Английская Википедия:Decline in insect populations

Материал из Онлайн справочника
Версия от 22:42, 25 февраля 2024; EducationBot (обсуждение | вклад) (Новая страница: «{{Английская Википедия/Панель перехода}} {{Short description|Ecological trend recorded since the late 20th century}} {{Use British English|date=November 2021}} thumb|An annual decline of 5.2% in flying insect [[biomass (ecology)|biomass found in nature reserves in Germany – about 75% loss in 26 years<ref name=Hallmann2017PLoS/>]] Insects are the most numerous and widespread clas...»)
(разн.) ← Предыдущая версия | Текущая версия (разн.) | Следующая версия → (разн.)
Перейти к навигацииПерейти к поиску

Шаблон:Short description Шаблон:Use British English

Файл:Journal.pone.0185809.g004.PNG
An annual decline of 5.2% in flying insect biomass found in nature reserves in Germany – about 75% loss in 26 years[1]

Insects are the most numerous and widespread class in the animal kingdom, accounting for up to 90% of all animal species.[2][3] In the 2010s, reports emerged about the widespread decline in insect populations across multiple insect orders. The reported severity shocked many observers, even though there had been earlier findings of pollinator decline. There has also been anecdotal reports of greater insect abundance earlier in the 20th century. Many car drivers know this anecdotal evidence through the windscreen phenomenon, for example.[4][5] Causes for the decline in insect population are similar to those driving other biodiversity loss. They include habitat destruction, such as intensive agriculture, the use of pesticides (particularly insecticides), introduced species, and – to a lesser degree and only for some regions – the effects of climate change.[6] An additional cause that may be specific to insects is light pollution (research in that area is ongoing).[7][8][9]

Most commonly, the declines involve reductions in abundance, though in some cases entire species are going extinct. The declines are far from uniform. In some localities, there have been reports of increases in overall insect population, and some types of insects appear to be increasing in abundance across the world.[10] Not all insect orders are affected in the same way; most affected are bees, butterflies, moths, beetles, dragonflies and damselflies. Many of the remaining insect groups have received less research to date. Also, comparative figures from earlier decades are often not available.[10] In the few major global studies, estimates of the total number of insect species at risk of extinction range between 10% and 40%,[11][6][12][13] though all of these estimates have been fraught with controversy.[14][15][16][17]

Studies concur that in areas where insects are declining, their abundance had been diminishing for decades. Yet, those trends had not been spotted earlier, as there has historically been much less interest in studying insects in comparison to mammals, birds and other vertebrates. One reason is the comparative lack of charismatic species of insects. In 2016, it was observed that while 30,000 insect species are known to inhabit Central Europe, there are practically no specialists in the region devoted to full-time monitoring.[4] This issue of insufficient research is even more acute in the developing countries. As of 2021, nearly all of the studies on regional insect population trends come from Europe and the United States, even though they account for less than 20% of insect species worldwide. In Africa, Asia and South America there are hardly any observations of insects that span several decades. Such studies would be required to draw conclusions about population trends on a large scale.[18]

To respond to these declines, various governments have introduced conservation measures to help insects. For example, the German government started an Action Programme for Insect Protection in 2018.[19][20] The goals of this program include promoting insect habitats in the agricultural landscape, and reducing pesticide use, light pollution, and pollutants in soil and water.[20]

Context

Файл:Melanoplus spretusAnnReportAgExpStaUM1902B.jpg
A 1902 illustration of a Rocky Mountain locust. These insects were seen in swarms estimated at over 10 trillion members as late as 1875. Soon after, their population rapidly declined, with the last recorded sighting in 1902, and the species formally declared extinct in 2014.

The fossil record concerning insects stretches back hundreds of millions of years. It suggests there are ongoing background levels of both new species appearing and extinctions. Very occasionally, the record also appears to show mass extinctions of insects, understood to be caused by natural phenomena such as volcanic activity or meteor impact. The Permian–Triassic extinction event saw the greatest level of insect extinction, and the Cretaceous–Paleogene the second highest. Insect diversity has recovered after mass extinctions, as a result of periods in which new species originate with increased frequency, although the recovery can take millions of years.[21]

Concern about a human-caused Holocene extinction has been growing since the late 20th century, although much of the early concern was not focused on insects. In a report on the world's invertebrates, the Zoological Society of London suggested in 2012 that insect populations were in decline globally, affecting pollination and food supplies for other animals.[22][23][5][24] It estimated that about 20 percent of all invertebrate species were threatened with extinction, and that species with the least mobility and smallest ranges were most at risk.[22]

