Shenandoah National Park

From Wikipedia, the free encyclopedia

 https://en.wikipedia.org/wiki/Shenandoah_National_Park

 

Shenandoah National Park
IUCN category II (national park)
Skyline Drive
Location in the United States Show map of the United StatesShow map of VirginiaShow map of Shenandoah ValleyShow all
Location	Virginia, United States
Nearest city	Front Royal
Coordinates	38°32′N 78°21′WCoordinates: 38°32′N 78°21′W
Area	199,173 acres (311.208 sq mi; 806.02 km2)
Established	December 26, 1935
Visitors	1,264,880 (in 2018)
Governing body	National Park Service
Website	Official website

Shenandoah National Park /ˈʃɛnənˌdoʊə/ (often /ˈʃænənˌdoʊə/) is an American national park that encompasses part of the Blue Ridge Mountains in the state of Virginia. The park is long and narrow, with the Shenandoah River and its broad valley to the west, and the rolling hills of the Virginia Piedmont to the east. Skyline Drive is the main park road, generally traversing near the ridgeline of the mountains. Almost 40% of the land area—79,579 acres (124.3 sq mi; 322.0 km²)—has been designated as wilderness and is protected as part of the National Wilderness Preservation System. The highest peak is Hawksbill Mountain at 4,051 feet (1,235 m).

Geography

Park map (click on map to enlarge)

The park encompasses parts of eight counties. On the west side of Skyline Drive they are, from northeast to southwest, Warren, Page, Rockingham, and Augusta counties. On the east side of Skyline Drive they are Rappahannock, Madison, Greene, and Albemarle counties. The park stretches for 105 miles (169 km) along Skyline Drive from near the town of Front Royal in the northeast to near the city of Waynesboro in the southwest. The park headquarters are located in Luray.

Geology

Shenandoah National Park lies along the Blue Ridge Mountains in north-central Virginia. These mountains form a distinct highland rising to elevations above 4,000 feet (1,200 m). Local topographic relief between the Blue Ridge Mountains and Shenandoah Valley exceeds 3,000 feet (910 m) at some locations. The crest of the range divides the Shenandoah River drainage basin, part of the Potomac River drainage, on the west side, from the James and Rappahannock River drainage basins on the east side.

Some of the rocks exposed in the park date to over one billion years in age, making them among the oldest in Virginia. Bedrock in the park includes Grenville-age granitic basement rocks (1.2–1.0 billion years old) and a cover sequence of metamorphosed Neoproterozoic (570–550 million years old) sedimentary and volcanic rocks of the Swift Run and Catoctin formations. Columns of Catoctin Formation metamorphosed basalt can be seen at Compton Peak. Clastic rocks of the Chilhowee Group are of early Cambrian age (542–520 million years old). Quaternary surficial deposits are common and cover much of the bedrock throughout the park.

The park is located along the western part of the Blue Ridge anticlinorium, a regional-scale Paleozoic structure at the eastern margin of the Appalachian fold and thrust belt. Rocks within the park were folded, faulted, distorted, and metamorphosed during the late Paleozoic Alleghanian orogeny (325 to 260 million years ago). The rugged topography of Blue Ridge Mountains is a result of differential erosion during the Cenozoic, although some post-Paleozoic tectonic activity occurred in the region.

History

Satellite view of Shenandoah in autumn, the leaf peeping season

Creation of the park

Legislation to create a national park in the Appalachian mountains was first introduced by freshman Virginia congressman Henry D. Flood in 1901, but despite the support of President Theodore Roosevelt, failed to pass. The first national park was Yellowstone, in Wyoming, Montana, and Idaho. It was signed into law in 1872. Yosemite National Park was created in 1890. When Congress created the National Park Service (NPS) in 1916, additional parks had maintained the western pattern (Crater Lake in 1902, Wind Cave in 1903, Mesa Verde in 1906, then Denali in 1917). Grand Canyon, Zion and Acadia were all created in 1919 during the administration of Virginia-born president Woodrow Wilson. Acadia finally broke the western mold, becoming the first eastern national park. It was also based on donations from wealthy private landowners. Stephen Mather, the first NPS director, saw a need for a national park in the southern states, and solicited proposals in his 1923 year-end report. In May 1925, Congress and President Calvin Coolidge authorized the NPS to acquire a minimum of 250,000 acres (390.6 sq mi; 1,011.7 km²) and a maximum of 521,000 acres (814.1 sq mi; 2,108.4 km²) to form Shenandoah National Park, and also authorized creation of Great Smoky Mountains National Park. However, the legislation also required that no federal funds would be used to acquire the land. Thus, Virginia needed to raise private funds, and could also authorize state funds and use its eminent domain (condemnation) power to acquire the land to create Shenandoah National Park. 

