تنوع زیستی (به انگلیسی: Biodiversity) مفهومی است که امروزه در سه سطح ژن، گونه و اکوسیستم مطرح میگردد، ولی این واژه در سطح گونه شناخته شدهتر بوده و کاربرد بیشتردارد.
امروزه روی کره زمین در حدود دو میلیون گونه موجود زنده شناسایی و نامگذاری شدهاند که دانشمندان حدس میزنند که این رقم تا حدود ده میلیون قابل افزایش باشد. البته بخش عظیم این افزایش متعلق به گروههای بیمهرگان و بخصوص بندپایان میباشد.
سازمان ملل در سال ۱۹۹۲ کنفرانسی را دربارهٔ حمایت از محیط زیست در ریودوژانیرو برگزار کرد که یکی از دستاوردهای آن انعقاد پیمان تنوع زیستی است که ایران هم این معاهده را در سال ۱۳۷۵ تصویب کرد و به آن پیوست.(مرتضی)
تنوع زیستی معمولاً به همهٔ شکلهای زندگی از ژنها تا گونهها گفته میشود. تا اندازهای میتوان گفت که تنوع زیستی عنوانی جدید برای ایدههایی کهن است. امروزه گاهی از تنوع زیستی منظور زندگی یا حیات وحش یا دیگر ارزشهای نگهداری از محیط زیست گفته میشود.
در تعریف تنوع زیستی مشکلی وجود دارد و آن این است که دشوار میتوان چیزی را از این تعریف که تقریباً شامل همه چیز میشود حذف کرد. سارکار استدلال کردهاست که با تفسیر تنوع زیستی در همهٔ سطوح زیست شناختی، از ژنها تا اکوسیستمها، ناگزیر تنوع زیستی همهٔ زیستشناسی را در بر میگیرد. تا کنون چهار سطح تنوع زیستشناختی به وسیلهٔ تنوع زیستی تعریف میشود:
تنوع مولکولی، تنوع گونهای، تنوع اکوسیستم و تنوع ژنتیکی
کالیکات و همکارانش گفتهاند که تنوع زیستی از جمله مفهومهایی است که به درستی تعریف نشدهاست و میان جنبههای ترکیبی و کاربری در نگاه به تنوع زیستی میتوان تمایز گذاشت. نگاه کاربردی بیشتر متوجه اکوسیستم و فرایندهای فرگشتی (تکاملی) است، در حالی که نگاه ترکیبی جانداران را به شکل گردآمده در جمعیتها، گونهها و ردهها و دستهبندیهای بالاتر میبیند.
در سال ۱۹۹۲، همایش زمین سازمان ملل تنوع زیستی را اینگونه تعریف کرد: «تنوع میان جانداران از همهٔ منابع، دربرگیرندهٔ میان چیزهای دیگر، زمینی، دریایی و دیگر اکوسیستمهای آبی و پیچیدههای اکولوژیکی که بخشی از آن هستند؛ این شامل تنوع میان گونهها، میان گونهها و اکوسیستم میشود.»
یک تعریف بر پایهٔ کتابهای درسی اینگونه است:« تنوع زندگی در همهٔ سطحهای طبقهبندی زیستشناختی.»
ژنتیکدانها آن را به شکل تنوع ژنها و جانداران تعریف میکنند. آنها فرایندهایی همچون جهش، انتقال ژنی، تحرک ژنومی را که به فرگشت میانجامند، مطالعه میکنند.
اندازهگیری تنوع زیستی در یک سطح، ممکن است دقیقاً برابر با تنوع در سطحی دیگر نباشد. ولی تنوع تتراپاد، تاکسونومیک و اکولوژیکی نسبت بسیار نزدیکی را نشان میدهند.