Studies finding insect decline have been available for decades—one study tracked a decline from 1840 to 2013—but it was the 2017 re-publication of the German nature reserves study[1] that saw the issue receive widespread attention in the media.[4][5] The press reported the decline with alarming headlines, including "Insect Apocalypse".[24][25] Ecologist Dave Goulson told The Guardian in 2017: "We appear to be making vast tracts of land inhospitable to most forms of life, and are currently on course for ecological Armageddon."[26] For many studies, factors such as abundance, biomass, and species richness are often found to be declining for some, but not all locations; some species are in decline while others are not.[15] The insects studied have mostly been butterflies and moths, bees, beetles, dragonflies, damselflies and stoneflies. Every species is affected in different ways by changes in the environment, and it cannot be inferred that there is a consistent decrease across different insect groups. When conditions change, some species adapt easily to the change while others struggle to survive.[27]

A March 2019 statement by the Entomological Society of America said there was not yet sufficient data to predict an imminent mass extinction of insects and that some of the extrapolated predictions might "have been extended well past the limits of the data or have been otherwise over-hyped".[28] For some insect groups such as some butterflies, moths, bees, and beetles, declines in abundance and diversity have been documented in European studies. These have generally led to an overall pattern of decline, but there are variable trends for individual species within groups. For instance, a minority of British moths are becoming more common.[29] Other areas have shown increases in some insect species, although trends in most regions are currently unknown. It is difficult to assess long-term trends in insect abundance or diversity because historical measurements are generally not known for many species. Robust data to assess at-risk areas or species is especially lacking for arctic and tropical regions and a majority of the southern hemisphere.[28]

In March 2019 Chris D. Thomas and other scientists wrote in response to the apocalyptic "Insectageddon" predictions of Sánchez-Bayo, "we respectfully suggest that accounts of the demise of insects may be slightly exaggerated". They called for "joined-up thinking" in responding to insect declines, backed up by more robust data than were currently available.[15]

Global estimates

Файл:Percent of insect species.svg
Insects with population trends documented by the International Union for Conservation of Nature, for orders Collembola, Hymenoptera, Lepidoptera, Odonata, and Orthoptera

A 2020 meta-analysis found that globally terrestrial insects appear to be declining in abundance at a rate of about 9% per decade, while the abundance of freshwater insects appears to be increasing by 11% per decade. The study analysed 166 long-term studies, involving 1676 different sites across the world. It found considerable variations in insect decline depending on locality – the authors considered this a hopeful sign, as it suggests local factors, including conservation efforts, can make a big difference. The article stated that the increase in freshwater insects may in part be due to efforts to clean up lakes and rivers, and may also relate to global warming and enhanced primary productivity driven by increased nutrient inputs.[12] However, the data selection and methodology of the article were criticised in several publications.[16][17]

In 2022, 66 researchers conducted a survey of 3331 biodiversity experts (meaning scientists who published a study on the subject of biodiversity over the past decade). This included 629 experts in terrestrial and freshwater invertebrates: on average, they believed that around 30% (with an uncertainty range between 20 and 50%) of these species are or have been threatened with extinction (including the species which had already gone extinct since 1500). As insects account for the vast majority of the world's invertebrates, this figure by extension applies to them as well.[13]

A 2019 survey of 24 entomologists working on six continents found that on a scale of 0 to 10, with 10 being the worst, all the scientists rated the severity of the insect decline crisis as being between 8–10.[30]

Global assessment report on biodiversity and ecosystem services

Шаблон:Main

The Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services reported its assessment of global biodiversity in 2019. Its summary for insect life was that "Global trends in insect populations are not known but rapid declines have been well documented in some places. ... Local declines of insect populations such as wild bees and butterflies have often been reported, and insect abundance has declined very rapidly in some places even without large-scale land-use change, but the global extent of such declines is not known. ... The proportion of insect species threatened with extinction is a key uncertainty, but available evidence supports a tentative estimate of 10 per cent."[11] In 2022, some researchers had expressed concern about the apparent mismatch between this tentative IPBES estimate, and that of 629 experts on invertebrate biodiversity they surveyed, which was closer to 30%. They argued that more investigations into insects and other "hyperdiverse and understudied taxa" are urgently required to clarify the matter.[13]

Causes

Шаблон:See also

Destruction and pollution

The causes of the declines in insect populations, and their relative importance, are not fully understood. They are likely to vary between different insect groups and geographical regions.[31] A study placed these causes in the order of importance as follows: "(i) habitat loss and conversion to intensive agriculture and urbanisation; ii) pollution,[32] mainly that by synthetic pesticides and fertilisers; iii) biological factors, including pathogens and introduced species; and iv) climate change."[33]

Light pollution also plays a role.[7][8][9] Other factors that are thought to be important are introduced species[34][6] and eutrophication from fertilisers.