Virginia's Democratic gubernatorial candidate (and the late Congressman Flood's nephew), Harry F. Byrd supported creation of Shenandoah National Park, as did his friend William E. Carson, a businessman who had become Virginia's first chairman of the Commission on Conservation and Development. Development of the western national parks had assisted tourism, which produced jobs, which Byrd and local politicians supported. The land that became Shenandoah park was scenic, mountainous, and had also lost about half of its trees to the Chestnut blight (which was incurable and affected trees as they reached maturity). However, it had been held as private property for over a century, so many farms and orchards existed. After Byrd became governor and convinced the legislature to appropriate $1 million for land acquisition and other work, Carson and his teams (including surveyors and his brother Kit who was Byrd's law partner) tried to figure out who owned the land. They found that it consisted of more than 5,000 parcels, some of them inhabited by tenant farmers or squatters (who were ineligible to receive compensation). Some landowners, including wealthy resort owner George Freeman Pollock and Luray Realtor and developer L. Ferdinand Zerkel, had long wanted the park created and had formed the Northern Virginia Park Association to win over the national park selection committee. However, many local families who had lived in the area for generations (especially people over 60 years old) did not want to sell their land, and some refused to sell at any price. Carson promised that if they sold to the state, they could still live on their homesteads for the rest of their lives. Carson also lobbied the new president, Herbert Hoover, who bought land to establish a vacation fishing camp near the headwaters of the Rapidan River (and would ultimately donate it to the park as he left office; it remains as Rapidan Camp).

A small family cemetery along Skyline Drive

The commonwealth of Virginia slowly acquired the land through eminent domain, and then gave it to the U.S. federal government to establish the national park. Carson's brother suggested that Virginia's legislature authorize condemnation by counties (followed by arbitration for individual parcels) rather than condemn each parcel. Some families accepted the payments because they needed the money and wanted to escape the subsistence lifestyle. Nearly 90 percent of the inhabitants worked the land for a living: selling timber, charcoal or crops. They had previously been able to earn money to buy supplies by harvesting the now-rare chestnuts, by working during the apple and peach harvest season (but the drought of 1930 devastated those crops and killed many fruit trees), by selling handmade textiles and crafts (displaced by factories) and moonshine (illegal after Prohibition started).

However, Carson and the politicians did not seek citizen input early in the process, nor convince residents that they could live better in a tourist economy. Instead they started with an advertising campaign to raise the funds, and courthouse property evaluations and surveys. Upon Mather's death in 1929, the new NPS director, Horace M. Albright also decided that the federal agency would only accept vacant land, so even elderly residents would be forced to leave. Thus, many families and entire communities were forced to vacate portions of the Blue Ridge Mountains in eight Virginia counties. Although the Skyline Drive right-of-way was purchased from owners without condemnation, the costs of the acreage purchased trebled over initial estimates and the acreage decreased to what Carson called a "fish-bone" shape and others a "shoestring". Although Byrd and Carson convinced Congress to reduce the minimum size of Shenandoah Park to just over 160,000 acres (250.0 sq mi; 647.5 km²) to eliminate some high-priced lands, in 1933 newly elected President Franklin D. Roosevelt decided to also create the Blue Ridge Parkway to connect to then-under-construction Skyline Drive on the Shenandoah National Park ridgeline, which required additional condemnations.

When many families continued to refuse to sell their land in 1932 and 1933, proponents changed tactics. Freeman hired social worker Miriam Sizer to teach at a summer school he had set up near one of his workers' communities, and asked her to write a report about the conditions in which they lived. Although later discredited, the report depicted the local population as very poor and inbred, and was soon used to support forcible evictions and burning of former cabins so residents would not sneak back. University of Chicago sociologists Fay-Cooper Cole and Mandel Sherman described how the small valley communities or hollows had existed "without contact with law or government" for centuries, which some analogized to a popular comic strip Li'l Abner and his fictional community, Dogpatch. In 1933, Sherman and journalist Thomas Henry published Hollow Folk drawing pitying eyes to local conditions and "hillbillies." As in many rural areas of the time, most remote homesteads in the Shenandoah lacked electricity and often running water, as well as access to schools and health facilities during many months. However, Hoover had hired experienced rural teacher Christine Vest to teach near his summer home (and who believed the other reports exaggerated, as did Episcopal missionary teachers in other Blue Ridge areas).

