Microbiology

From Wikipedia, the free encyclopedia

An agar plate streaked with microorganisms

Microbiology (from Greek μῑκρος, mīkros, "small"; βίος, bios, "life"; and -λογία, -logia) is the study of microscopic organisms, either unicellular (single cell), multicellular (cell colony), or acellular (lacking cells).^[1] Microbiology encompasses numerous sub-disciplines including virology, mycology, parasitology, and bacteriology.

Eukaryotic microorganisms possess membrane-bound cell organelles and include fungi and protists, whereas prokaryotic organisms—which all are microorganisms—are conventionally classified as lacking membrane-bound organelles and include eubacteria and archaebacteria. Microbiologists traditionally relied on culture, staining, and microscopy. However, less than 1% of the microorganisms present in common environments can be cultured in isolation using current means.^[2] Microbiologists often rely on extraction or detection of nucleic acid, either DNA or RNA sequences.

Viruses have been variably classified as organisms,^[3] as they have been considered either as very simple microorganisms or very complex molecules. Prions, never considered microorganisms, have been investigated by virologists, however, as the clinical effects traced to them were originally presumed due to chronic viral infections, and virologists took search—discovering "infectious proteins".

As an application of microbiology, medical microbiology is often introduced with medical principles of immunology as microbiology and immunology. Otherwise, microbiology, virology, and immunology as basic sciences have greatly exceeded the medical variants, applied sciences.^[4][5][6]

Branches

The branches of microbiology can be classified into pure and applied sciences.^[7] Microbiology can be also classified based on taxonomy, in the cases of bacteriology, mycology, protozoology, and phycology. There is considerable overlap between the specific branches of microbiology with each other and with other disciplines, and certain aspects of these branches can extend beyond the traditional scope of microbiology.

Pure microbiology

Taxonomic arrangement

• Bacteriology: The study of bacteria.
• Mycology: The study of fungi.
• Protozoology: The study of protozoa.
• Phycology/algology: The study of algae.
• Parasitology: The study of parasites.
• Immunology: The study of the immune system.
• Virology: The study of viruses.
• Nematology: The study of nematodes.

Integrative arrangement

• Microbial cytology: The study of microscopic and submicroscopic details of microorganisms.
• Microbial physiology: The study of how the microbial cell functions biochemically. Includes the study of microbial growth, microbial metabolism and microbial cell structure.
• Microbial ecology: The relationship between microorganisms and their environment.
• Microbial genetics: The study of how genes are organized and regulated in microbes in relation to their cellular functions. Closely related to the field of molecular biology.
• Cellular microbiology: A discipline bridging microbiology and cell biology.
• Evolutionary microbiology: The study of the evolution of microbes. This field can be subdivided into:
  • Microbial taxonomy: The naming and classification of microorganisms.
  • Microbial systematic: The study of the diversity and genetic relationship of microorganisms.
• Generation microbiology: The study of those microorganisms that have the same characters as their parents.
• Systems microbiology: A discipline bridging systems biology and microbiology.
• Molecular microbiology: The study of the molecular principles of the physiological processes in microorganisms.

Other

• Nano microbiology: The study of those organisms on nano level.
• Exo microbiology (or Astro microbiology): The study of microorganisms in outer space (see: List of microorganisms tested in outer space)
• Biological agent: The study of those microorganisms which are being used in weapon industries.

Applied microbiology

• Medical microbiology: The study of the pathogenic microbes and the role of microbes in human illness. Includes the study of microbial pathogenesis and epidemiology and is related to the study of disease pathology and immunology.
• Pharmaceutical microbiology: The study of microorganisms that are related to the production of antibiotics, enzymes, vitamins,vaccines, and other pharmaceutical products and that cause pharmaceutical contamination and spoil.
• Industrial microbiology: The exploitation of microbes for use in industrial processes. Examples include industrial fermentation and wastewater treatment. Closely linked to the biotechnology industry. This field also includes brewing, an important application of microbiology.
• Microbial biotechnology: The manipulation of microorganisms at the genetic and molecular level to generate useful products.
• Food microbiology: The study of microorganisms causing food spoilage and foodborne illness. Using microorganisms to produce foods, for example by fermentation.
• Agricultural microbiology: The study of agriculturally relevant microorganisms. This field can be further classified into the following:
  • Plant microbiology and Plant pathology: The study of the interactions between microorganisms and plants and plant pathogens.
  • Soil microbiology: The study of those microorganisms that are found in soil.
• Veterinary microbiology: The study of the role of microbes in veterinary medicine or animal taxonomy.
• Environmental microbiology: The study of the function and diversity of microbes in their natural environments. This involves the characterization of key bacterial habitats such as the rhizosphere and phyllosphere, soil and groundwater ecosystems, open oceans or extreme environments (extremophiles). This field includes other branches of microbiology such as:
  • Microbial ecology
  • Microbially mediated nutrient cycling
  • Geomicrobiology
  • Microbial diversity
  • Bioremediation
• Water microbiology (or Aquatic microbiology): The study of those microorganisms that are found in water.
• Aeromicrobiology (or Air microbiology): The study of airborne microorganisms.