The use of increased quantities of insecticides and herbicides on crops have affected not only non-target insect species, but also the plants on which they feed.

For example, a review in 2017 commented on a large study in Germany about insect population decline as follows: "The authors of the German study were not able to link the observed decline to climate change or pesticide use; although agricultural intensification and the practices associated with it, were, however, suggested as likely to be involved in some way."[4]

Climate change

Climate change and the introduction of exotic species (see climate change and invasive species) that compete with the indigenous ones put the native species under stress, and as a result they are more likely to succumb to pathogens and parasites.[27] Plants grow faster in presence of increased CO2 (due to the CO2 fertilisation effect) but the resulting plant biomass contains fewer nutrients.[35] While some species such as flies and cockroaches might increase as a result,[6] the total biomass of insects is estimated to be decreasing by between about 0.9 to 2.5% per year.[36][12]

Шаблон:Excerpt

Methodology

Three principal metrics are used to capture and report on insect declines:

  • Abundance – simply put the numerical total of individual insects. Depending on context, it can refer to the number of insects in a particular assembly, in a geographical area, or the sum total of insects globally (regardless of which species the individuals belong to).
  • Biomass – the total weight of insects (again regardless of species).
  • Biodiversity – the number of extant insect species. Depending on context, a reduction in biodiversity can mean certain species of insects have vanished locally, though it may mean species have gone totally extinct across the entire planet.[37][12][6]

Most of the individual studies tracking insect declines report just abundance, others just on biomass, some on both, and yet others report on all three metrics. Data directly related to diversity loss at global level is more sparse than for abundance or biomass declines. Estimates for diversity loss at a planetary level tend to involve extrapolating from abundance or biomass data; while studies sometimes show local extirpation of an insect species, actual world wide extinctions are challenging to discern. In a 2019 review, David Wagner noted that currently the Holocene extinction is seeing animal species loss at about 100–1,000 times the planet's normal background rate, and that various studies found a similar, or possibly even faster extinction rate for insects. Wagner opines that serious though this biodiversity loss is, it is the decline in abundance that will have the most serious ecological impact.[37][12][6][38]

In theory it is possible for the three metrics to be independent. For instance, a decline in biomass might not involve a decrease in abundance or diversity if all that was happening was that typical insects were getting smaller. In practice though, abundance and biomass tend to be closely related, typically showing a similar level of decline. Change in biodiversity is often, though not always, directly proportional to the other two metrics.[12][6] Some studies find cases where, in certain locations, change in biodiversity is inversely proportional to the other metrics. For example, a 42 year study of insects in the pristine Breitenbach stream near Schlitz, which is believed to have been unaffected by anthropogenic decline related causes except for climate change, found that while abundance of insects decreased, biodiversity actually rose, especially during the first half of the study.[39]

Survey results for specific regions

United Kingdom

The Rothamsted Insect Survey at Rothamsted Research, Harpenden, England, began monitoring insect suction traps across the UK in 1964. According to the group, these have produced "the most comprehensive standardised long-term data on insects in the world".[40] The traps are "effectively upside-down Hoovers running 24/7, continually sampling the air for migrating insects", according to James Bell, the survey leader, in an interview in 2017 with the journal Science. Between 1970 and 2002, the insect biomass caught in the traps declined by over two-thirds in southern Scotland, although it remained stable in England. The scientists speculate that insect abundance was already lost in England by 1970 (figures in Scotland were higher than in England when the survey began), or that aphids and other pests increased there in the absence of their insect predators.[10]

A 2014 review noted: "Of all insects with IUCN-documented population trends [203 insect species in five orders], 33% are declining, with strong variation among orders." In the UK, "30 to 60% of species per order have declining ranges". Insect pollinators, "needed for 75% of all the world's food crops", appear to be "strongly declining globally in both abundance and diversity", which has been linked in Northern Europe to the decline of plant species that rely on them. The study referred to the human-caused loss of vertebrates and invertebrates as the "Anthropocene defaunation".[38][25]

