echosounder system aboard USNS Sumner.
This study by James. V. Gardner et al. of the Center for Coastal &
Ocean Mapping-Joint Hydrographic Center (CCOM/JHC), Chase Ocean
Engineering Laboratory of the University of New Hampshire splits the
measurement attempt history into three main groups: early single-beam
echo sounders (1950s–1970s), early multibeam echo sounders (1980s – 21st
century), and modern (i.e., post-GPS, high-resolution) multibeam echo
sounders. Taking uncertainties in depth measurements and position
estimation into account, the raw data of the 2010 bathymetry of the
Challenger Deep vicinity consisting of 2,051,371 soundings from eight
survey lines was analyzed. The study concludes that with the best of
2010 multibeam echosounder technologies after the analysis a depth
uncertainty of ±25 m (82 ft) (95% confidence level) on 9 degrees of
freedom and a positional uncertainty of ±20 to 25 m (66 to 82 ft) (2drms) remain and the location of the deepest depth recorded in the 2010 mapping is 10,984 m (36,037 ft) at 11.329903°N 142.199305°E.
The depth measurement uncertainty is a composite of measured
uncertainties in the spatial variations in sound-speed through the water
volume, the ray-tracing and bottom-detection algorithms of the
multibeam system, the accuracies and calibration of the motion sensor
and navigation systems, estimates of spherical spreading, attenuation
throughout the water volume, and so forth.
Both the RV Sonne expedition in 2016, and the RV Sally Ride
expedition in 2019 expressed strong reservations concerning the depth
corrections applied by the Gardner et al. study of 2014, and serious
doubt concerning the accuracy of the deepest depth calculated by Gardner
(in the western basin), of 10,984 m (36,037 ft) after analysis
of their multibeam data on a 100 m (328 ft) grid. Dr. Hans van Haren,
chief scientist on the RV Sally Ride cruise SR1916, indicated
that Gardner's calculations were 69 m (226 ft) too deep due to the
"sound velocity profiling by Gardner et al. (2014)."
In 2018-2019, the deepest points of each ocean were mapped using a
full-ocean depth Kongsberg EM 124 multibeam echosounder aboard DSSV Pressure Drop.
In 2021, a data paper was published by Cassandra Bongiovanni, Heather
A. Stewart and Alan J. Jamieson regarding the gathered data donated to
GEBCO. The deepest depth recorded in the 2019 Challenger Deep sonar
mapping was 10,924 m (35,840 ft) ±15 m (49 ft) at 11.369°N 142.587°E
in the eastern basin. This depth closely agrees with the deepest point
(10,925 m (35,843 ft) ±12 m (39 ft)) determined by the Van Haren et al.
sonar bathymetry. The geodetic position of the deepest depth according
to the Van Haren et al. significantly differs (about 42 km (26 mi) to
the west) with the 2021 paper. After post-processing the initial depth
estimates by application of a full-ocean depth sound velocity profile
Bongiovanni et al. report an (almost) as deep point at 11.331°N 142.205°E
in the western basin that geodetically differs about 350 m (1,150 ft)
with the deepest point position determined by Van Haren et al. (11.332417°N 142.20205°E
in the western basin). After analysis of their multibeam data on a 75 m
(246 ft) grid, the Bongiovanni et al. 2021 paper states the
technological accuracy does not currently exist on low-frequency
ship-mounted sonars required to determine which location was truly the
deepest, nor does it currently exist on deep-sea pressure sensors.
In 2021, a study by Samuel F. Greenaway, Kathryn D. Sullivan,
Samuel H. Umfress, Alice B. Beittel and Karl D. Wagner was published
presenting a revised estimate of the maximum depth of the Challenger
Deep based on a series of submersible dives conducted in June 2020.