View from the summit of Hawksbill Mountain

Carson had had ambitions to become governor in 1929 and 1933, but Byrd instead selected George C. Peery of the state's southwest corner to succeed easterner Pollard. After winning election, Peery and Carson's successor would establish Virginia's state park system, although plans to relocate reluctant residents kept changing and basically failed. Carson had hoped to head that new state agency, but was not selected because of his growing differences with Byrd, over fees owed his brother and especially over the evictions that began in late 1933 against his advice but pursuant to new federal policies and that garnered much negative publicity.

Most of the reluctant families came from the park's central counties (Madison, Page, and Rappahannock), not the northern counties nearest Byrd's and Carson's bases, or from the southern end where residents could see tourism's benefits at Thomas Jefferson's Monticello since the 1920s, as well as the jobs available in the Shenandoah and new Blue Ridge projects. In 1931 and 1932, residents were allowed to petition the state agency to stay another year to gather crops, etc. However, some refused to cooperate to any extent, others wanted to continue to use resources now protected (including timber or homes and gardens vacated by others), and many found the permit process arbitrary. Businessman Robert H. Via filed suit against the condemnations in 1934 but did not prevail (and ended up moving to Pennsylvania and never cashed his condemnation check).

Carson announced his resignation from his unpaid job effective in December 1934. As one of his final acts, Carson wrote the new NPS director, Arno B. Cammerer, urging that 60 people over 60 years of age whose plots were not visible from the new Skyline Drive not be evicted. When evictions kept creating negative publicity in 1935, photographer Arthur Rothstein coordinated with the Hollow Folk authors and then went to document the conditions they claimed.

View from Skyline Drive

Creation of the park had immediate benefits to some Virginians. During the Great Depression, many young men received training and jobs through the Civilian Conservation Corps (CCC). The first CCC camp in Virginia was established in the George Washington National Forest near Luray, and Governor Pollard quickly filled his initial quota of 5,000 workers. About 1,000 men and boys worked on Skyline Drive, and about 100,000 worked in Virginia during the agency's existence. In Shenandoah Park, CCC crews removed many of the dead chestnut trees whose skeletons marred views in the new park, as well as constructed trails and facilities. Tourism revenues also skyrocketed. On the other hand, CCC crews were assigned to burn and destroy some cabins in the park, to prevent residents from coming back. Also, U.S. Secretary of the Interior Harold Ickes who had jurisdiction over the NPS and partial jurisdiction over the CCC, tried to use his authority to force Byrd to cooperate on other New Deal projects.

Shenandoah National Park was finally established on December 26, 1935, and soon construction began on the Blue Ridge Parkway that Byrd wanted. President Franklin Delano Roosevelt formally opened Shenandoah National Park on July 3, 1936. Eventually, about 40 people (on the "Ickes list") were allowed to live out their lives on land that became the park. One of them was George Freeman Pollock, whose residence Killahevlin was later listed on the National Register, and whose Skyland Resort reopened under a concessionaire in 1937. Carson also donated significant land; a mountain in the park is now named in his honor and signs acknowledge his contributions. The last grandmothered resident was Annie Lee Bradley Shenk. NPS employees had watched and cared for her since 1950; she died in 1979 at age 92. Most others left quietly. 85-year-old Hezekiah Lam explained, "I ain't so crazy about leavin' these hills but I never believed in bein' ag'in (against) the Government. I signed everythin' they asked me."

Segregation and desegregation

Mount Marshall and Hogback Mountain covered in clouds in winter

In the early 1930s, the National Park Service began planning the park facilities and envisioned separate provisions for blacks and whites. At that time, in Jim Crow Virginia, racial segregation was the order of the day. In its transfer of the parkland to the federal government, Virginia initially attempted to ban African Americans entirely from the park, but settled for enforcing its segregation laws in the park's facilities.