Benefits

Fermenting tanks with yeast being used to brew beer

While some fear microbes due to the association of some microbes with various human illnesses, many microbes are also responsible for numerous beneficial processes such as industrial fermentation (e.g. the production of alcohol, vinegar and dairy products), antibiotic production and as vehicles for cloning in more complex organisms such as plants. Scientists have also exploited their knowledge of microbes to produce biotechnologically important enzymes such as Taq polymerase, reporter genes for use in other genetic systems and novel molecular biology techniques such as the yeast two-hybrid system.

Bacteria can be used for the industrial production of amino acids. Corynebacterium glutamicum is one of the most important bacterial species with an annual production of more than two million tons of amino acids, mainly L-glutamate and L-lysine.^[8]

A variety of biopolymers, such as polysaccharides, polyesters, and polyamides, are produced by microorganisms. Microorganisms are used for the biotechnological production of biopolymers with tailored properties suitable for high-value medical application such as tissue engineering and drug delivery. Microorganisms are used for the biosynthesis of xanthan, alginate, cellulose, cyanophycin, poly(gamma-glutamic acid), levan, hyaluronic acid, organic acids, oligosaccharides and polysaccharide, and polyhydroxyalkanoates.^[9]

Microorganisms are beneficial for microbial biodegradation or bioremediation of domestic, agricultural and industrial wastes and subsurface pollution in soils, sediments and marine environments. The ability of each microorganism to degrade toxic waste depends on the nature of each contaminant. Since sites typically have multiple pollutant types, the most effective approach to microbial biodegradation is to use a mixture of bacterial and fungal species and strains, each specific to the biodegradation of one or more types of contaminants.^[10]

Symbiotic microbial communities are known to confer various benefits to their human and animal hosts health including aiding digestion, production of beneficial vitamins and amino acids, and suppression of pathogenic microbes. Some benefit may be conferred by consuming fermented foods, probiotics (bacteria potentially beneficial to the digestive system) and/or prebiotics (substances consumed to promote the growth of probiotic microorganisms).^[11][12] The ways the microbiome influences human and animal health, as well as methods to influence the microbiome are active areas of research.^[13]

Research has suggested that microorganisms could be useful in the treatment of cancer. Various strains of non-pathogenic clostridia can infiltrate and replicate within solid tumors. Clostridial vectors can be safely administered and their potential to deliver therapeutic proteins has been demonstrated in a variety of preclinical models.^[14]

History

Ancient

The existence of microorganisms was hypothesized for many centuries before their actual discovery.
The existence of unseen microbiological life was postulated by Jainism which is based on Mahavira’s teachings as early as 6th century BCE.^[15] Paul Dundas notes that Mahavira asserted existence of unseen microbiological creatures living in earth, water, air and fire.^[16] Jain scriptures also describe nigodas which are sub-microscopic creatures living in large clusters and having a very short life and are said to pervade each and every part of the universe, even in tissues of plants and flesh of animals.^[17] The Roman Marcus Terentius Varro made references to microbes when he warned against locating a homestead in the vicinity of swamps "because there are bred certain minute creatures which cannot be seen by the eyes, which float in the air and enter the body through the mouth and nose and there by cause serious diseases."^{[18][citation needed]}

In the medieval Islamic world

Avicenna "ibn Sina"

At the golden age of Islamic civilization, some scientists had knowledge about microorganisms, such as Ibn Sina in his book The Canon of Medicine, Ibn Zuhr (also known as Avenzoar) who discovered scabies germs^{[clarification needed]}, and Al-Razi who spoke of parasites^{[clarification needed]} in his book The Virtuous Life (al-Hawi).^[19]

In 1546, Girolamo Fracastoro proposed that epidemic diseases were caused by transferable seedlike entities that could transmit infection by direct or indirect contact, or vehicle transmission.^[20]

However, early claims about the existence of microorganisms were speculative, and not based on microscopic observation. Actual observation and discovery of microbes had to await the invention of the microscope in the 17th century.

Modern

Anton van Leeuwenhoek, is considered to be the one of the first to observe microorganisms using a microscope.