These depth estimates are derived from acoustic echo sounding profiles
referenced to in-situ direct pressure measurements and corrected for
observed oceanographic properties of the water-column, atmospheric
pressure, gravity and gravity-gradient anomalies, and water-level
effects. The study concludes according to their calculations the deepest
observed seafloor depth was 10,935 m (35,876 ft) ±6 m (20 ft) below
mean sea level at a 95% confidence level at 11°22.3′N142°35.3′E
in the eastern basin. For this estimate, the error term is dominated by
the uncertainty of the employed pressure sensor, but Greenaway et al.
show that the gravity correction is also substantial. The Greenaway et
al. study compares its results with other recent acoustic and
pressure-based measurements for the Challenger Deep and concludes the
deepest depth in the western basin is very nearly as deep as the eastern
basin. The disagreement between the maximum depth estimates and their
geodetic positions between post-2000 published depths however exceed the
accompanying margins of uncertainty, raising questions regarding the
measurements or the reported uncertainties.
Another 2021 paper by Scott Loranger, David Barclay and Michael
Buckingham, besides a December 2014 implosion shock wave based depth
estimate of 10,983 m (36,033 ft), which is among the deepest estimated
depths, also treatises the differences between various maximum depth
estimates and their geodetic positions.
Direct measurements
The 2010 maximal sonar mapping depths reported by Gardner et al. in
2014 and Greenaway et al. study in 2021 have not been confirmed by
direct descent (pressure gauge/manometer) measurements at full-ocean
depth. Expeditions have reported direct measured maximal depths in a narrow range.
For the western basin deepest depths were reported as 10,913 m (35,804 ft) by Trieste in 1960 and 10,923 m (35,837 ft) ±4 m (13 ft) by DSV Limiting Factor in June 2020.
For the central basin the greatest reported depth is 10,915 m (35,810 ft) ±4 m (13 ft) by DSV Limiting Factor in June 2020.
For the eastern basin deepest depths were reported as 10,911 m (35,797 ft) by Kaikō ROV in 1995, 10,902 m (35,768 ft) by ROV Nereus in 2009, 10,908 m (35,787 ft) by Deepsea Challenger in 2012, 10,929 m (35,856 ft) by benthic lander "Leggo" in May 2019, and 10,925 m (35,843 ft) ±4 m (13 ft) by DSV Limiting Factor in May 2019.
Descents
Crewed descents
Bathyscaphe Trieste.
The spherical crew cabin is attached to the underside of a tank filled
with gasoline (which is incompressible), which serves as a float giving
the craft buoyancy.Lt. Don Walsh, USN (bottom) and Jacques Piccard (middle) in the Trieste
On 23 January 1960, the Swiss-designed Trieste, originally built in Italy and acquired by the U.S. Navy, supported by the USS Wandank (ATF 204) and escorted by the USS Lewis (DE 535), descended to the ocean floor in the trench piloted by Jacques Piccard (who co-designed the submersible along with his father, Auguste Piccard) and USN Lieutenant Don Walsh.
Their crew compartment was inside a spherical pressure vessel –
measuring 2.16 metres in diameter suspended beneath a buoyancy tank 18.4
metres in length – which was a heavy-duty replacement (of the Italian original) built by Krupp Steel Works of Essen,
Germany. The steel walls were 12.7 cm (5.0 in) thick and designed to
withstand pressure of up to 1250 kilograms per square centimetre
(17800 psi; 1210 atm; 123 MPa). Their descent took almost five hours and the two men spent barely twenty
minutes on the ocean floor before undertaking the
three-hour-and-fifteen-minute ascent. Their early departure from the ocean floor was due to their concern over a crack in the outer window caused by the temperature differences during their descent.
Trieste dived at/near 11°18.5′N142°15.5′E, bottoming at 10,911 metres (35,797 ft) ±7 m (23 ft) into the Challenger Deep's western basin, as measured by an onboard manometer. Another source states the measured depth at the bottom was measured with a manometer at 10,913 m (35,804 ft) ±5 m (16 ft). Navigation of the support ships was by celestial and LORAN-C with an accuracy of 460 metres (1,510 ft) or less. Fisher noted that the Trieste's reported depth "agrees well with the sonic sounding."