معمولترین کاربرد تنوع زیستی جابجایی برای عبارتکهنتر و تعریف شدهتر تنوع گونهها است. تنوع زیستی نوعی میزان برای سنجش سلامت اکوسیستمها است، ولی خود تابعی از آبو هوا است. از زمین، تنوع زیستی در منطقههای استوایی بیشینه و در قطبها کمینه است. تغییرهای تند محیطی اغلب به انقراضهای گروهی میانجامد. بر پایهٔ یک برآورد، تنها ۱٪ گونههایی که در زمین میزیستهاند اکنون وجود دارند.
نخستین بار واژهٔ تنوع زیستی به وسیلهٔ ریموند داسمن در ۱۹۶۸ در کتاب نوع دیگری از زندگی در دفاع از محیط زیست به کار برده شد. پس از آن و به فاصلهٔ یک دهه این واژه بسیار پذیرفته شد تا جایی که در دههٔ ۱۹۸۰ به کاربرد عادی در علم و سیاست محیطی وارد شد.
تنوع زیستی خدماتی که اکوسیستمها دارند را پشتیبانی میکند. خدماتی همچون: کیفیت هوا، آب و هوا (نمونه:تجزیهٔ دیاکسید کربن)، تصفیهٔ آب، گرده افشانی، و جلوگیری از فرسایش.
از زمان دوران سنگی، از میان رفتن گونهها، به وسیلهٔ انسان، شدت گرفتهاست. برآورد میشود که از میان رفتن گونهها صد تا ده هزار برابر آن چیزی است که شواهد برای شواهد فسیلی معمول است.
از فایدههای غیر مادی تنوع زیستی میتوان به ارزشهای روحانی و زیباییشناختی، و ارزش آموزش اشاره کرد.
تنوع غلات به بازیابی آنها پس از حمله به یک گونهٔ مورد کشت به وسیلهٔ آفتها یا بیماری کمک میکند:
آفت سیبزمینی ایرلندی در ۱۸۴۶ عامل مرگ یک میلیون نفر و مهاجرت یک میلیون دیگر شد. این فاجعه به دلیل کاشت تنها دو نوع سیب زمینی بود که هر دوی آنها هم به آفت حساس بودند.
زمانی که ویروس جلوگیریکننده از رشد برنج در دههٔ ۱۹۷۰به مزرعههای اندونزی تا هند حمله برد، ۶۲۳۷ نوع گوناگون برای بررسی مقاومت تست شدند. و تنها یکی از آنها که هندی و شناخته شده برای علم از سال ۱۹۶۶ بود، مقاومت داشت. این نوع با دیگر انواع هیبرید تشکیل داد اکنون به شکل گسترده کشت میشود.
زنگ قهوه در سال ۱۹۷۰ به مزرعههای قوه در سریلانکا، برزیل و آمریکای مرکزی حمله برد. یک نوع مقاوم در اتیوپی پیدا شد. هرچند که بیماریها نیز خود بخشی از تنوع زیستی هستند.
تک کشتی، یکی از عواملی بودهاست که به فاجعههای کشاورزی انجامیده است. هر چند که تقریباً ۸۰ درصد غذای انسانی از ۲۰ نوع گیاه به دست میآید، ولی انسانها دست کم ۴۰۰۰۰ گونه را به کار میبرند.
اثر تنوع زیستی بر تندرستی انسان در حال تبدیل شده به موضوعی سیاسی در سطح بینالمللی است، از آنجا که شواهد علمی تأثیر کم شدن تنوع زیستی بر تندرستی در سطح جهانی را نشان میدهند. این موضوع با گرمایش آبو هوایی پیوندی نزدیک دارد، از آنجا که بسیاری از تأثیرهای پیشبینی شدهٔ تغییر آبوهوا با تغییر در تنوع زیستی در ارتباط هستند (برای نمونه تغییر در جمعیتها و پخش بردارهای بیماری، کمیابی آب شیرین، تأثیر بر تنوع زیستی کشاورزی و منابع غذایی و غیره). دلیل آن این است که گونههایی که بیشتر احتمال از میان رفتنشان هست، آنهایی هستند که در برابر انتقال بیماری سد ایجاد میکنند در حالی که گونههایی که زنده میمانند آنهایی هستند که انتقال بیماری را افزایش میدهند، همان ویروس باختر نیل و هانتاویروس.
