[分享]阅读机经相关英文背景材料---持续更新（至机经39飞蛾拟声）

buda

hoho，偶们CDer很强大，很团结。我们懂分享，懂回报，懂感恩！

GavinDing

好東西怎麼沉了~~~

lancyfly

支持

yuren1978

这种背景材料要小心领会，个人认为看一些生词就够了， 不适合花大精力。

buda

同意楼上，看个大概混个脸熟就好

buda

Dune

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This article is about sand formations. For other uses, see Dune (disambiguation).

In physical geography, a dune is a hill of sand built by eolian processes. Dunes are subject to different forms and sizes based on their interaction with the wind. Most kinds of dune are longer on the windward side where the sand is pushed up the dune, and a shorter "slip face" in the lee of the wind. The "valley" or trough between dunes is called a slack. A "dune field" is an area covered by extensive sand dunes. Large dune fields are known as ergs.

Some coastal areas have one or more sets of dunes running parallel to the shoreline directly inland from the beach. In most cases the dunes are important in protecting the land against potential ravages by storm waves from the sea. Although the most widely distributed dunes are those associated with coastal regions, the largest complexes of dunes are found inland in dry regions and associated with ancient lake or sea beds.

Dunes also form under the action of water flow (alluvial processes), on sand or gravel beds of rivers, estuaries and the sea-bed.

The modern word "dune" came into English from French circa 1790 but it's an old Indo-European word that's found in most of the Slavic languages as well as the Germanic and Latin languages. In ancient times words cognate to "dune" probably had the meaning of a citadel or built-up hill fortification.[1]

[edit]
            Conservation

Dune habitats provide niches for highly specialized plants and animals, including numerous rare and endangered species. Due to human population expansion dunes face destruction through recreation and land development, as well as alteration to prevent encroachment on inhabited areas. Some countries, notably the U.S., New Zealand, Great Britain, Australia, Canada and the Netherlands have developed extensive programs of dune protection. In the UK, a Biodiversity Action Plan has been developed to assess dunes loss and prevent future dunes destruction.

[edit]
            Dune shapes

[edit]
            Crescentic

Crescent-shaped mounds are generally wider than they are long. The slipface is on the dune's concave side. These dunes form under winds that blow from one direction, and they also are known as barchans, or transverse dunes. Some types of crescentic dunes move faster over desert surfaces than any other type of dune. A group of dunes moved more than 100 meters per year between 1954 and 1959 in the People's Republic of China's Ningxia Province; similar rates have been recorded in the Western Desert of Egypt. The largest crescentic dunes on Earth, with mean crest-to-crest widths of more than 3 kilometers, are in China's Taklamakan Desert.

[edit]
            Linear

Straight or slightly sinuous sand ridges typically much longer than they are wide are known as linear dunes. They may be more than 160 kilometers long. Linear dunes may occur as isolated ridges, but they generally form sets of parallel ridges separated by miles of sand, gravel, or rocky interdune corridors. Some linear dunes merge to form Y-shaped compound dunes. Many form in bidirectional wind regimes. The long axes of these dunes extend in the resultant direction of sand movement.

[edit]
            Star

Radially symmetrical, star dunes are pyramidal sand mounds with slipfaces on three or more arms that radiate from the high center of the mound. They tend to accumulate in areas with multidirectional wind regimes. Star dunes grow upward rather than laterally. They dominate the Grand Erg Oriental of the Sahara. In other deserts, they occur around the margins of the sand seas, particularly near topographic barriers. In the southeast Badain Jaran Desert of China, the star dunes are up to 500 meters tall and may be the tallest dunes on Earth.

[edit]
            Dome

Oval or circular mounds that generally lack a slipface, dome dunes are rare and occur at the far upwind margins of sand seas.

[edit]
            Parabolic

U-shaped mounds of sand with convex noses trailed by elongated arms are parabolic dunes. Sometimes these dunes are called U-shaped, blowout, or hairpin dunes, and they are well known in coastal deserts. Unlike crescent shaped dunes, their crests point upwind. The elongated arms of parabolic dunes follow rather than lead because they have been fixed by vegetation, while the bulk of the sand in the dune migrates forward.

[edit]
            Longitudinal (Seif) and transverse dunes

                

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Seif dunes.

Longitudinal dunes (also called Seif dunes, after the Arabic word for "sword"), elongate parallel to the prevailing wind, possibly caused by a larger dune having its smaller sides blown away. Seif dunes are sharp-crested and are common in the Sahara. They range up to 300 m (900 ft) in height and 300 km (200 mi) in length. In the southern third of the Arabian Peninsula, a region called the Empty Quarter because of its total lack of populatation, a vast erg called Rub al Khali conatins seif dunes that stretch for almost 200 km and reach heights of over 300m.