In 1676, Anton van Leeuwenhoek, who lived for most of his life in Delft, Holland, observed bacteria and other microorganisms using a single-lens microscope of his own design.^[1] While Van Leeuwenhoek is often cited as the first to observe microbes, Robert Hooke made the first recorded microscopic observation, of the fruiting bodies of molds, in 1665.^[21] It has, however, been suggested that a Jesuit priest called Athanasius Kircher was the first to observe micro-organisms.^[22] He was among the first to design magic lanterns for projection purposes, so he must have been well acquainted with the properties of lenses.^[22] One of his books contains a chapter in Latin, which reads in translation – ‘Concerning the wonderful structure of things in nature, investigated by Microscope.’ Here, he wrote ‘who would believe that vinegar and milk abound with an innumerable multitude of worms.’ He also noted that putrid material is full of innumerable creeping animalcule. These observations antedate Robert Hooke’s Micrographia by nearly 20 years and were published some 29 years before van Leeuwenhoek saw protozoa and 37 years before he described having seen bacteria.^[22]

Innovative laboratory glassware and experimental methods developed by Louis Pasteur and other biologists contributed to the young field of bacteriology in the late 19th century.

The field of bacteriology (later a subdiscipline of microbiology) was founded in the 19th century by Ferdinand Cohn, a botanist whose studies on algae and photosynthetic bacteria led him to describe several bacteria including Bacillus and Beggiatoa. Cohn was also the first to formulate a scheme for the taxonomic classification of bacteria and discover spores.^[23] Louis Pasteur and Robert Koch were contemporaries of Cohn’s and are often considered to be the father of microbiology^[22] and medical microbiology, respectively.^[24] Pasteur is most famous for his series of experiments designed to disprove the then widely held theory of spontaneous generation, thereby solidifying microbiology’s identity as a biological science.^[25] Pasteur also designed methods for food preservation (pasteurization) and vaccines against several diseases such as anthrax, fowl cholera and rabies.^[1] Koch is best known for his contributions to the germ theory of disease, proving that specific diseases were caused by specific pathogenic micro-organisms. He developed a series of criteria that have become known as the Koch's postulates. Koch was one of the first scientists to focus on the isolation of bacteria in pure culture resulting in his description of several novel bacteria including Mycobacterium tuberculosis, the causative agent of tuberculosis.^[1]

While Pasteur and Koch are often considered the founders of microbiology, their work did not accurately reflect the true diversity of the microbial world because of their exclusive focus on micro-organisms having direct medical relevance. It was not until the late 19th century and the work of Martinus Beijerinck and Sergei Winogradsky, the founders of general microbiology (an older term encompassing aspects of microbial physiology, diversity and ecology), that the true breadth of microbiology was revealed.^[1] Beijerinck made two major contributions to microbiology: the discovery of viruses and the development of enrichment culture techniques.^[26] While his work on the Tobacco Mosaic Virus established the basic principles of virology, it was his development of enrichment culturing that had the most immediate impact on microbiology by allowing for the cultivation of a wide range of microbes with wildly different physiologies. Winogradsky was the first to develop the concept of chemolithotrophy and to thereby reveal the essential role played by micro-organisms in geochemical processes.^[27] He was responsible for the first isolation and description of both nitrifying and nitrogen-fixing bacteria.^[1] French-Canadian microbiologist Felix d'Herelle co-discovered bacteriophages and was one of the earliest applied microbiologists.^[28]

Green nanotechnology

From Wikipedia, the free encyclopedia

Green nanotechnology refers to the use of nanotechnology to enhance the environmental sustainability of processes producing negative externalities. It also refers to the use of the products of nanotechnology to enhance sustainability. It includes making green nano-products and using nano-products in support of sustainability.

Green nanotechnology has been described as the development of clean technologies, "to minimize potential environmental and human health risks associated with the manufacture and use of nanotechnology products, and to encourage replacement of existing products with new nano-products that are more environmentally friendly throughout their lifecycle."^[1]

Goals

Green nanotechnology has two goals: producing nanomaterials and products without harming the environment or human health, and producing nano-products that provide solutions to environmental problems. It uses existing principles of green chemistry and green engineering^[2] to make nanomaterials and nano-products without toxic ingredients, at low temperatures using less energy and renewable inputs wherever possible, and using lifecycle thinking in all design and engineering stages.

In addition to making nanomaterials and products with less impact to the environment, green nanotechnology also means using nanotechnology to make current manufacturing processes for non-nano materials and products more environmentally friendly. For example, nanoscale membranes can help separate desired chemical reaction products from waste materials. Nanoscale catalysts can make chemical reactions more efficient and less wasteful. Sensors at the nanoscale can form a part of process control systems, working with nano-enabled information systems. Using alternative energy systems, made possible by nanotechnology, is another way to "green" manufacturing processes.