برخی از مشکلات تندرستی که از تحت تأثیر تنوع زیستی است دربرگیرندهٔ تندرستی رژیمی و امنیت تغذیه، بیماریهای عفونی، علوم و منابع پزشکی و سلامت روانی و اجتماعی. همچین تنوع زیستی اثری بزرگ بر کاهش خطر فاجعه و بازیابی پس از فاجعه دارد.
تنوع زیستی پشتیبانی مهم برای کشف دارو و در دسترس بودن منابع پزشکی است. بخش قابل توجهی از داروها، مستقیم یا غیرمستقیم، از منبعهای زیستشناختی به دست آمدهاند: دست کم ٪۵۰ ترکیبهای داروسازی در آمریکا از گیاهان، جانوران و میکروارگانیسمها به دست آمدهاند، در حالی که ٪۸۰ جمعیت دنیا، برای نگهداری پزشکی نخستین خود، وابسته به داروهای طبیعی هستند (در پزشکی سنتی یا مدرن). تنها بخش کوچکی از گونههای وحشی برای کاربرد پزشکی بررسی شدهاند. شواهدی از تحلیل بازار و علم تنوع زیستی نشان میدهند که کاهش برونده بخش داروسازی از میانههای دههٔ ۱۹۸۰ میتواند مربوط به دوری گزیدن از جستجو در فراوردههای طبیعی به نفع ژنومیک و شیمی سنتزی باشد، در حالی که فراوردههای طبیعی تاریخی دراز در پشتیبانی از نوآوریهای پزشکی و اقتصادی دارند. اکوسیستمهای دریایی به ویژه اهمیت دارند.
بسیاری از مواد صنعتی مسقیم از منبعهای زیستشناختی به دست میآیند. اینها دربرگیرندهٔ مواد ساختمانی، فیبرها، رنگها، لاستیک و روغن میشوند. تنوع زیستی همچنین برای امنیت منابعی مانند آب، الوار، کاغذ، فیبر و غذا مهم است. در نتیجه از دست رفتن تنوع زیستی عامل خطر مهمی در رشد تجاری و تهدیدی برای ثبات بلندمدت اقتصادی است.
بیشتر اکولوژیستها دو جنبه از تنوع زیستی را برای اندازهگیری آن در نظر میگیرند: یکی فراوانی گونهها، یعنی تعداد گونهها در یک اجتماع، و دیگری فراوانی نسبی است که یکنواختی پخش شدن افراد در میان گونههای یک اجتماع است.
این اندازهگیری تنها شمارش تعداد گونههای پیدا شده در زمانی که مشاهدهکننده از اجتماع نمونه میگیرد میباشد. آن را با S نشان میدهند. تنها پیچیدگی در این اندازهگیری این است که این تعداد تا حدی بستگی به اندازهٔ نمونهای دارد که مشاهدهکننده برمیگزیند. زمانیکه نمونهبرداری میکنید، افراد را یکی یکی و به شکل تصادفی برمیگزینید، و گونهٔ هر فرد را ثبت میکنید. در آغاز گونههای جدید را به شکل معمول میگیرید، ولی پس از گذشت زمان افراد بیشتری از گونههای پیشین خواهند بود. شاید هیچگاه یافتن گونههای جدید پایان نیابد، ولی هر چه بیشتر کمیاب میشوند. با افزایش تعداد افراد مورد آزمایش، فراوانی گونهها افزایش مییابد: در آغاز تند و سپس کندتر.
زمانی که این رخداد پیش میآید، باید تصمیم گرفت که چه تعداد از افراد را قرار است بشماریم تا بگوییم S را برآورد کردهایم. تکنیکهایی وجود دارند که با کاربرد شکل این منحنی عددی را که در نهایت ثابت میشود را برآورد میکند. یا اینکه میتوان تصمیم گرفت که S را زمانی در نظر بگیریم که تعداد گونههای جدید کمتر از حد مشخصی (برای نمونه ٪۱) از افرادی شود که میشماریم.