Seif dunes are thought to develop from barchans if a change of wind direction occurs. The new wind direction will lead to the development of a new wing and the over development of one of the original wings. If the prevailing wind then becomes dominant for a lengthy period of time the dune will revert to its barchan form, with one exaggerated wing. Should the strong wind then return the exaggerated wing will further extend so that eventually it will be supplied with sand when the prevailing wind returns. The wing will continue to grow under both wind conditions, thus producing a seif dune. On a seif dune the slip face develops on the side facing away from the strong wind, while the slip face of a barchan faces the direction of movement. In the sheltered troughs between highly developed seif dunes barchans may be formed because the wind is unidirectional.

A transverse dune is perpendicular to the prevailing wind, probably caused by a steady buildup of sand on an already existing minuscule mound.

[edit]
            Reversing dunes

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Complex dune: Dune 7 in the Namib desert, one of the tallest in the world.

Occurring wherever winds periodically reverse direction, reversing dunes are varieties of any of the above shapes. These dunes typically have major and minor slipfaces oriented in opposite directions.

All these dune shapes may occur in three forms: simple, compound, and complex. Simple dunes are basic forms with a minimum number of slipfaces that define the geometric type. Compound dunes are large dunes on which smaller dunes of similar type and slipface orientation are superimposed, and complex dunes are combinations of two or more dune types. A crescentic dune with a star dune superimposed on its crest is the most common complex dune. Simple dunes represent a wind regime that has not changed in intensity or direction since the formation of the dune, while compound and complex dunes suggest that the intensity and direction of the wind has changed.

[edit]
            Dune types

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The Great Dune of Pyla is the largest dune in Europe.

[edit]
            Sub-aqueous dunes

Sub-aqueous (underwater) dunes form on a bed of sand or gravel under the actions of water flow. They are ubiquitous in natural channels such as rivers and estuaries, and also form in engineered canals and pipelines. Dunes move downstream as the upstream slope is eroded and the sediment deposited on the downstream or lee slope.

These dunes most often form as a continuous 'train' of dunes, showing remarkable similarity in wavelength and height.

Dunes on the bed of a channel significantly increase flow resistance, their presence and growth playing a major part in river flooding.

[edit]
            Lithified dunes

A lithified (consolidated) sand dune is a type of sandstone that is formed when a marine or eolian sand dune becomes compacted and hardened. Once in this form, water passing through the rock can carry and deposit minerals, which can alter the hue of the rock. Cross-bedded layers of stacks of lithified dunes can produce the cross-hatching patterns, such as those seen in Zion National Park.

A local slang term used for these consolidated dunes is "slickrock", a name that was introduced by pioneers of the old west because their steel-rimmed wagon wheels could not gain purchase on the rock.

[edit]
            Coastal dunes

                

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Coastal dunes in Curonian spit.

                

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The fore dune and first yellow dune at Studland, England.

Dunes form where constructive waves encourage the accumulation of sand, and where prevailing onshore winds blow this sand inland. There needs to be obstacles e.g. vegetation, pebbles etc. to trap the moving sand grains. As the sand grains get trapped they start to accumulate, this is the start of dune formation. The wind then starts to affect the mound of sand by eroding sand particles from the windward side and depositing them on the leeward side. Gradually this action causes the dune to “migrate” inland, as it does so it accumulates more and more sand. Dunes provide privacy and shelter from the wind.

[edit]
            Ecological succession on coastal dunes

As a dune forms, plant succession occurs. The conditions on an embryo dune are harsh, with salt spray from the sea carried on strong winds. The dune is well drained and often dry, and composed of calcium carbonate from seashells. Rotting seaweed, brought in by storm waves adds nutrients to allow pioneer species to colonize the dune. These pioneer species are marram grass, sea wort grass and other sea grasses in the UK. These plants are well adapted to the harsh conditions of the fore-dune typically having deep roots which reach the water table, root nodules that produce nitrogen compounds, and protected stoma, reducing transpiration. Also, the deep roots bind the sand together, and the dune grows into a fore dune as more sand is blown over the grasses. The grasses add nitrogen to the soil, meaning other, less hardy plants can then colonize the dunes. Typically these are heathers and gorses. These too are adapted to the low soil water content and have small, prickly leaves which reduce transpiration. Heathers add humus to the soil, but have a pH of lower than 7, so make the soil slightly acidic. Heathers are usually replaced by coniferous trees which can tolerate the low pH. Coniferous forests and heathland are common climax communities for sand dune systems.