The second goal of green nanotechnology involves developing products that benefit the environment either directly or indirectly. Nanomaterials or products directly can clean hazardous waste sites, desalinate water, treat pollutants, or sense and monitor environmental pollutants. Indirectly, lightweight nanocomposites for automobiles and other means of transportation could save fuel and reduce materials used for production; nanotechnology-enabled fuel cells and light-emitting diodes (LEDs) could reduce pollution from energy generation and help conserve fossil fuels; self-cleaning nanoscale surface coatings could reduce or eliminate many cleaning chemicals used in regular maintenance routines;^[3] and enhanced battery life could lead to less material use and less waste.
Green Nanotechnology takes a broad systems view of nanomaterials and products, ensuring that unforeseen consequences are minimized and that impacts are anticipated throughout the full life cycle.^[4]

Current research

Solar cells

One major project that is being worked on is the development of nanotechnology in solar cells.^[5] 

Solar cells are more efficient as they get tinier and solar energy is a renewable resource. The price per watt of solar energy is lower than one dollar.
Nanotechnology is already used to provide improved performance coatings for photovoltaic (PV) and solar thermal panels. Hydrophobic and self-cleaning properties combine to create more efficient solar panels, especially during inclement weather. PV covered with nanotechnology coatings are said to stay cleaner for longer to ensure maximum energy efficiency is maintained.^[6]

Nanoremediation and water treatment

Nanotechnology offers the potential of novel nanomaterials for the treatment of surface water, groundwater, wastewater, and other environmental materials contaminated by toxic metal ions, organic and inorganic solutes, and microorganisms. Due to their unique activity toward recalcitrant contaminants, many nanomaterials are under active research and development for use in the treatment of water and contaminated sites.^[7][8]

The present market of nanotech-based technologies applied in water treatment consists of reverse osmosis, nanofiltration, ultrafiltration membranes. Indeed, among emerging products one can name nanofiber filters, carbon nanotubes and various nanoparticles.^[9] Nanotechnology is expected to deal more efficiently with contaminants which convectional water treatment systems struggle to treat, including bacteria, viruses and heavy metals. This efficiency generally stems from the very high specific surface area of nanomaterials which increases dissolution, reactivity and sorption of contaminants.^[10][11]

Some potential applications include:

• To maintain public health, pathogens in water need to be identified rapidly and reliably. Unfortunately, traditional laboratory culture tests take days to complete. Faster methods involving enzymes, immunological or genetic tests are under development.^[7]
• Water filtration may be improved with the use of nanofiber membranes and the use of nanobiocides, which appear promisingly effective.^[12]
• Biofilms are mats of bacteria wrapped in natural polymers. These can be difficult to treat with antimicrobials or other chemicals. They can be cleaned up mechanically, but at the cost of substantial down-time and labour. Work is in progress to develop enzyme treatments that may be able to break down such biofilms.^[7]

Pollution

Scientists have been researching the capabilities of buckminsterfullerene in controlling pollution, as it may be able to control certain chemical reactions. Buckminsterfullerene has been demonstrated as having the ability of inducing the protection of reactive oxygen species and causing lipid peroxidation. This material may allow for hydrogen fuel to be more accessible to consumers.

Freethought

From Wikipedia, the free encyclopedia

Freethought (also spelled free thought^[1]) is a philosophical viewpoint which holds that positions regarding truth should be formed on the basis of logic, reason, and empiricism, rather than authority, tradition, or other dogmas.^[1][2][3] The cognitive application of freethought is known as "freethinking", and practitioners of freethought are known as "freethinkers".^[1][4]
Freethought holds that individuals should not accept ideas proposed as truth without recourse to knowledge and reason. Thus, freethinkers strive to build their opinions on the basis of facts, scientific inquiry, and logical principles, independent of any logical fallacies or the intellectually limiting effects of authority, confirmation bias, cognitive bias, conventional wisdom, popular culture, prejudice, sectarianism, tradition, urban legend, and all other dogmas. Regarding religion, freethinkers hold that there is insufficient evidence to support the existence of supernatural phenomena.^[5]

A line from Clifford's Credo by the 19th-century British mathematician and philosopher William Kingdon Clifford describes the premise of freethought as: "It is wrong always, everywhere, and for anyone, to believe anything upon insufficient evidence."^[6]

Symbol

The pansy, symbol of freethought

The pansy serves as the long-established and enduring symbol of freethought; literature of the American Secular Union inaugurated its usage in the late 1800s. The reasoning behind the pansy as the symbol of freethought lies both in the flower's name and in its appearance. The pansy derives its name from the French word pensée, which means "thought". It allegedly received this name because the flower is perceived by some to bear resemblance to a human face, and in mid-to-late summer it nods forward as if deep in thought.^[7]

History

Pre-modern movement

Critical thought has flourished in the Hellenistic Mediterranean, in the repositories of knowledge and wisdom in Ireland and in the Iranian civilizations (for example in the era of Khayyam (1048–1131) and his unorthodox Sufi Rubaiyat poems), and in other civilizations, such as the Chinese (note for example the seafaring renaissance of the Southern Song dynasty of 420–479),^[8] and on through heretical thinkers on esoteric alchemy or astrology, to the Renaissance and the Protestant Reformation.