اندازهگیری فراوانی گونهها اطلاعات مفیدی را به دست میدهد. این مزیت را دارد که به راحتی به نمودار تبدیل میشود و فهم آن ساده است و به آسانی میتوان آن را به مخاطب عمومی توضیح داد. اغلب این تنها نوع از تنوع زیستی است که میتوان به دست آورد، مگر اینکه خود به بیرون رفته و کار محیطی انجام دهید. و در بسیاری از موقعیتها، فراوانی گونهها برای انجام مقایسهها، به ویژه میان زیستگاههای جغرافیایی، بسنده است.
با این همه، شمارهٔ فراوانی گونهها (S) میتواند گمراهکننده باشد. دو اجتماع را در نظر بگیرید، هر دو با یک تعداد گونه، ولی در یکی از آنها یک گونهٔ معمول و افراد کمی از دیگر گونهها وجود دارد، در حالی که در اجتماع دیگر شمارهٔ برابری از هر گونه وجود دارد. به شکل ناخودآگاه ما اجتماعی راکه افراد به شکل یکنواختی در میان گونههای دیگر پخش شدهاند را متنوعتر از اجتماعی که تقریباً همهٔ افرادش متعلق به یک گونه هستند در نظر میگیریم. برای وارد کردن این موضوع در شمارش خود، نیاز داریم که فراوانی نسبی را در نظر بگیریم.
میدانیم که در بیشتر اجتماعها، برخی گونهها معمولتر از دیگر گونهها هستند و برخی نیز کمیابند. ولی شدت این پدیده از اجتماع به اجتماع و از موقعیتی به موقعیت دیگر متفاوت است. فرمولهای ریاضی برای اندازهگیری یکنواختی پخش افراد در میان گونهها وجود دارد و این گونهها در برخی موارد مفید نیز هستند. ولی به خودی خود این مشکل را دارند که تنها یکنواختی را اندازه میگیریند و اطلاعات مهم دربارهٔ فراوانی گونهها را از دست میدهند.
چیزی که بیش از همه کاربردی است ترکیبی از فراوانی گونهها و یکنواختی آنها است.
یک اندازهگیری که بومشناسان برای این منظور به کار میبرند شاخص شانون-واینر یا اطلاعات است. این شاخص یک فرمول ریاضی است که از نظریهٔ اطلاعات گرفته شدهاست که به وسیلهٔ مهندسان برای تحیلی بازدهی انتقال داده در خطهای تلفن توسعه یافتهاست.
این شاخص، H، با فرمول زیر به دست میآید:
H=-Sigma Pi ln Pi
هر چند که پیچیده به نظر میرسد، معنی آن این است که برای هر گونه نسبت (p) آن به کل را تعیین میکنید و سپس آن شماره را در لوگاریتم طبیعی آن عدد (ln) و خود آن عدد ضرب میکنیم. تا اینجا p ln p به دست میآید. این کار را برای هر گونه در اجتماع انجام میدهیم و سپس همهٔ شمارههای به دست آمده را جمع میکنیم. از آنجا که این شماره منفی خواهد شد، برای آسانی کار آن را مثبت میکنیم.
شاخص اطلاعات هم یکنواختی پخش گونهها و هم تعداد مطلق آنها را به حساب میآورد. برای بسیاری از مطالعهها این اندازهٔ بهتری برای کاربرد است. ولی به هر روی، درک آن چندان ذاتی نیست و ممکن است در هنگام توضیح تنوع برای مخاطب عام، به کاربردی شاخص فراوانی گونهها S نباشد.
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↑ ۱۰٫۰۱۰٫۱Hassan, Rashid M.; Robert Scholes, Neville Ash (2006). Ecosystems and human well-being: current state and trends : findings of the Condition and Trends Working Group of the Millennium Ecosystem Assessment. Island Press. p. 105. ISBN1-55963-228-3, 9781559632287.