On 26 March 2012 (local time), Canadian film director James Cameron made a solo descent in the DSVDeepsea Challenger to the bottom of the Challenger Deep. At approximately 05:15 ChST on 26 March (19:15 UTC on 25 March), the descent began. At 07:52 ChST (21:52 UTC), Deepsea Challenger arrived at the bottom. The descent lasted 2 hours and 36 minutes and the recorded depth was 10,908 metres (35,787 ft) when Deepsea Challenger touched down. Cameron had planned to spend about six hours near the ocean floor
exploring but decided to start the ascent to the surface after only 2
hours and 34 minutes. The time on the bottom was shortened because a hydraulic fluid leak in
the lines controlling the manipulator arm obscured the visibility out of
the only viewing port. It also caused the loss of the submersible's
starboard thrusters. At around 12:00 ChST (02:00 UTC on 26 March), the Deepsea Challenger website says the sub resurfaced after a 90-minute ascent, although Paul Allen's tweets indicate the ascent took only about 67 minutes. During a post-dive press conference Cameron said: "I landed on a very
soft, almost gelatinous flat plain. Once I got my bearings, I drove
across it for quite a distance ... and finally worked my way up the
slope." The whole time, Cameron said, he didn't see any fish, or any
living creatures more than an inch (2.54 cm) long: "The only free
swimmers I saw were small amphipods" – shrimplike bottom-feeders.
2019 – Five Deeps Expedition / DSV Limiting Factor
DSSV Pressure Drop and DSV Limiting Factor at its sternThe landers Skaff and Closp are prepared for a deployment during the Five Deeps Expedition.
The Five Deeps Expedition's objective was to thoroughly map and visit
the deepest points of all five of the world's oceans by the end of
September 2019. On 28 April 2019, explorer Victor Vescovo descended to the "Eastern Pool" of the Challenger Deep in the Deep-Submergence Vehicle Limiting Factor (a Triton 36000/2 model submersible). Between 28 April and 4 May 2019, the Limiting Factor
completed four dives to the bottom of Challenger Deep. The fourth dive
descended to the slightly less deep "Central Pool" of the Challenger
Deep (crew: Patrick Lahey, Pilot; John Ramsay, Sub Designer). The Five
Deeps Expedition estimated maximum depths of 10,927 m (35,850 ft) ±8 m
(26 ft) and 10,928 m (35,853 ft) ±10.5 m (34 ft) at (11.3693°N 142.5889°E) by direct CTD pressure measurements and a survey of the operating area by the support ship, the Deep Submersible Support Vessel DSSV Pressure Drop,
with a Kongsberg SIMRAD EM124 multibeam echosounder system. The CTD
measured pressure at 10,928 m (35,853 ft) of seawater depth was
1,126.79 bar (112.679 MPa; 16,342.7 psi). Due to a technical problem the (uncrewed) ultra-deep-sea lander Skaff used by the Five Deeps Expedition stayed on the bottom for two and half days before it was salvaged by the Limiting Factor (crew: Patrick Lahey, Pilot; Jonathan Struwe, DNV GL Specialist) from an estimated depth of 10,927 m (35,850 ft). The gathered data was published with the caveat that it was subject to
further analysis and could possibly be revised in the future. The data
will be donated to the GEBCO Seabed 2030 initiative.Later in 2019, following a review of bathymetric data, and multiple sensor recordings taken by the DSV Limiting Factor and the ultra-deep-sea landers Closp, Flere and Skaff, the Five Deeps Expedition revised the maximum depth to 10,925 m (35,843 ft) ±4 m (13 ft).
2020 – Ring of Fire Expedition / DSV Limiting Factor
Caladan Oceanic's "Ring of Fire" expedition in the Pacific included
six manned descents and twenty-five lander deployments into all three
basins of the Challenger Deep all piloted by Victor Vescovo and further topographical and marine life survey of the entire Challenger Deep. The expedition craft used are the Deep Submersible Support Vessel DSSV Pressure Drop, Deep-Submergence Vehicle DSV Limiting Factor and the ultra-deep-sea landers Closp, Flere and Skaff.