French physician and writer Rabelais celebrated "rabelaisian" freedom as well as good feasting and drinking (an expression and a symbol of freedom of the mind) in defiance of the hypocrisies of conformist orthodoxy in his utopian Thelema Abbey (from θέλημα: free "will"), the device of which was Do What Thou Wilt:

"So had Gargantua established it. In all their rule and strictest tie of their order there was but this one clause to be observed, Do What Thou Wilt; because free people ... act virtuously and avoid vice. They call this honor."

When Rabelais's hero Pantagruel journeys to the "Oracle of The Div(in)e Bottle", he learns the lesson of life in one simple word: "Trinch!", Drink! Enjoy the simple life, learn wisdom and knowledge, as a free human. Beyond puns, irony, and satire, Gargantua's prologue-metaphor instructs the reader to "break the bone and suck out the substance-full marrow" ("la substantifique moëlle"), the core of wisdom.

Modern movements

The year 1600 is considered the beginning of the era of modern freethought, as it is marked by the execution in Italy of Giordano Bruno, a former Dominican Monk, by the Inquisition.^[9]

England

The term free-thinker emerged toward the end of the 17th century in England to describe those who stood in opposition to the institution of the Church, and of literal belief in the Bible. The beliefs of these individuals were centered on the concept that people could understand the world through consideration of nature. Such positions were formally documented for the first time in 1697 by William Molyneux in a widely publicized letter to John Locke, and more extensively in 1713, when Anthony Collins wrote his Discourse of Free-thinking, which gained substantial popularity.
The Freethinker magazine was first published in Britain in 1881.

France

In France, the concept first appeared in publication in 1765 when Denis Diderot, Jean le Rond d'Alembert, and Voltaire included an article on Libre-Penseur in their Encyclopédie.^{[citation needed]} The European freethought concepts spread so widely that even places as remote as the Jotunheimen, in Norway, had well-known freethinkers such as Jo Gjende by the 19th century.^{[citation needed]}
Jean-François Lefebvre de la Barre (September 12, 1745 – July 1, 1766) was a young French nobleman, famous for having been tortured and beheaded before his body was burnt on a pyre along with Voltaire's Philosophical Dictionary. La Barre is often said to have been executed for not saluting a Roman Catholic religious procession, but the elements of the case were far more complex.

In France, Lefebvre de la Barre is widely regarded a symbol of the victims of Christian religious intolerance; La Barre along with Jean Calas and Pierre-Paul Sirven, was championed by Voltaire. A second replacement statue to de la Barre stands nearby the Basilica of the Sacred Heart of Jesus of Paris at the summit of the butte Montmartre (itself named from the Temple of Mars), the highest point in Paris and an 18th arrondissement street nearby the Sacré-Cœur is also named after Lefebvre de la Barre.

Germany

In Germany, during the period (1815–1848) and before the March Revolution, the resistance of citizens against the dogma of the church increased. In 1844, under the influence of Johannes Ronge and Robert Blum, belief in the rights of man, tolerance among men, and humanism grew, and by 1859 they had established the Bund Freireligiöser Gemeinden Deutschlands (Union of Secular Communities in Germany). This union still exists today, and is included as a member in the umbrella organization of free humanists. In 1881 in Frankfurt am Main, Ludwig Büchner established Deutscher Freidenkerbund (German Freethinkers League) as the first German organization for atheists. In 1892 the Freidenker-Gesellschaft and in 1906 the Deutscher Monistenbund were formed.^[10] Freethought organizations developed "Jugendweihe", secular "confirmation" ceremonies, and atheist funeral rites.^[10][11] The Union of Freethinkers for Cremation was founded in 1905, and the Central Union of German Proletariat Freethinker in 1908. The two groups merged in 1927, becoming the German Freethinking Association in 1930.^[12]