Anecdotal evidence for insect decline has been offered by those who recall apparently greater insect abundance in the 20th century. Entomologist Simon Leather recalls that, in the 1970s, windows of Yorkshire houses he visited on his early-morning paper round would be "plastered with tiger moths" attracted by the house's lighting during the night. Tiger moths have now largely disappeared from the area.[41] Another anecdote is recalled by environmentalist Michael McCarthy concerning the vanishing of the "moth snowstorms", a relatively common sight in the UK in the 1970s and earlier. Moth snowstorms occurred when moths congregated with such density that they could appear like a blizzard in the beam of automobile headlights.[42]

In 2004 the Royal Society for the Protection of Birds organised a Big Bug Count, issuing "splatometers" to about 40,000 volunteers to help count the number of insects colliding with their number plates. They found an average of one insect per 5 miles (8 km), which was less than expected.[43][44]

GermanyШаблон:Anchor

Файл:Malaise trap, Germany.jpg
Malaise traps in German nature reserves[1]

In 2013 the Krefeld Entomological Society reported a "huge reduction in the biomass of insects"[4] caught in malaise traps in 63 nature reserves in Germany (57 in Nordrhein-Westfalen, one in Rheinland-Pfalz and one in Brandenburg).[45][46] A reanalysis published in 2017 suggested that, in 1989–2016, there had been a "seasonal decline of 76%, and mid-summer decline of 82%, in flying insect biomass over the 27 years of study". The decline was "apparent regardless of habitat type" and could not be explained by "changes in weather, land use, and habitat characteristics". The authors suggested that not only butterflies, moths and wild bees appear to be in decline, as previous studies indicated, but "the flying insect community as a whole".[1][4][47][48][49]

Scientists stated in 2019: "In 2017, a 27-year long population monitoring study revealed a shocking 76% decline in flying insect biomass at several of Germany's protected areas (Hallmann et al., 2017). This represents an average 2.8% loss in insect biomass per year in habitats subject to rather low levels of human disturbance, which could either be undetectable or regarded statistically non-significant if measurements were carried out over shorter time frames. Worryingly, the study shows a steady declining trend over nearly three decades."[6]

According to The Economist, the study was the "third most frequently cited scientific study (of all kinds) in the media in 2017". It "pushed the governments of Germany and the Netherlands into setting up programmes to protect insect diversity."[50] The British entomologist Simon Leather said that he hoped media reports, following the study, of an "ecological Armageddon" had been exaggerated; he argued that the Krefeld and other studies should be a wake-up call, and that more funding is needed to support long-term studies.[4][26][51] The Krefeld study's authors were not able to link the decline to climate change or pesticides, he wrote, but they suggested that intensive farming was involved. While agreeing with their conclusions, he cautioned that "the data are based on biomass, not species, and the sites were not sampled continuously and are not globally representative".

Puerto Rico

A 2018 study of the El Yunque National Forest in Puerto Rico reported a decline in arthropods, and in lizards, frogs, and birds (insect-eating species) based on measurements in 1976 and 2012.[52][6] The American entomologist David Wagner called the study a "clarion call" and "one of the most disturbing articles" he had ever read.[53] The researchers reported "biomass losses between 98% and 78% for ground-foraging and canopy-dwelling arthropods over a 36-year period, with respective annual losses between 2.7% and 2.2%".[6] The decline was attributed to a rise in the average temperature; tropical insect species cannot tolerate a wide range of temperatures.[52][6][36] The researchers were shocked by the results: "We couldn't believe the first results. I remember [in the 1970s] butterflies everywhere after rain. On the first day back [in 2012], I saw hardly any."[50]

Netherlands

In 2019 a study of butterfly numbers in the Netherlands from 1890 to 2017 reported an estimated decline of 84 percent. When analysed by type of habitat, the trend was found to have stabilised in grassland and woodland in recent decades but the decline continued in heathland. The decline was attributed to changes in land use due to more efficient farming methods, which has caused a decline in weeds. The recent up-tick in some populations documented in the study was attributed to (conservationist) changes in land management and thus an increase in suitable habitat.[54][55][56][57]

Switzerland

A report by the Swiss Academy of Natural Sciences in April 2019 reported that 60 percent of the insects that had been studied in Switzerland were at risk, mostly in farming and aquatic areas; that there had been a 60 percent decline in insect-eating birds since 1990 in rural areas; and that urgent action was needed to address the causes.[58][59]

United States and Western Europe Шаблон:Anchor

Файл:SympetrumInfuscatum.jpg
Except for taxa regarded as beneficial or charismatic, such as the pictured dragonfly, there is relatively little population decline data available for specific insect species.