During the first manned dive on 7 June 2020 Victor Vescovo and former US astronaut (and former NOAA Administrator) Kathryn D. Sullivan descended to the "Eastern Pool" of the Challenger Deep in the Deep-Submergence Vehicle Limiting Factor.
On 12 June 2020, Victor Vescovo and mountaineer and explorer Vanessa O'Brien
descended to the "Eastern Pool" of the Challenger Deep spending three
hours mapping the bottom. O'Brien said her dive scanned about a mile of
desolate bottom terrain, finding that the surface is not flat, as once
was thought, but sloping by about 18 ft (5.5 m) per mile, subject to verification. On 14 June 2020, Victor Vescovo and John Rost descended to the "Eastern
Pool" of the Challenger Deep in the Deep-Submergence Vehicle Limiting Factor spending four hours at depth and transiting the bottom for nearly 2 miles. On 20 June 2020, Victor Vescovo and Kelly Walsh descended to the
"Western Pool" of the Challenger Deep in the Deep-Submergence Vehicle Limiting Factor spending four hours at the bottom. They reached a maximum depth of 10,923 m (35,837 ft). Kelly Walsh is the son of the Trieste's captain Don Walsh who descended there in 1960 with Jacques Piccard. On 21 June 2020, Victor Vescovo and Woods Hole Oceanographic Institution
researcher Ying-Tsong Lin descended to the "Central Pool" of the
Challenger Deep in the Deep-Submergence Vehicle Limiting Factor. They reached a maximum depth of 10,915 m (35,810 ft) ±4 m (13 ft). On 26 June 2020 Victor Vescovo and Jim Wigginton descended to the
"Eastern Pool" of the Challenger Deep in the Deep-Submergence Vehicle Limiting Factor.
Fendouzhe (奋斗者, Striver) is a manned Chinese
deep-sea submersible developed by the China Ship Scientific Research
Center (CSSRC). Between 10 October and 28 November, 2020, it carried out
thirteen dives in the Mariana Trench as part of a test programme. Of
these, eight led to depths of more than 10,000 m (32,808 ft). On 10
November 2020, the bottom of the Challenger Deep was reached by Fendouzhe
with three Chinese scientists (Zhāng Wěi 张伟 [pilot], Zhào Yáng 赵洋, and
Wáng Zhìqiáng 王治强) onboard whilst live-streaming the descent to a
reported depth of 10,909 m (35,791 ft). This makes the Fendouzhe the fourth manned submersible vehicle achieving a successful descent. The pressure hull of Fendouzhe, made from a newly developed titanium alloy, offers space for three people in addition to technical equipment. Fendouzhe is equipped with cameras made by the Norwegian manufacturer Imenco. According to Ye Cong 叶聪, the chief designer of the submersible, China's
goals for the dive aren't just scientific investigation but also the
future use of deep-sea seabed resources.
2021 – Ring of Fire 2 Expedition / DSV Limiting Factor
On 28 February 2021 Caladan Oceanic's "Ring of Fire 2" expedition
arrived over the Challenger Deep and conducted manned descents and
lander deployments into the Challenger Deep. At the start the (uncrewed) ultra-deep-sea lander Skaff
was deployed to collect water column data by CTD for the expedition.
The effects of the Pacific subducting plate crashing into the Philippine
Plate was among the things researched onsite.
On 1 March 2021, the first manned descent to the eastern pool was made
by Victor Vescovo and Richard Garriott. Garriott became the 17th person to descend to the bottom. On 2 March 2021, a descent to the eastern pool was made by Victor Vescovo and Michael Dubno. On 5 March a descent to the eastern pool was made by Victor Vescovo and Hamish Harding. They traversed the bottom of Challenger Deep. On 11 March 2021 a descent to the Western Pool was made by Victor Vescovo and marine botanist Nicole Yamase. On 13 April 2021 a descent was made by deep water submersible operations expert Rob McCallum and Tim Macdonald who piloted the dive. A 2021 descent with a Japanese citizen is planned. All manned descents were conducted in the Deep-Submergence Vehicle DSV Limiting Factor.