More "bourgeois" organizations declined after World War I, and "proletarian" Freethought groups proliferated, becoming an organization of socialist parties.^[10][13] European socialist freethought groups formed the International of Proletarian Freethinkers (IPF) in 1925.^[14] Activists agitated for Germans to disaffiliate from the Church and for secularization of elementary schools; between 1919–21 and 1930–32 more than 2.5 million Germans, for the most part supporters of the Social Democratic and Communist parties, gave up church membership.^[15] Conflict developed between radical forces including the Soviet League of the Militant Godless and Social Democratic forces in Western Europe led by Theodor Hartwig and Max Sievers.^[14] In 1930 the Soviet and allied delegations, following a walk-out, took over the IPF and excluded the former leaders.^[14] Following Hitler's rise to power in 1933, most freethought organizations were banned, though some right-wing groups that worked with Völkisch associations were tolerated by the Nazis until the mid-1930s.^[10][13]

Belgium

The Université Libre de Bruxelles and the Vrije Universiteit Brussel, along with the two Circles of Free Inquiry (Dutch and French speaking), defend the freedom of critical thought, lay philosophy and ethics, while rejecting the argument of authority.

Netherlands

In the Netherlands, freethought has existed in organized form since the establishment of De Dageraad (now known as de Vrije Gedachte) in 1856. Among its most notable subscribing 19th century individuals were Johannes van Vloten, Multatuli, Adriaan Gerhard and Domela Nieuwenhuis.

In 2009, Frans van Dongen established the Atheist-Secular Party, which takes a considerably restrictive view of religion and public religious expressions.

Since the 19th century, Freethought in the Netherlands has become more well known as a political phenomenon through at least three currents: liberal freethinking, conservative freethinking, and classical freethinking. In other words, parties which identify as freethinking tend to favor non-doctrinal, rational approaches to their preferred ideologies, and arose as secular alternatives to both clerically aligned parties as well as labor-aligned parties. Common themes among freethinking political parties are "freedom", "liberty", and "individualism".

United States

The Free Thought movement was first organized in the United States as the "Free Press Association" in 1827 in defense of George Houston, publisher of The Correspondent, an early journal of Biblical criticism in an era when blasphemy convictions were still possible. Houston had helped found an Owenite community at Haverstraw, New York in 1826–27. The short-lived Correspondent was superseded by the Free Enquirer, the official organ of Robert Owen's New Harmony community in Indiana, edited by Robert Dale Owen and Fanny Wright between 1828 and 1832 in New York.
During this time Robert Dale Owen sought to introduce the philosophic skepticism of the Free Thought movement into the Workingmen's Party in New York city. The Free enquirers annual civic celebrations of Paine's birthday after 1825 finally coalesced in 1836 in the first national Free Thinkers organization, the "United States Moral and Philosophical Society for the General Diffusion of Useful Knowledge". It was founded on August 1, 1836, at a national convention at the Lyceum in Saratoga Springs, with Isaac S. Smith of Buffalo, New York, as president. He was also the 1836 Equal Rights Party's candidate for Governor of New York. Smith had also been the Workingmen's Party candidate for Lt. Governor of New York in 1830. The Moral and Philosophical Society published The Beacon, edited by Gilbert Vale.^[16]

Robert G. Ingersoll^[17]

Driven by the revolutions of 1848 in the German states, the 19th century saw an immigration of German freethinkers and anti-clericalists to the United States (see Forty-Eighters). In the United States, they hoped to be able to live by their principles, without interference from government and church authorities.^[18]

Many Freethinkers settled in German immigrant strongholds, including St. Louis, Indianapolis, Wisconsin, and Texas, where they founded the town of Comfort, Texas, as well as others.^[18]

These groups of German Freethinkers referred to their organizations as Freie Gemeinden, or "free congregations".^[18] The first Freie Gemeinde was established in St. Louis in 1850.^[19] Others followed in Pennsylvania, California, Washington, D.C., New York, Illinois, Wisconsin, Texas, and other states.^[18][19]

Freethinkers tended to be liberal, espousing ideals such as racial, social, and sexual equality, and the abolition of slavery.^[18]

The "Golden Age of Freethought" in the US was the late 1800s. The dominant organization was the National Liberal League which formed in 1876 in Philadelphia. This group reformed itself in 1885 as the American Secular Union under the leadership of the eminent agnostic orator Robert G. Ingersoll. Following Ingersoll's death in 1899 the organization declined, in part due to lack of effective leadership.^[20]

Freethought in the United States declined in the early twentieth century. Its anti-religious views alienated would-be sympathizers. The movement also lacked cohesive goals or beliefs. By the early twentieth century, most Freethought congregations had disbanded or joined other mainstream churches. The longest continuously operating Freethought congregation in America is the Free Congregation of Sauk County, Wisconsin, which was founded in 1852 and is still active today. It affiliated with the American Unitarian Association (now the Unitarian Universalist Association) in 1955.^[21] D. M. Bennett was the founder and publisher of The Truth Seeker in 1873, a radical freethought and reform American periodical.