A 2019 review analysed 73 long-term insect surveys that had shown decline, most of them in the United States and Western Europe.[6][60] While noting population increases for certain species of insects in particular areas, the authors reported an annual 2.5% loss of biomass. They wrote that the review "revealed dramatic rates of decline that may lead to the extinction of 40% of the world's insect species over the next few decades",[6][61] a conclusion that was challenged.[62][63] They did note the review's limitations, namely that the studies were largely concentrated on popular insect groups (butterflies and moths, bees, dragonflies and beetles); few had been done on groups as Diptera (flies), Orthoptera (which includes grasshoppers and crickets), and Hemiptera (such as aphids); data from the past from which to calculate trends is largely unavailable; and the data that does exist mostly relates to Western Europe and North America, with the tropics and southern hemisphere (major insect habitats) under-represented.[6][64]

The methodology and strong language of the review were questioned.[62][63][65] Other criticism included that the authors attributed the decline to particular threats based on the studies they reviewed, even when those studies had simply suggested threats rather than clearly identifying them.[63] Some reviewers said the study might underestimate the rate of insect decline in the tropics.[61] Some reviewers also had concerns about the review's search terms, geographic biases, calculations of extinction rates, and inaccurate assessment of drivers of population change. Nevertheless, they found that while it was "a useful review of insect population declines in North America and Europe, it should not be used as evidence of global insect population trends and threats."[63]

In a 2020 paper that studied insects and other arthropods across all Long-term Ecological Research (LTER) sites in the U.S., the authors found some declines, some increases, but generally few consistent losses in arthropod abundance or diversity. This study found some variation in location, but generally stable numbers of insects. As noted in the paper, the authors did not do any a priori selection of arthropod taxa. Instead, they tested the hypothesis that if the arthropod decline was pervasive, it would be detected in monitoring programs not originally designed to look for declines. They suggest that overall numbers of insects vary but overall show no net change.[66] However, the methodology of the article was criticised because it failed to account for changes in sampling location and sampling effort at LTER sites and for the impact of experimental conditions, had inconsistencies in the database constitution and relied on an inadequate statistical analysis.[67][68]

Файл:Windshield phenomenon, Australia, March 2009 (2).jpg
Bug splats, New South Wales, 2009

The windshield phenomenon – car windscreens covered in dead insects after even a short drive through a rural area in Europe and North America – seems also largely to have disappeared; in the 21st century, drivers find they can go an entire summer without noticing it.[10][43] John Rawlins, head of invertebrate zoology at the Carnegie Museum of Natural History, speculated in 2006 that more aerodynamic car designs could explain the change.[69] Entomologist Martin Sorg told Science in 2017: "I drive a Land Rover, with the aerodynamics of a refrigerator, and these days it stays clean."[10] Rawlins added that land next to high-speed highways has become more manicured and therefore less attractive to insects.[69]

Impacts

Файл:00 1680 Bumblebee.gif
Bumblebee collecting pollen

Insect population decline affects ecosystems, and other animal populations, including humans. Insects are at "the structural and functional base of many of the world's ecosystems."[6] A 2019 global review warned that, if not mitigated by decisive action, the decline would have a catastrophic impact on the planet's ecosystems.[6] Birds and larger mammals that eat insects can be directly affected by the decline. Declining insect populations can reduce the ecosystem services provided by beneficial bugs, such as pollination of agricultural crops, and biological waste disposal.[36]

According to the Zoological Society of London, in addition to such loss of instrumental value, the decline also represents a loss of the declining species' intrinsic value.[22]

Countermeasures

Overall policies and conventions

The most influential factors, that can be counteracted, are habitat loss and degradation, pesticide use, and climate change. Policies at all levels of government across the globe are required to address these in a meaningful way.[70]

Much of the world's efforts to retain biodiversity at national level is reported to the United Nations as part of the Convention on Biological Diversity. Reports typically describe policies to prevent the loss of diversity generally, such as habitat preservation, rather than specifying measures to protect particular taxa. Pollinators are the main exception to this, with several countries reporting efforts to reduce the decline of their pollinating insects.[19]

Following the 2017 Krefeld and other studies, Germany's environment ministry, the BMU, started an Action Programme for Insect Protection (Aktionsprogramm Insektenschutz).[19] Their goals include promoting insect habitats in the agricultural landscape, and reducing pesticide use, light pollution, and pollutants in soil and water.[20]

Reduction of pesticide-use

Beyond halting habitat loss and fragmentation and limiting climate change, reducing pesticide use is required for preserving insect populations.[71] Pesticides have been found far from their application source and legislatively mandated elimination of cosmetic pesticide use, as well as general reductions of pesticide use, could greatly benefit insects.[72] Organic food/farming-related measures can be solutions.[70]