By the 1930s, there were several concessions operated by private firms within the area that would become the park, some going back to the late 19th century. These early private facilities at Skyland Resort, Panorama Resort, and Swift Run Gap were operated only for whites. By 1937, the Park Service accepted a bid from Virginia Sky-Line Company to take over the existing facilities and add new lodges, cabins, and other amenities, including Big Meadows Lodge. Under their plan, all the sites in the parks, save one, were for "whites only". Their plan included a separate facility for African Americans at Lewis Mountain—a picnic ground, a smaller lodge, cabins and a campground. The site opened in 1939, and it was substantially inferior to the other park facilities. By then, however, the Interior Department was increasingly anxious to eliminate segregation from all parks. Pinnacles picnic ground was selected to be the initial integrated site in the Shenandoah, but Virginia Sky-Line Company continued to balk, and distributed maps showing Lewis Mountain as the only site for African Americans. During World War II, concessions closed and park usage plunged. But once the War ended, in December 1945, the NPS mandated that all concessions in all national parks were to be desegregated. In October 1947 the dining rooms of Lewis Mountain and Panorama were integrated and by early 1950, the mandate was fully accomplished.

Social history

Particularly after the 1960s, park operations broadened from nature-focused to include social history. The Potomac Appalachian Trail Club had restored some cabins beginning in the 1940s, and made them available to overnight hikers. Some displaced residents (and their descendants) created the Children of the Shenandoah to lobby for more balanced presentations.

In the 1990s, the park hired cultural resource specialists and conducted an archeological inventory of existing structures, the Survey of Rural Mountain Settlement. Eventually, the park's new focus on cultural resources coincided with agitation from a descendant's organization known as the Children of Shenandoah, which resulted in the removal of questionable interpretive displays. Hikes and tours that explained the social history of the displaced mountain people began.

Attractions

Skyline Drive

View from Skyline Drive's Pinnacles Overlook

The park is best known for Skyline Drive, a 105-mile (169 km) road that runs the length of the park along the ridge of the mountains. 101 miles (163 km) of the Appalachian Trail are also in the park. In total, there are over 500 miles (800 km) of trails within the park. There is also horseback riding, camping, bicycling, and a number of waterfalls. The Skyline Drive is the first National Park Service road east of the Mississippi River listed as a National Historic Landmark on the National Register of Historic Places. It is also designated as a National Scenic Byway. 

Backcountry camping

Shenandoah National Park offers 196,000 acres (306.2 sq mi; 793.2 km²) of backcountry and wilderness camping. While in the backcountry, campers must use a "Leave No Trace" policy that includes burying excrement and not building campfires.

Backcountry campers must also be careful of wildlife such as bears and venomous snakes. Campers must suspend their food from trees while not in use in "bear bags" or park-approved bear canisters to prevent unintentionally feeding the bears, who then become habituated to humans and their food and therefore dangerous. All animals are protected by federal law.

Lodging

Campgrounds and cabins

Most of the campgrounds are open from April to October–November. There are five major campgrounds:

• Mathews Arm Campground
• Big Meadows Campground
• Lewis Mountain Campground
• Loft Mountain Campground
• Dundo Group Campground

Lodges

There are three lodges/cabins:

• Skyland Resort
• Big Meadows
• Lewis Mountain Cabins

Massanutten Lodge at Skyland Resort

Lodges are located at Skyland and Big Meadows. The park's Harry F. Byrd Visitor Center is also located at Big Meadows. Another visitor center is located at Dickey Ridge. Campgrounds are located at Mathews Arm, Big Meadows, Lewis Mountain, and Loft Mountain.

Rapidan Camp, the restored presidential fishing retreat Herbert Hoover built on the Rapidan River in 1929, is accessed by a 4.1-mile (6.6 km) round-trip hike on Mill Prong Trail, which begins on the Skyline Drive at Milam Gap (Mile 52.8). The NPS also offers guided van trips that leave from the Byrd Center at Big Meadows.

Shenandoah National Park is one of the most dog-friendly in the national park system. The campgrounds all allow dogs, and dogs are allowed on almost all of the trails including the Appalachian Trail, if kept on leash (6 feet or shorter). Dogs are not allowed on ten trails: Fox Hollow Trail, Stony Man Trail, Limberlost Trail, Post Office Junction to Old Rag Shelter, Old Rag Ridge Trail, Old Rag Saddle Trail, Dark Hollow Falls Trail, Story of the Forest Trail, Bearfence Mountain Trail, Frazier Discovery Trail. These ten trails fall short of a total of 20 miles of the 500 miles of trails of the Shenandoah National Park.

Streams and rivers in the park are very popular with fly fisherman for native brook trout.

Waterfalls

Many waterfalls are located within the park boundaries. Below is a list of significant falls.