German Freethinker settlements were located in:

• Burlington, Racine County, Wisconsin^[18]
• Belleville, St. Clair County, Illinois
• Castell, Llano County, Texas
• Comfort, Kendall County, Texas
• Fond du Lac, Fond du Lac County, Wisconsin^[18]
• Frelsburg, Colorado County, Texas
• Hermann, Gasconade County, Missouri
• Jefferson, Jefferson County, Wisconsin^[18]
• Indianapolis, Indiana^[22]
• Latium, Washington County, Texas
• Manitowoc, Manitowoc County, Wisconsin^[18]
• Meyersville, DeWitt County, Texas
• Milwaukee, Wisconsin^[18]
• Millheim, Austin County, Texas
• Oshkosh, Winnebago County, Wisconsin^[18]
• Ratcliffe, DeWitt County, Texas
• Sauk City, Sauk County, Wisconsin^[18][21]
• Shelby, Austin County, Texas
• Sisterdale, Kendall County, Texas
• St. Louis, Missouri
• Tusculum, Kendall County, Texas
• Two Rivers, Manitowoc County, Wisconsin^[18]
• Watertown, Dodge County, Wisconsin^[18]

Canada

The earliest known secular organization in English Canada is the Toronto Freethought Association, founded in 1873 by a handful of secularists. Reorganized in 1877 and again in 1881, when it was renamed the Toronto Secular Society, the group formed the nucleus of the Canadian Secular Union, established in 1884 to bring together freethinkers from across the country.

A significant number of the early members appear to have been drawn from the educated labour "aristocracy," including Alfred F. Jury, J. Ick Evans and J. I. Livingstone, all of whom were leading labour activists and secularists. The second president of the Toronto association was T. Phillips Thompson, a central figure in the city's labour and social reform movements during the 1880s and 1890s and arguably Canada's foremost late nineteenth-century labour intellectual. By the early 1880s, freethought organizations were scattered throughout southern Ontario and parts of Quebec, and elicited both urban and rural support.

The principal organ of the freethought movement in Canada was Secular Thought (Toronto, 1887–1911). Founded and edited by English freethinker Charles Watts (1835–1906) during its first several years, the editorship was assumed by Toronto printer and publisher James Spencer Ellis in 1891 when Watts returned to England.

In 1968 the Humanist Association of Canada was formed to serve as an umbrella group for Humanists, atheists, freethinkers, and to champion social justice issues and oppose religious influence on public policy—most notably in the fight to make access to abortion free and legal in Canada. HAC, also known as Humanist Canada, is an active voice for Humanism in Canada and supports the activities of groups who wish to raise awareness about secular issues.

The Canadian Secular Alliance is an active community.

Anarchism

In the United States, "freethought was a basically anti-christian, anti-clerical movement, whose purpose was to make the individual politically and spiritually free to decide for himself on religious matters. A number of contributors to Liberty were prominent figures in both freethought and anarchism. The individualist anarchist George MacDonald was a co-editor of Freethought and, for a time, The Truth Seeker. E.C. Walker was co-editor of the freethought/free love journal Lucifer, the Light-Bearer."^[23] "Many of the anarchists were ardent freethinkers; reprints from freethought papers such as Lucifer, the Light-Bearer, Freethought and The Truth Seeker appeared in Liberty...The church was viewed as a common ally of the state and as a repressive force in and of itself."^[23]

In Europe, a similar development occurred in French and Spanish individualist anarchist circles. "Anticlericalism, just as in the rest of the libertarian movement, in another of the frequent elements which will gain relevance related to the measure in which the (French) Republic begins to have conflicts with the church...Anti-clerical discourse, frequently called for by the French individualist André Lorulot, will have its impacts in Estudios (a Spanish individualist anarchist publication). There will be an attack on institutionalized religion for the responsibility that it had in the past on negative developments, for its irrationality which makes it a counterpoint of philosophical and scientific progress. There will be a criticism of proselitism and ideological manipulation which happens on both believers and agnostics".^[24] These tendencies will continue in French individualist anarchism in the work and activism of Charles-Auguste Bontemps and others. In the Spanish individualist anarchist magazines Ética and Iniciales "there is a strong interest in publishing scientific news, usually linked to a certain atheist and anti-theist obsession, philosophy which will also work for pointing out the incompatibility between science and religion, faith, and reason. In this way there will be a lot of talk on Darwin´s theories or on the negation of the existence of the soul".^[25]

In 1901, Catalan anarchist and freethinker Francesc Ferrer i Guàrdia established "modern" or progressive schools in Barcelona in defiance of an educational system controlled by the Catholic Church.^[26] The schools' stated goal was to "educate the working class in a rational, secular and non-coercive setting". Fiercely anti-clerical, Ferrer believed in "freedom in education", education free from the authority of church and state.^[27] Ferrer's ideas generally, formed the inspiration for a series of Modern Schools in the United States,^[26] Cuba, South America and London. The first of these was started in New York City in 1911. It also inspired the Italian newspaper Università popolare, founded in 1901.^[26]