However, some scientists warned that excessive focus on reducing pesticide use could be counterproductive as pests already cause a 35 percent yield loss in crops, which can rise to 70 percent if pesticides are not used. If the yield loss was compensated for by expanding agricultural land with deforestation and other habitat destruction, it could exacerbate insect decline.[15]

Wildflower strips and buffer zones

Файл:Mechtenberg2009.jpg
A flowering strip with cornflower dominance between cereal fields as a field trial in Germany

A wildflower strip is a strip of land sown with seeds of biodiverse insect- and pollinator-friendly flowering plant species, usually at the edge of an agricultural field, intended to sustain local biodiversity, conserve insects, restore farmland birds and counteract the negative consequences of agricultural intensification.[73][74][75][76]

Buffer-zones around nature reserves where pesticide-use is drastically reduced has been proposed for inclusion in the countermeasures. Scientists who proposed the measure conducted a Germany-wide field study and found that insect samples in these areas are contaminated with ~16 pesticides on average, proportionate to the agricultural production area in a radius of 2 km.[77]

Wildlife gardens

Шаблон:Further The Entomological Society of America suggests that people maintain plant diversity in their gardens and leave "natural habitat, like leaf litter and dead wood".[28] The Xerces Society in the U.S. has been doing a Western Monarch Thanksgiving Count which includes observations from volunteers for 22 years.[78]

It has been suggested that "Because many insects need little space to survive, even partial conversion of lawns to minimally disturbed natural vegetation—say 10%—could significantly aid insect conservation, while simultaneously lowering the cost of lawn maintenance".[72]

Awareness raising

In the UK, 27 British entomologists and ecologists signed an open letter to The Guardian in March 2019, calling on the British research establishment to investigate the decline. Signatories included Simon Leather, Stuart Reynolds (former president of the Royal Entomological Society), John Krebs and John Lawton (both former presidents of the Natural Environment Research Council), Paul Brakefield, George McGavin, Michael Hassell, Dave Goulson, Richard Harrington (editor of the Royal Entomological Society's magazine, Antenna), Kathy Willis and Jeremy Thomas.[79] The letter requested action "to enable intensive investigation of the real threat of ecological disruption caused by insect declines without delay".[79]

More media coverage has been proposed.[80]

In a 2019 paper, scientists listed 100 studies and other references suggesting that insects can help meet the Sustainable Development Goals (SDG) adopted in 2015 by the United Nations. They argued that the global policy-making community should continue its transition from seeing insects as enemies, to the current view of insects as "providers of ecosystem services", and should advance to a view of insects as "solutions for SDGs" (such as using them as food and biological pest control).[81][82] The public in many countries is largely unaware of benefits and services that insects provide (such as honey, ecosystem balance, food for other animals, pollination, soil health, etc.), and negative perceptions of insects are widespread.[72]

Society and culture

In arts

In April 2019, in response to the studies about insect decline, Carol Ann Duffy released several poems, by herself and others, to mark the end of her tenure as Britain's poet laureate and to coincide with protests that month by the environmentalist movement Extinction Rebellion. The poets included Fiona Benson, Imtiaz Dharker, Matthew Hollis, Michael Longley, Daljit Nagra, Alice Oswald, and Denise Riley. Duffy's contribution was "The Human Bee".[83]

Decline of professionals studying insects

One reason that studies into the decline are limited is that entomology and taxonomy are themselves in decline.[84][85][86] At the 2019 Entomology Congress, leading entomologist Jürgen Gross said that "We are ourselves an endangered species" while Wolfgang Wägele – an expert in systematic zoology – said that "in the universities we have lost nearly all experts".[87] In 2016, Jürgen Deckert of Berlin Natural History Museum commented that while around 30,000 insect species are known to inhabit Central Europe, there are "only a few specialists" dedicated to the region, and even they often do monitoring as a side job.[5] General biology courses in college give less attention to insects, and the number of biologists specialising in entomology is decreasing as specialities such as genetics expand.[88][89][90] In addition, studies investigating the decline tend to be done by collecting insects and killing them in traps, which poses an ethical problem for conservationists.[91][92]

Further, the above describes the situation in the developed countries: the developing countries have typically not had time to build up their entomology in the first place. Consequently, nearly all of the major insect studies to date are from Europe and the United States, even though it's estimated that fewer than 20% of insect species worldwide are in those countries.[18]

See also

References

Шаблон:Reflist

Шаблон:Human impact on the environment Шаблон:Insects in culture Шаблон:Insecticides Шаблон:Pesticides Шаблон:Doomsday Шаблон:Extinction