2022 - Ring of Fire 3 Expedition / DSV Limiting Factor
Dawn Wright and Victor Vescovo aboard DSV Limiting Factor during their July 2022 dive into the Western Pool
Southern wall of the Western Pool
In July 2022 for the fourth consecutive year, Caladan Oceanic's deep submergence system, consisting of the deep submersible DSV Limiting Factor supported by the mother ship DSSV Pressure Drop, returned to the Challenger Deep for dives into the Challenger Deep. In early July 2022, Victor Vescovo was joined by Aaron Newman as a mission specialist for a dive into the Central pool. On 5 July 2022, Tim Macdonald as pilot and Jim Kitchen as mission specialist for a dive into the Eastern pool. On 8 July 2022 Victor Vescovo was joined by Dylan Taylor as mission specialist for a dive into the Eastern pool. Victor Vescovo (for his 15th dive into the Challenger Deep) was joined by geographer and oceanographer Dawn Wright as mission specialist on the 12 July 2022 dive to 10,919 m (35,823 ft) in the Western Pool. Wright operated the world's first sidescan sonar to ever operate at
full-ocean depth to capture detailed imagery along short transects of
the southern wall of the Western Pool.
The remotely operated vehicle (ROV) Kaikō made many uncrewed descents to the Mariana Trench from its support ship RV Yokosuka during two expeditions in 1996 and 1998. From 29 February to 4 March the ROV Kaiko made three dives into the central basin, Kaiko #21 – Kaiko #23, . Depths ranged from 10,898 metres (35,755 ft) at 11°22.536′N142°26.418′E, to 10,896 metres (35,748 ft) at 11°22.59′N142°25.848′E; dives #22 & #23 to the north, and dive #21 northeast of the deepest waters of the central basin. During the 1996 measurements the temperature (water temperature increases at great depth due to adiabatic compression), salinity
and water pressure at the sampling station was 2.6 °C (36.7 °F), 34.7‰
and 1,113 bar (111.3 MPa; 16,140 psi), respectively at 10,897 m
(35,751 ft) depth. The Japanese robotic deep-sea probe Kaikō broke the depth record for uncrewed probes when it reached close to the surveyed bottom of the Challenger Deep. Created by the Japan Agency for Marine-Earth Science and Technology (JAMSTEC),
it was one of the few uncrewed deep-sea probes in operation that could
dive deeper than 6,000 metres (20,000 ft). The manometer measured depth
of 10,911.4 m (35,799 ft) ±3 m (10 ft) at 11°22.39′N142°35.54′E for the Challenger Deep is believed to be the most accurate measurement taken up to then. Another source states the greatest depth measured by Kaikō in 1996 was 10,898 m (35,755 ft) at 11°22.10′N142°25.85′E and 10,907 m (35,784 ft) at 11°22.95′N142°12.42′E in 1998. The ROV Kaiko was the first vehicle to visit to the bottom of the Challenger Deep since the bathyscaph Trieste's dive in 1960, and the first success in sampling the trench bottom sediment/mud, from which Kaiko obtained over 360 samples. Approximately 3,000 different microbes were identified in the samples. Kaikō was lost at sea off Shikoku Island during Typhoon Chan-Hom on 29 May 2003.