Falls	Height	Location	Description
Overall Run	93 ft (28 m)	Mile 21.1, parking lot just south of Hogback Overlook	The tallest waterfall in the park. 6.5 mile (10 km) round trip hike. Go before June as this waterfall tends to dry up.
Whiteoak Canyon	86 ft (26 m)	Mile 42.6, Whiteoak Canyon parking area	Whiteoak Canyon has a series of six waterfalls, the first (and tallest) is 86 feet (28 m). Not all the falls are easily accessible from the trail. Start at the lowest and work your way up to the tallest waterfall.
Cedar Run	34 ft (10 m)	Mile 45.6, Hawksbill Gap parking area	Difficult 3.4 mile (5 km) round trip hike. Sights along the way include waterfalls, swimming holes, and natural rock slides of varying lengths.
Rose River	67 ft (20 m)	Mile 49.4, parking at Fishers Gap Overlook	A 2.6 mile (4 km) round trip hike. Can also be done as a longer loop hike.
Dark Hollow Falls	70 ft (21 m)	Mile 50.7, Dark Hollow Falls parking area	1.4 mile (2 km) round trip hike. The closest waterfall to Skyline Drive and the most popular. No pets allowed on this trail.
Lewis Falls	81 ft (25 m)	Mile 51.4, parking lot just south of Big Meadows, next to a service road	2 mile (3 km) round trip hike.
South River Falls	83 ft (25 m)	Mile 62.8, park at South River picnic area	3.3 mile (5 km) loop hike to an overlook above the falls. There is also a rocky, 1 mile (2 km) round trip spur trail that goes to the base of the falls. The "shortcut" is before the overlook but watch out for water snakes as they're very common in this area.
Doyles River Falls	28 and 63 ft (9 and 19 m)	Mile 81.1, Doyles River parking area	A 3-mile (4.8 km) round trip hike to see both the upper and lower falls. Be sure to go a little past the lower falls viewing spot for a better view. Can also be turned into a 7.8-mile (12.6 km) loop trail that also goes by Jones Run Falls
Jones Run Falls	42 ft (13 m)	Mile 84.1, Jones Run parking area	A 3.6-mile (5.8 km) round trip hike. Can also be turned into a longer loop hike that goes by Doyles River upper and lower falls

• 

  Whiteoak Canyon
  
• 

  Rose River Falls
  
• 

  South River Falls
  
• 

  Jones Run Falls
  

Hiking trails

Dark Hollow Falls Trail

Dark Hollow Falls

Beginning at mile 50.7 of the Skyline Drive near the Byrd Visitor Center, Dark Hollow Falls Trail leads downhill beside Hogcamp Branch to Dark Hollow Falls, a 70-foot cascade. The distance from the trailhead to the base of the falls is 0.7 mile, although the trail continues beyond that point, crossing the creek and connecting with the Rose River fire road. Various fauna can be viewed along the trail, including occasional sightings of black bears and timber rattlesnakes. While the trail is relatively short, parts of it are steep and may prove challenging to some visitors. There is no view from the brink of the falls, and slippery rocks make it inadvisable to leave the trail.

Climate

According to the Köppen climate classification system, Shenandoah National Park has a humid continental climate with warm summers and no dry season (Dfb). According to the United States Department of Agriculture, the plant hardiness zone at Big Meadows Visitor Center (3514 ft / 1071 m) is 6a with an average annual extreme minimum temperature of -7.1 °F (-21.7 °C).

Ecology

Deer at Tanner Ridge Overlook

The climate of the park and its flora and fauna are typical for mountainous regions of the eastern Mid-Atlantic woodland, while a large portion of common species are also typical of ecosystems at lower altitudes. A. W. Kuchler's potential natural vegetation type for the park is Appalachian oak (104) within an eastern hardwood forest vegetation form (25), also known as a temperate broadleaf and mixed forest.

Pines predominate on the southwestern faces of some of the southernmost hillsides, where an occasional prickly pear cactus may also grow naturally. In contrast, some of the northeastern aspects are most likely to have small but dense stands of moisture loving hemlocks and mosses in abundance. Other commonly found plants include oak, hickory, chestnut, maple, tulip poplar, mountain laurel, milkweed, daisies, and many species of ferns. The once predominant American chestnut tree was effectively brought to extinction by a fungus known as the chestnut blight during the 1930s; though the tree continues to grow in the park, it does not reach maturity and dies back before it can reproduce. Various species of oaks superseded the chestnuts and became the dominant tree species. Gypsy moth infestations beginning in the early 1990s began to erode the dominance of the oak forests as the moths would primarily consume the leaves of oak trees. Though the gypsy moths seem to have abated, they continue to affect the forest and have destroyed almost ten percent of the oak groves.