  1. 1,0 1,1 1,2 1,3 Ошибка цитирования Неверный тег <ref>; для сносок Hallmann2017PLoS не указан текст
  2. Шаблон:Cite book In: Шаблон:Cite book
  3. Шаблон:Cite journal
  4. 4,0 4,1 4,2 4,3 4,4 4,5 4,6 Ошибка цитирования Неверный тег <ref>; для сносок Leather2017 не указан текст
  5. 5,0 5,1 5,2 5,3 Ошибка цитирования Неверный тег <ref>; для сносок SchwägerlYale2016 не указан текст
  6. 6,00 6,01 6,02 6,03 6,04 6,05 6,06 6,07 6,08 6,09 6,10 6,11 6,12 6,13 6,14 6,15 Ошибка цитирования Неверный тег <ref>; для сносок Sánchez-Bayo2019 не указан текст
  7. 7,0 7,1 Ошибка цитирования Неверный тег <ref>; для сносок OwensLewis2018 не указан текст
  8. 8,0 8,1 Light pollution is key 'bringer of insect apocalypse' The Guardian, 2019
  9. 9,0 9,1 Шаблон:Cite journal
  10. 10,0 10,1 10,2 10,3 10,4 Ошибка цитирования Неверный тег <ref>; для сносок Vogel2017 не указан текст
  11. 11,0 11,1 Ошибка цитирования Неверный тег <ref>; для сносок IPBES не указан текст
  12. 12,0 12,1 12,2 12,3 12,4 12,5 Ошибка цитирования Неверный тег <ref>; для сносок vanKlink2020 не указан текст
  13. 13,0 13,1 13,2 Шаблон:Cite journal
  14. Шаблон:Cite journal
  15. 15,0 15,1 15,2 15,3 Ошибка цитирования Неверный тег <ref>; для сносок Thomas2019 не указан текст
  16. 16,0 16,1 Шаблон:Cite journal
  17. 17,0 17,1 Шаблон:Cite journal
  18. 18,0 18,1 Шаблон:Cite journal
  19. 19,0 19,1 19,2 Ошибка цитирования Неверный тег <ref>; для сносок FAO2019 не указан текст
  20. 20,0 20,1 20,2 Ошибка цитирования Неверный тег <ref>; для сносок BMU не указан текст
  21. Ошибка цитирования Неверный тег <ref>; для сносок fossil не указан текст
  22. 22,0 22,1 22,2 Ошибка цитирования Неверный тег <ref>; для сносок ZSL не указан текст
  23. Ошибка цитирования Неверный тег <ref>; для сносок BorrellSA4Sept2012 не указан текст
  24. 24,0 24,1 Ошибка цитирования Неверный тег <ref>; для сносок NYTeditorial29Oct2017 не указан текст
  25. 25,0 25,1 Ошибка цитирования Неверный тег <ref>; для сносок JarvisNYT27Nov2018 не указан текст
  26. 26,0 26,1 Ошибка цитирования Неверный тег <ref>; для сносок DCGuardian18Oct2017 не указан текст
  27. 27,0 27,1 Ошибка цитирования Неверный тег <ref>; для сносок Reckhaus2017 не указан текст
  28. 28,0 28,1 28,2 Ошибка цитирования Неверный тег <ref>; для сносок FAQEntSocAm2019 не указан текст
  29. Шаблон:Cite journal
  30. Ошибка цитирования Неверный тег <ref>; для сносок Hance2019 не указан текст
  31. Шаблон:Cite journal
  32. Шаблон:Cite journal
  33. Шаблон:Cite journal
  34. Ошибка цитирования Неверный тег <ref>; для сносок Wagner2010 не указан текст
  35. Шаблон:Cite journal
  36. 36,0 36,1 36,2 Ошибка цитирования Неверный тег <ref>; для сносок MainNatGeographic14Feb2019 не указан текст
  37. 37,0 37,1 Ошибка цитирования Неверный тег <ref>; для сносок WagnerJ2020 не указан текст
  38. 38,0 38,1 Ошибка цитирования Неверный тег <ref>; для сносок Dirzo2014 не указан текст
  39. Ошибка цитирования Неверный тег <ref>; для сносок Baranov2020 не указан текст
  40. Шаблон:Cite web
  41. Ошибка цитирования Неверный тег <ref>; для сносок McKieObserver17June2018 не указан текст
  42. Ошибка цитирования Неверный тег <ref>; для сносок McCarthyGuardian21Oct2017 не указан текст
  43. 43,0 43,1 Ошибка цитирования Неверный тег <ref>; для сносок KnaptonTelegraph17June2018 не указан текст
  44. Ошибка цитирования Неверный тег <ref>; для сносок BBC04 не указан текст