Young dunes are called yellow dunes, dunes which have high humus content are called grey dunes. Leaching occurs on the dunes, washing humus into the slacks, and the slacks may be much more developed than the exposed tops of the dunes. It is usually in the slacks that more rare species are developed and there is a tendency for the dune slacks soil to be waterlogged and where only marsh plants can survive. These plants would include: creeping willow, cotton grass, yellow ins, reeds, and rushes. As for the species, there is a tendency for natterjack toads to breed here.

buda

Song of Dunes. This is a natural
    sound
    phenomenon of up to 105 decibels lasting as long as several minutes that occurs in about 35 desert locations around the world. The sound is similar to a loud, low-pitch, rumble, and it emanates from the crescent-shaped dunes, or barchans. The sound emission accompanies a slumping or avalanching movement of the sand, usually triggered by wind passing over the dune or by someone walking near the crest. Scientists announced in 2004 that they had discovered how the singing sand phenomenon works: collisions between grains of sand emit surface elastic waves that in turn, cause the motions of the grains to become synchronized. The sound in the air is emitted by the vibration of the sand surface (by the surface elastic waves) that behaves like a loudspeaker. The resonance of the outer layer of the dune controls the threshold of the phenomenon: a sufficiently deep layer of dry sand at the surface is necessary for booming to occur. The scientists suggested that the most beautiful sounds come from dunes in Oman.

The particular note produced by the dune, between 60 and 105 Hertz, is controlled by the rate of collision in the shear band separating the avalanche from the static part of the dune. For spontaneous avalanches, the frequency is controlled by gravity and by the size of the sand grains.

Singing sand, whistling sand or barking sand is sand that produces sounds of either high or low frequency under pressure. The sound emission is usually triggered by wind passing over dunes or by walking on the sand. The sound is generated by shear stress.

Certain conditions have to come together to create singing sand:

1. The sand grains have to be round and between 0.1 and 0.5 mm in diameter
           
2. The sand has to contain silica
           
3. The sand needs to be a certain humidity
           

The most common frequency emitted seems to be close to 450 Hz.

Importantly, there are still scientific controversies on the details of the singing sand mechanism (see references). It has been proposed that the sound frequency is controlled by the shear rate. Others have suggested that the frequency of vibration is related to the thickness of the dry surface layer of sand. The sound waves bounce back and forth between the surface of the dune and the surface of the moist layer creating a resonance that increases the sound's volume.

Other sounds that can be emitted by sand have been described as "roaring" or "booming".

buda

The use of licensed oral vaccines for the mass vaccination of free-ranging wildlife should be considered in selected situations, with the approval of the state agency responsible for animal rabies control (5,36). The distribution of oral rabies vaccine should be based on scientific assessments of the target species and followed by timely and appropriate analysis of surveillance data; such results should be provided to all stakeholders. In addition, parenteral vaccination (trap-vaccinate-release) of wildlife rabies reservoirs can be integrated into coordinated oral rabies vaccination programs to enhance their effectiveness. Long-term, widespread programs for trapping or poisoning wildlife are not effective in reducing wildlife rabies reservoirs on a statewide basis. However, limited population control in high-contact areas (e.g., picnic grounds, camps, and suburban areas) might be indicated for the removal of selected high-risk species of wildlife (5). State agriculture, public health, and wildlife agencies should be consulted for planning, coordination, and evaluation of vaccination or population-reduction programs.

 

Oral Rabies Vaccination
    

Oral rabies vaccination (ORV) has been under field investigation in the United States since 1990, in Canada since 1985 and in Europe since 1980. Currently, there are 15 states distributing oral vaccines for raccoons in the U.S., while Texas distributes baits for gray fox and coyote. There have been nearly 48 million doses of Raboral V-RG® distributed in the U.S. and Canada, and 63 million doses have been dispersed worldwide. Raboral V-RG® is currently the only effective oral vaccine licensed for use in free-ranging raccoons, gray foxes, and coyotes in the United States.

V-RG is a recombinant vaccine made from a living pox virus vector, vaccinia (V), that carries the rabies antigen in the form of rabies glycoprotein (RG). The rabies glycoprotein is the protective sheath that surrounds the rabies virus and elicits an immune response when swallowed by raccoons, gray foxes, or coyotes. The vaccine cannot cause rabies because it contains only the non-infective surface proteins of the rabies virus, not the viral nuclear material which would be necessary for the virus to replicate and cause an infection.

The outer bait matrix is made from fishmeal (for raccoons and coyotes) or dog food (for gray foxes) combined with a polymer that acts as a binding agent. The vaccine packet, or sachet, resembles a small catsup package but contains about 1.5 ml of vaccine. The sachet is inside the bait matrix and waxed into place so it does not fall out during aerial delivery. As the raccoon, gray fox, or coyote eats through the outer bait matrix, the inner sachet gets punctured allowing vaccine to enter the animal’s mouth and coat the lymphatic tissue in the throat. There is an immune response to the rabies antigen which creates antibodies to fight off the disease. After two to three weeks the “blueprint” to create rabies antibodies exists in the animal’s immune system which can easily be created should the animal be exposed to a rabid animal.