Wildlife

Juvenile American black bear at Old Rag Mountain

Mammals include black bear, coyote, striped skunk, spotted skunk, raccoon, beaver, river otter, opossum, woodchuck, two species of foxes, white-tailed deer, and eastern cottontail rabbit. Though unsubstantiated, there have been some reported sightings of cougar in remote areas of the park. Over 200 species of birds make their home in the park for at least part of the year. About thirty live in the park year round, including the barred owl, Carolina chickadee, red-tailed hawk, and wild turkey. The peregrine falcon was reintroduced into the park in the mid-1990s and by the end of the 20th century there were numerous nesting pairs in the park. Thirty-two species of fish have been documented in the park, including brook trout, longnose and eastern blacknose dace, and the bluehead chub.

Ranger programs

Park rangers organize several programs from spring to fall. These include ranger-led hikes, as well as discussions of the history, flora, and fauna. Shenandoah Live is an online series where listeners may chat live with rangers and learn about some of the park's features. Rangers discuss a wide range of topics while answering questions and talking with experts from the field.

Artist-in-Residence Program

In 2014, under the leadership of Superintendent Jim Northup, Shenandoah National Park established an Artist-in-Residence Program that is administered by the Shenandoah National Park Trust, the park's philanthropic partner. Photographer Sandy Long was selected as the park's first artist-in-residence. The results of Long's residency were featured in the photography exhibit "Wild Beauty: The Artful Nature of Shenandoah National Park" held at the Looking Glass Art Gallery in the historic Hawley Silk Mill, in Hawley, Pennsylvania.

High-resolution transmission electron microscopy

From Wikipedia, the free encyclopedia

https://en.wikipedia.org/wiki/High-resolution_transmission_electron_microscopy 

 

High-resolution transmission electron microscopy (HRTEM) (or HREM) is an imaging mode of specialized transmission electron microscopes (TEMs) that allows for direct imaging of the atomic structure of the sample. HRTEM is a powerful tool to study properties of materials on the atomic scale, such as semiconductors, metals, nanoparticles and sp²-bonded carbon (e.g., graphene, C nanotubes). While HRTEM is often also used to refer to high resolution scanning TEM (STEM, mostly in high angle annular dark field mode), this article describes mainly the imaging of an object by recording the 2D spatial wave amplitude distribution in the image plane, in analogy to a "classic" light microscope. For disambiguation, the technique is also often referred to as phase contrast TEM. At present, the highest point resolution realised in phase contrast TEM is around 0.5 ångströms (0.050 nm). At these small scales, individual atoms of a crystal and its defects can be resolved. For 3-dimensional crystals, it may be necessary to combine several views, taken from different angles, into a 3D map. This technique is called electron crystallography.

One of the difficulties with HRTEM is that image formation relies on phase contrast. In phase-contrast imaging, contrast is not necessarily intuitively interpretable, as the image is influenced by aberrations of the imaging lenses in the microscope. The largest contributions for uncorrected instruments typically come from defocus and astigmatism. The latter can be estimated from the so-called Thon ring pattern appearing in the Fourier transform modulus of an image of a thin amorphous film.

Image contrast and interpretation

Simulated HREM images for GaN[0001]

The contrast of a HRTEM image arises from the interference in the image plane of the electron wave with itself. Due to our inability to record the phase of an electron wave, only the amplitude in the image plane is recorded. However, a large part of the structure information of the sample is contained in the phase of the electron wave. In order to detect it, the aberrations of the microscope (like defocus) have to be tuned in a way that converts the phase of the wave at the specimen exit plane into amplitudes in the image plane.

The interaction of the electron wave with the crystallographic structure of the sample is complex, but a qualitative idea of the interaction can readily be obtained. Each imaging electron interacts independently with the sample. Above the sample, the wave of an electron can be approximated as a plane wave incident on the sample surface. As it penetrates the sample, it is attracted by the positive atomic potentials of the atom cores, and channels along the atom columns of the crystallographic lattice (s-state model). At the same time, the interaction between the electron wave in different atom columns leads to Bragg diffraction. The exact description of dynamical scattering of electrons in a sample not satisfying the weak phase object approximation (WPOA), which is almost all real samples, still remains the holy grail of electron microscopy. However, the physics of electron scattering and electron microscope image formation are sufficiently well known to allow accurate simulation of electron microscope images.