  45. Ошибка цитирования Неверный тег <ref>; для сносок Sorg2013 не указан текст
  46. Шаблон:Cite web
  47. Ошибка цитирования Неверный тег <ref>; для сносок Nature18Oct2017 не указан текст
  48. Ошибка цитирования Неверный тег <ref>; для сносок Guarino18Oct2017 не указан текст
  49. Ошибка цитирования Неверный тег <ref>; для сносок StagerNYT26May2018 не указан текст
  50. 50,0 50,1 Ошибка цитирования Неверный тег <ref>; для сносок Economist23March2019 не указан текст
  51. Ошибка цитирования Неверный тег <ref>; для сносок McGraneNYT4Dec2017 не указан текст
  52. 52,0 52,1 Ошибка цитирования Неверный тег <ref>; для сносок Lister2018 не указан текст
  53. Ошибка цитирования Неверный тег <ref>; для сносок Guarino15Oct2018 не указан текст
  54. Ошибка цитирования Неверный тег <ref>; для сносок vanStrien2019 не указан текст
  55. Шаблон:Cite web
  56. Шаблон:Cite news
  57. Ошибка цитирования Неверный тег <ref>; для сносок Barkham2019 не указан текст
  58. Ошибка цитирования Неверный тег <ref>; для сносок SWI не указан текст
  59. Ошибка цитирования Неверный тег <ref>; для сносок SANS не указан текст
  60. "Fig. 1. Geographic location of the 73 reports studied on the world map", Sánchez-Bayo and Wyckhuys 2019.
  61. 61,0 61,1 Ошибка цитирования Неверный тег <ref>; для сносок LePageNewScientist11Feb2019 не указан текст
  62. 62,0 62,1 Ошибка цитирования Неверный тег <ref>; для сносок Wagner2019 не указан текст
  63. 63,0 63,1 63,2 63,3 Ошибка цитирования Неверный тег <ref>; для сносок Simmons2019 не указан текст
  64. Ошибка цитирования Неверный тег <ref>; для сносок DCObserver10Feb2019 не указан текст
  65. Ошибка цитирования Неверный тег <ref>; для сносок Sanders16Feb2019 не указан текст
  66. Шаблон:Cite journal
  67. Welti, E.A.R., Joern, A., Ellison, A.M. et al. Studies of insect temporal trends must account for the complex sampling histories inherent to many long-term monitoring efforts. Nature Ecology and Evolution 5 589–591 (2021). Шаблон:Doi
  68. Шаблон:Cite journal
  69. 69,0 69,1 Ошибка цитирования Неверный тег <ref>; для сносок LinnPost-Gazette4June2006 не указан текст
  70. 70,0 70,1 Шаблон:Cite journal
  71. Шаблон:Cite journal
  72. 72,0 72,1 72,2 Шаблон:Cite journal
  73. Шаблон:Cite journal
  74. Шаблон:Cite journal
  75. Шаблон:Cite journal
  76. Шаблон:Cite journal
  77. Шаблон:Cite journal
  78. Шаблон:Cite web
  79. 79,0 79,1 Ошибка цитирования Неверный тег <ref>; для сносок Leather2019 не указан текст
  80. Шаблон:Cite journal
  81. Ошибка цитирования Неверный тег <ref>; для сносок Dangles2019 не указан текст
  82. Шаблон:Cite web
  83. Ошибка цитирования Неверный тег <ref>; для сносок Duffy27April2019 не указан текст
  84. Ошибка цитирования Неверный тег <ref>; для сносок Yong2019 не указан текст
  85. Ошибка цитирования Неверный тег <ref>; для сносок Time не указан текст
  86. Ошибка цитирования Неверный тег <ref>; для сносок Wired не указан текст
  87. Ошибка цитирования Неверный тег <ref>; для сносок DW не указан текст
  88. Ошибка цитирования Неверный тег <ref>; для сносок Leather2007 не указан текст
  89. Ошибка цитирования Неверный тег <ref>; для сносок AE не указан текст
  90. Ошибка цитирования Неверный тег <ref>; для сносок PS не указан текст
  91. Ошибка цитирования Неверный тег <ref>; для сносок RSB не указан текст
  92. Ошибка цитирования Неверный тег <ref>; для сносок ICD не указан текст