Baits are distributed by airplanes in rural areas and by hand in urban and suburban areas. Airplanes fly in straight lines or “transects” at about 500 feet above ground while distributing baits. The bait distribution machine is controlled from the airplane and is turned off when crossing a road or house to avoid human contact with the bait. Baiting by hand is done in urban and suburban areas to get the best chance to vaccinate an animal while decreasing human contact with baits. In 2003, more than 10 million baits were distributed in the U.S. and Canada.

 

Oral vaccination programs that have proved effective in the
        wild to control rabies in red foxes used liquid vaccines enclosed
        in a bait, with bait distribution programs recommended twice
        per year (World Health Organization, 1992). A spring program
        is designed to vaccinate adult foxes that have survived the
        winter and an autumn program to vaccinate young from the previous
        summer. A vaccination rate of 50–70% has been proposed
        as the coverage required to prevent an epizootic from spreading
        through an animal population (Wandeler, 1991). This type of
        program could fail in arctic regions, where freezing temperatures
        can occur throughout the year, especially during spring and
        autumn. A liquid vaccine could freeze and thereby be ineffective,
        should it pass directly into the stomach without vaccine virus
        being absorbed through the buccal and pharyngeal mucosa. It
        is not unusual for arctic foxes to scavenge frozen carcasses.
        Therefore, eating frozen vaccine-bait would be expected. Solutions
        to avoid this problem are a coated vaccine that passes through
        the stomach and is enterically absorbed (Wandeler, 1991) or
        a lyophilized vaccine that would not be negatively affected
        by freezing temperatures and require chewing to expose vaccine
        virus to buccal and pharyngeal mucosa. The present article evaluates
        the latter approach in captive foxes. Although the ultimate
        success of a vaccine and distribution program is to evaluate
        it in the field, it is necessary to first determine the effectiveness
        of a new version of a vaccine under controlled conditions.
        

buda

这个文章应该是比较对口的，但是很无奈国外的网好像上不去。只能看这一页

Abstract

Parasitic and predatory arthropods often prevent plants from being severely damaged by killing herbivores as they feed on the plants. Recent studies show that a variety of plants, when injured by herbivores, emit chemical signals that guide natural enemies to the herbivores. It is unlikely that herbivore-damaged plants initiate the production of chemicals solely to attract parasitoids and predators. The signaling role probably evolved secondarily from plant responses that produce toxins and deterrents against herbivores and antibiotics against pathogens. To effectively function as signals for natural enemies, the emitted volatiles should be clearly distinguishable from background odors, specific for prey or host species that feed on the plant, and emitted at times when the natural enemies forage. Our studies on the phenomena of herbivore-induced emissions of volatiles in corn and cotton plants and studies conducted by others indicate that (i) the clarity of the volatile signals is high, as they are unique for herbivore damage, produced in relatively large amounts, and easily distinguishable from background odors; (ii) specificity is limited when different herbivores feed on the same plant species but high as far as odors emitted by different plant species and genotypes are concerned; (iii) the signals are timed so that they are mainly released during the daytime, when natural enemies tend to forage, and they wane slowly after herbivory stops.

buda

INUIT WHALING HISTORY
Before Europeans began hunting large whales along Greenland's west coast and in the Canadian Eastern Arctic, Inuit hunters took bowhead whales (-Greenland right whales.) and other whale species for food and raw materials such -as baleen and bone. Whale products, and in particular baleen, were part of a flourishing and extensive exchange economy throughout West Greenland, and local belie& emphasised the importance of showing proper respect for whales to ensure a safe and successful hunt.

But in the 17th and 18th centuries, European whalers pushed the bowhead to the brink of extinction, and colonial settlers severely undermined Inuit beliefs and whaling practices. For a while during this period, local hunters were employed by a Danish trading monopoly to catch whales, while their own whaling practices persisted only in few places, in some cases for large whales but mostly for smaller cetaceans. in the Canadian Eastern Arctic also, the mid-19th century saw European whalers employing many Inuit in their commercial whaling operations. With their new whaling equipment and the decimation of the bowhead populations, these Europeans were responsible for profound changes in the traditional hunt. Once the commercial bowhead fishery ended, commercial hunts for the smaller beluga were carried out by trading companies. These operations continued until the mid-20th century, with skins and blubber being exported to Europe.

In the first half of the 20th century, Danish authorities oversaw whaling in West Greenland using a large catcherboat equipped with a harpoon cannon. Whales were towed to communities where locals flensed them in exchange for meat and mattak the whale skin, while the blubber was sent to Denmark to cover operating costs.