As a result of the interaction with a crystalline sample, the electron exit wave right below the sample φ_e(x,u) as a function of the spatial coordinate x is a superposition of a plane wave and a multitude of diffracted beams with different in plane spatial frequencies u (spatial frequencies correspond to scattering angles, or distances of rays from the optical axis in a diffraction plane). The phase change φ_e(x,u) relative to the incident wave peaks at the location of the atom columns. The exit wave now passes through the imaging system of the microscope where it undergoes further phase change and interferes as the image wave in the imaging plane (mostly a digital pixel detector like a CCD camera). It is important to realize, that the recorded image is NOT a direct representation of the samples crystallographic structure. For instance, high intensity might or might not indicate the presence of an atom column in that precise location (see simulation). The relationship between the exit wave and the image wave is a highly nonlinear one and is a function of the aberrations of the microscope. It is described by the contrast transfer function.

The phase contrast transfer function

The phase contrast transfer function (CTF) is a function of limiting apertures and aberrations in the imaging lenses of a microscope. It describes their effect on the phase of the exit wave φ_e(x,u) and propagates it to the image wave. Following Williams and Carter, if we assume the WPOA holds (thin sample) the CTF becomes

${\displaystyle CTF(u)=A(u)E(u)2\sin(\chi (u))}$

where A(u) is the aperture function, E(u) describes the attenuation of the wave for higher spatial frequency u, also called envelope function. χ(u) is a function of the aberrations of the electron optical system. 

The last, sinusoidal term of the CTF will determine the sign with which components of frequency u will enter contrast in the final image. If one takes into account only spherical aberration to third order and defocus, χ is rotationally symmetric about the optical axis of the microscope and thus only depends on the modulus u = |u|, given by

${\displaystyle \chi (u)={\frac {\pi }{2}}C_{s}\lambda ^{3}u^{4}-\pi \Delta f\lambda u^{2}}$

where C_s is the spherical aberration coefficient, λ is the electron wavelength, and Δf is the defocus. In TEM, defocus can easily be controlled and measured to high precision. Thus one can easily alter the shape of the CTF by defocusing the sample. Contrary to optical applications, defocusing can actually increase the precision and interpretability of the micrographs.

The aperture function cuts off beams scattered above a certain critical angle (given by the objective pole piece for ex), thus effectively limiting the attainable resolution. However it is the envelope function E(u) which usually dampens the signal of beams scattered at high angles, and imposes a maximum to the transmitted spatial frequency. This maximum determines the highest resolution attainable with a microscope and is known as the information limit. E(u) can be described as a product of single envelopes:

${\displaystyle E(u)=E_{s}(u)E_{c}(u)E_{d}(u)E_{v}(u)E_{D}(u),\,}$

due to

E_s(u): angular spread of the source

E_c(u): chromatic aberration

E_d(u): specimen drift

E_v(u): specimen vibration

E_D(u): detector

Specimen drift and vibration can be minimized in a stable environment. It is usually the spherical aberration C_s that limits spatial coherency and defines E_s(u) and the chromatic aberration C_c, together with current and voltage instabilities that define the temporal coherency in E_c(u). These two envelopes determine the information limit by damping the signal transfer in Fourier space with increasing spatial frequency u

${\displaystyle E_{s}(u)=\exp \left[-\left({\frac {\pi \alpha }{\lambda }}\right)^{2}\left({\frac {\delta \mathrm {X} (u)}{\delta u}}\right)^{2}\right]=\exp \left[-\left({\frac {\pi \alpha }{\lambda }}\right)^{2}(C_{s}\lambda ^{3}u^{3}+\Delta f\lambda u)^{2}\right],}$

where α is the semiangle of the pencil of rays illuminating the sample. Clearly, if the wave aberration ('here represented by C_s and Δf) vanished, this envelope function would be a constant one. In case of an uncorrected TEM with fixed C_s, the damping due to this envelope function can be minimized by optimizing the defocus at which the image is recorded (Lichte defocus). 

The temporal envelope function can be expressed as

${\displaystyle E_{c}(u)=\exp \left[-{\frac {1}{2}}\left(\pi \lambda \delta \right)^{2}u^{4}\right],}$.

Here, δ is the focal spread with the chromatic aberration C_c as the parameter:

${\displaystyle \delta =C_{c}{\sqrt {4\left({\frac {\Delta I_{\text{obj}}}{I_{\text{obj}}}}\right)^{2}+\left({\frac {\Delta E}{V_{\text{acc}}}}\right)^{2}+\left({\frac {\Delta V_{\text{acc}}}{V_{\text{acc}}}}\right)^{2}}},}$

The terms ${\displaystyle \Delta I_{\text{obj}}/I_{\text{obj}}}$ and ${\displaystyle \Delta V_{\text{acc}}/V_{\text{acc}}}$ represent instabilities in of the total current in the magnetic lenses and the acceleration voltage. ${\displaystyle \Delta E/V_{\text{acc}}}$ is the energy spread of electrons emitted by the source.