NYT Smears Scientist Willie Soon for Telling the Truth About ‘Global Warming’

AP Photo/Romas Dabrukas

by James Delingpole21 Feb 20152133

Original link:  http://www.breitbart.com/big-government/2015/02/21/nyt-smears-scientist-willie-soon-for-telling-the-truth-about-global-warming/

 

Another day, another attack on the integrity of the Harvard-Smithsonian astrophysicist Dr. Willie Soon, this time in the New York Times.

I first became aware of Soon in 2009 when reading through the Climategate emails. One of them was a jocular suggestion by a warmist called Tom Wigley as to how best to smear Soon and his co-author Sallie Baliunas.

Might be interesting to see how frequently Soon and Baliunas, individually, are cited (as astronomers). Are they any good in their own fields? Perhaps we could start referring to them as astrologers (excusable as…’oops, just a typo’).

You might be wondering what Soon and Baliunas had done to incur the wrath of the climate alarmist establishment. Well, they’d just published a meta-analysis of all the papers which had been written on the Medieval Warm Period (MWP). What their paper showed is that contrary to claims by one Michael Mann (the name may be familiar), the MWP was not a small, localised event but global, big and widespread.

So the memo went out from the Hockey Team (the uber-vindictive Mann and his lickspittle posse) to get Soon, and they’ve been going at him ever since: not by criticising the quality of his science — that would be too difficult because his science is impeccable — but simply by trying to make his life miserable, deny him tenure, and to smear him as compromised and corrupt.

The reason for the latest attack on Soon is that he is the co-author, with Christopher Monckton et al, of a paper published earlier this year in the prestigious Chinese Academy of Sciences journal Science Bulletin.

This study — Why Models Run Hot — infuriated the alarmist establishment, first because it was unusually popular (receiving over 10,000 views — thousands more than most scientific papers get) and second because it made a mockery of their cherished computer models.

As Paul Driessen explains:

Results from an irreducibly simple climate model,” concluded that, once discrepancies in IPCC computer models are taken into account, the impact of CO2-driven manmade global warming over the next century (and beyond) is likely to be “no more than one-third to one-half of the IPCC’s current projections” – that is, just 1-2 degrees C (2-4 deg F) by 2100! That’s akin to the Roman and Medieval Warm Periods and would be beneficial, not harmful.

Rather than attack the substance of the paper, the warmists reverted to their usual tricks, lead by Kert Davies, an activist lawyer who works for a Greenpeace front organisation called Climate Investigations Center.

Climate Investigations Center executive director (and former top Greenpeace official) Kert Davies told the Boston Globe it “simply cannot be true” that the authors have no conflict of interest over their study, considering their alleged industry funding sources and outside consulting fees. Davies singled out Dr. Willie Soon, saying the Harvard researcher received more than $1 million from companies that support studies critical of manmade climate change claims. An allied group launched a petition drive to have Dr. Soon fired.
Davies’ libelous assertions have no basis in fact. Not one of these four authors received a dime in grants or other payments for researching and writing their climate models paper. Every one of them did the work on his own time. The only money contributed to the Science Bulletin effort went to paying the “public access” fees, so that people could read their study for free.

I spoke to Soon last night. He told me that of course he receives private funding for his research: he has to because it’s his only way of making ends meet, especially since the Alarmist establishment launched its vendetta against him when, from 2009 onwards, he became more outspoken in his critiques of global warming theory.

Harvard-Smithsonian strove to make his life harder and harder, first by banning him from working on anything even remotely connected with issues like climate change or CO2, then by moving his office away from the astrophysics department to a remote area Soon calls Siberia. What the faculty couldn’t quite do was actually sack Soon because it had no cause: he was producing too many quality papers, and he was also bringing in too much money (40 per cent of which goes straight into the faculty coffers).

So there’s nothing new or scandalous about this latest New York Times hit job on poor Willie Soon. It’s just a continuation of a vendetta which has been waged for years against an honest, decent, hardworking — and incredibly brave — scientist who refuses to toe the official (and increasingly discredited) line on man-made global warming.

What most definitely is scandalous is the vile hypocrisy of Soon’s harrassment by the warmist establishment, which receives billions every year from the US government, left-wing charities, and billionaire activists like Tom Steyer and George Soros to prop up their bankrupt cause by promoting exactly the kind of junk science which Soon (and similarly principled scientists) have made it their business to shred.

The warmists are losing their argument. Their desperation is beginning to show.