From 2 May to 5 June 2009, the RV Kilo Moana hosted the Woods Hole Oceanographic Institution (WHOI) hybrid remotely operated vehicle (HROV) Nereus team for the first operational test of the Nereus in its 3-ton tethered ROV mode. The Nereus team was headed by the Expedition Leader Andy Bowen of WHOI, Louis Whitcomb of Johns Hopkins University,
and Dana Yoerger, also of WHOI. The expedition had co-chief scientists:
biologist Tim Shank of WHOI, and geologist Patricia Fryer of the
University of Hawaiʻi, to head the science team exploiting the ship's bathymetry and organizing the science experiments deployed by the Nereus. From Nereus dive #007ROV to 880 m (2,887 ft) just south of Guam, to dive #010ROV into the Nero Deep at 9,050 m (29,692 ft), the testing gradually increased depths and complexities of activities at the bottom.
Dive #011ROV, on 31 May 2009, saw the Nereus piloted on a 27.8-hour underwater mission, with about ten hours transversing the eastern
basin of the Challenger Deep – from the south wall, northwest to the
north wall – streaming live video and data back to its mothership. A
maximum depth of 10,902 m (35,768 ft) was registered at 11°22.10′N142°35.48′E. The RV Kilo Moana then relocated to the western
basin, where a 19.3-hour underwater dive found a maximum depth of
10,899 m (35,758 ft) on dive #012ROV, and on dive #014ROV in the same
area (11°19.59 N, 142°12.99 E) encountered a maximum depth of 10,176 m
(33,386 ft). The Nereus was successful in recovering both sediment and rock samples from the eastern and the western
basins with its manipulator arm for further scientific analysis. The
HROV's final dive was about 80 nmi (148.2 km) to the north of the
Challenger Deep, in the backarc, where they dived 2,963 m (9,721 ft) at the TOTO Caldera (12°42.00 N, 143°31.5 E). Nereus thus became the first vehicle to reach the Mariana Trench since 1998 and the deepest-diving vehicle then in operation. Project manager and developer Andy Bowen heralded the achievement as "the start of a new era in ocean exploration". Nereus, unlike Kaikō, did not need to be powered or controlled by a cable connected to a ship on the ocean surface. The HROV Nereus was lost on 10 May 2014 while conducting a dive at 9,900 metres (32,500 ft) in depth in the Kermadec Trench.
In June 2008, the Japan Agency for Marine-Earth Science and Technology (JAMSTEC) deployed the research vessel Kairei to the area of Guam for cruise KR08-05 Leg 1 and Leg 2.
On 1–3 June 2008, during Leg 1, the Japanese robotic deep-sea probe ABISMO
(Automatic Bottom Inspection and Sampling Mobile) on dives 11–13 almost
reached the bottom about 150 km (93 mi) east of the Challenger Deep:
"Unfortunately, we were unable to dive to the sea floor because the
legacy primary cable of the Kaiko system was a little bit short. The 2-m
long gravity core sampler was dropped in free fall, and sediment
samples of 1.6m length were obtained. Twelve bottles of water samples
were also obtained at various depths..." ABISMO's dive #14 was into the
TOTO caldera (12°42.7777 N, 143°32.4055 E), about 60 nmi northeast of
the deepest waters of the central basin of the Challenger Deep, where they obtained videos of the hydrothermal plume. Upon successful testing to 10,000 m (32,808 ft), JAMSTEC' ROV ABISMO
became, briefly, the only full-ocean-depth rated ROV in existence. On
31 May 2009, the ABISMO was joined by the Woods Hole Oceanographic
Institution's HROV Nereus as the only two operational full ocean depth capable remotely operated vehicles in existence. During the ROV ABISMO's deepest sea trails dive its manometer measured a depth of 10,257 m (33,652 ft) ±3 m (10 ft) in "Area 1" (vicinity of 12°43' N, 143°33' E).
Leg 2, under chief scientist Takashi Murashima, operated at the
Challenger Deep 8–9 June 2008, testing JAMSTEC's new full ocean depth
"Free Fall Mooring System," i.e. a lander. The lander was successfully tested twice to 10,895 m (35,745 ft) depth, taking video images and sediment samplings at 11°22.14′N142°25.76′E, in the central basin of the Challenger Deep.