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aberration correctors.

Optimum defocus in HRTEM

CTF of the OAM microscope

Choosing the optimum defocus is crucial to fully exploit the capabilities of an electron microscope in HRTEM mode. However, there is no simple answer as to which one is the best.

In Gaussian focus one sets the defocus to zero, the sample is in focus. As a consequence contrast in the image plane gets its image components from the minimal area of the sample, the contrast is localized (no blurring and information overlap from other parts of the sample). The CTF now becomes a function that oscillates quickly with C_su⁴. What this means is that for certain diffracted beams with a given spatial frequency u the contribution to contrast in the recorded image will be reversed, thus making interpretation of the image difficult.

Scherzer defocus

In Scherzer defocus, one aims to counter the term in u⁴ with the parabolic term Δfu² of χ(u). Thus by choosing the right defocus value Δf one flattens χ(u) and creates a wide band where low spatial frequencies u are transferred into image intensity with a similar phase. In 1949, Scherzer found that the optimum defocus depends on microscope properties like the spherical aberration C_s and the accelerating voltage (through λ) in the following way:

${\displaystyle \Delta f_{\text{Scherzer}}=-1.2{\sqrt {C_{s}\lambda }}\,}$

where the factor 1.2 defines the extended Scherzer defocus. For the CM300 at NCEM, C_s = 0.6mm and an accelerating voltage of 300keV (λ = 1.97 pm) (Wavelength calculation) result in Δf_Scherzer = -41.25 nm. 

The point resolution of a microscope is defined as the spatial frequency u_res where the CTF crosses the abscissa for the first time. At Scherzer defocus this value is maximized:

${\displaystyle u_{\text{res}}({\text{Scherzer}})=0.6\lambda ^{3/4}C_{s}^{1/4},}$

which corresponds to 6.1 nm⁻¹ on the CM300. Contributions with a spatial frequency higher than the point resolution can be filtered out with an appropriate aperture leading to easily interpretable images at the cost of a lot of information lost.

Gabor defocus

Gabor defocus is used in electron holography where both amplitude and phase of the image wave are recorded. One thus wants to minimize crosstalk between the two. The Gabor defocus can be expressed as a function of the Scherzer defocus as

${\displaystyle \Delta f_{\text{Gabor}}=0.56\Delta f_{\text{Scherzer}}}$

Lichte defocus

To exploit all beams transmitted through the microscope up to the information limit, one relies on a complex method called exit wave reconstruction which consists in mathematically reversing the effect of the CTF to recover the original exit wave φ_e(x,u). To maximize the information throughput, Hannes Lichte proposed in 1991 a defocus of a fundamentally different nature than the Scherzer defocus: because the dampening of the envelope function scales with the first derivative of χ(u), Lichte proposed a focus minimizing the modulus of dχ(u)/du 

${\displaystyle \Delta f_{\text{Lichte}}=-0.75C_{s}(u_{\max }\lambda )^{2},}$

where u_max is the maximum transmitted spatial frequency. For the CM300 with an information limit of 0.8 Å Lichte defocus lies at −272 nm.

Exit wave reconstruction

Exit wave reconstruction through focal series

To calculate back to φ_e(x,u) the wave in the image plane is back propagated numerically to the sample. If all properties of the microscope are well known, it is possible to recover the real exit wave with very high accuracy. 

First however, both phase and amplitude of the electron wave in the image plane must be measured. As our instruments only record amplitudes, an alternative method to recover the phase has to be used. There are two methods in use today:

• Holography, which was developed by Gabor expressly for TEM applications, uses a prism to split the beam into a reference beam and a second one passing through the sample. Phase changes between the two are then translated in small shifts of the interference pattern, which allows recovering both phase and amplitude of the interfering wave.
• Through focal series method takes advantage of the fact that the CTF is focus dependent. A series of about 20 pictures is shot under the same imaging conditions with the exception of the focus which is incremented between each take. Together with exact knowledge of the CTF the series allows for computation of φ_e(x,u) (see figure).

Both methods extend the point resolution of the microscope past the information limit, which is the highest possible resolution achievable on a given machine. The ideal defocus value for this type of imaging is known as Lichte defocus and is usually several hundred nanometers negative.