2016 – Haidou-1
On 23 May 2016, the Chinese submersible Haidou-1 dived to a
depth of 10,767 m (35,325 ft) at an undisclosed position in the Mariana
Trench, making China the third country after Japan (ROV Kaikō), and the US (HROV Nereus), to deploy a full-ocean-depth ROV. This autonomous and remotely operated vehicle has a design depth of 11,000 m (36,089 ft).
2020 – Vityaz-D
On 8 May 2020, the Russian submersible Vityaz-D dived to a depth of 10,028 m (32,900 ft) at an undisclosed position in the Mariana Trench.
Lifeforms
The summary report of the HMS Challenger expedition lists unicellular life forms from the two dredged samples taken when the Challenger Deep was first discovered. These (Nassellaria and Spumellaria) were reported in the Report on Radiolaria (1887) written by Ernst Haeckel.
On their 1960 descent, the crew of the Trieste noted that the floor consisted of diatomaceous ooze and reported observing "some type of flatfish" lying on the seabed.
And as we were settling this final fathom, I saw a wonderful thing. Lying on the bottom just beneath us was some type of flatfish, resembling a sole,
about 1 foot [30 cm] long and 6 inches [15 cm] across. Even as I saw
him, his two round eyes on top of his head spied us – a monster of
steel – invading his silent realm. Eyes? Why should he have eyes? Merely
to see phosphorescence? The floodlight that bathed him was the first
real light ever to enter this hadal realm. Here, in an instant, was the
answer that biologists had asked for the decades. Could life exist in
the greatest depths of the ocean? It could! And not only that, here
apparently, was a true, bony teleost fish, not a primitive ray or elasmobranch.
Yes, a highly evolved vertebrate, in time's arrow very close to man
himself. Slowly, extremely slowly, this flatfish swam away. Moving along
the bottom, partly in the ooze and partly in the water, he disappeared
into his night. Slowly too – perhaps everything is slow at the bottom of
the sea – Walsh and I shook hands.
Many marine biologists are now skeptical of this supposed sighting,
and it is suggested that the creature may instead have been a sea cucumber. The video camera on board the Kaiko probe spotted a sea cucumber, a scale worm and a shrimp at the bottom.At the bottom of the Challenger Deep, the Nereus probe spotted one polychaete worm (a multi-legged predator) about an inch long.
An analysis of the sediment samples collected by Kaiko found large numbers of simple organisms at 10,900 m (35,800 ft). While similar lifeforms have been known to exist in shallower ocean trenches (> 7,000 m) and on the abyssal plain, the lifeforms discovered in the Challenger Deep possibly represent taxa distinct from those in shallower ecosystems.
Most of the organisms collected were simple, soft-shelled foraminifera (432 species according to National Geographic), with four of the others representing species of the complex, multi-chambered genera Leptohalysis [es] and Reophax [es]. Eighty-five per cent of the specimens were organic, soft-shelled allogromiids, which is unusual compared to samples of sediment-dwelling organisms from other deep-sea environments, where the percentage of organic-walled foraminifera
ranges from 5% to 20%. As small organisms with hard, calcareous shells
have trouble growing at extreme depths because of the high solubility of
calcium carbonate
in the pressurized water, scientists theorize that the preponderance of
soft-shelled organisms in the Challenger Deep may have resulted from
the typical biosphere
present when the Challenger Deep was shallower than it is now. Over the
course of six to nine million years, as the Challenger Deep grew to its
present depth, many of the species present in the sediment died out or
were unable to adapt to the increasing water pressure and changing
environment.
On 17 March 2013, researchers reported data that suggested piezophilic microorganisms thrive in the Challenger Deep. Other researchers reported related studies that microbes thrive inside
rocks up to 579 m (1,900 ft) below the sea floor under 2,591 m
(8,500 ft) of ocean off the coast of the northwestern United States. According to one of the researchers, "You can find microbes
everywhere – they're extremely adaptable to conditions, and survive
wherever they are."
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