↑Wahl, GM; Robert de Saint Vincent B; Derose, ML (1984). "Effect of chromosomal position on amplification of transfected genes in animal cells". Nature 307 (5951): 516–20. Bibcode 1984Natur.307..516W. doi:10.1038/307516a0. PMID 6694743.
A sampling of fungi collected during summer 2008 in Northern Saskatchewan mixed woods, near LaRonge, is an example regarding the species diversity of fungi. In this photo, there are also leaf lichens and mosses.
Rapid environmental changes typically cause mass extinctions. More than 99.9 percent of all species that ever lived on Earth, amounting to over five billion species, are estimated to be extinct. Estimates on the number of Earth's current species range from 10 million to 14 million, of which about 1.2 million have been documented and over 86 percent have not yet been described. More recently, in May 2016, scientists reported that 1 trillion species are estimated to be on Earth currently with only one-thousandth of one percent described. The total amount of related DNAbase pairs on Earth is estimated at 5.0 x 1037 and weighs 50 billion tonnes. In comparison, the total mass of the biosphere has been estimated to be as much as 4 TtC (trillion tons of carbon). In July 2016, scientists reported identifying a set of 355 genes from the Last Universal Common Ancestor (LUCA) of all organisms living on Earth.
1916 – The term biological diversity was used first by J. Arthur Harris in "The Variable Desert," Scientific American, JSTOR6182: "The bare statement that the region contains a flora rich in genera and species and of diverse geographic origin or affinity is entirely inadequate as a description of its real biological diversity."
1975 – The term natural diversity was introduced (by The Science Division of The Nature Conservancy in a 1975 study, "The Preservation of Natural Diversity.")
1980 – Thomas Lovejoy introduced the term biological diversity to the scientific community in a book. It rapidly became commonly used.
1985 – According to Edward O. Wilson, the contracted form biodiversity was coined by W. G. Rosen: "The National Forum on BioDiversity ... was conceived by Walter G.Rosen ... Dr. Rosen represented the NRC/NAS throughout the planning stages of the project. Furthermore, he introduced the term biodiversity".
1985 - The term "biodiversity" appears in the article, "A New Plan to Conserve the Earth's Biota" by Laura Tangley.
1988 - The term biodiversity first appeared in a publication.
The present - the term has achieved widespread use.
Biologists most often define biodiversity as the "totality of genes, species and ecosystems of a region". An advantage of this definition is that it seems to describe most circumstances and presents a unified view of the traditional types of biological variety previously identified:
taxonomic diversity (usually measured at the species diversity level)
functional diversity (which is a measure of the number of functionally disparate species within a population (e.g. different feeding mechanism, different motility, predator vs prey, etc.)) This multilevel construct is consistent with Datman and Lovejoy.
An explicit definition consistent with this interpretation was first given in a paper by Bruce A. Wilcox commissioned by the International Union for the Conservation of Nature and Natural Resources (IUCN) for the 1982 World National Parks Conference. Wilcox's definition was "Biological diversity is the variety of life forms...at all levels of biological systems (i.e., molecular, organismic, population, species and ecosystem)...".
Genetic: Wilcox 1984
Biodiversity can be defined genetically as the diversity of alleles, genes and organisms. They study processes such as mutation and gene transfer that drive evolution.
Terrestrial biodiversity is thought to be up to 25 times greater than ocean biodiversity. A new method used in 2011, put the total number of species on Earth at 8.7 million, of which 2.1 million were estimated to live in the ocean. However, this estimate seems to under-represent the diversity of microorganisms.
Generally, there is an increase in biodiversity from the poles to the tropics. Thus localities at lower latitudes have more species than localities at higher latitudes. This is often referred to as the latitudinal gradient in species diversity. Several ecological factors may contribute to the gradient, but the ultimate factor behind many of them is the greater mean temperature at the equator compared to that of the poles.
Even though terrestrial biodiversity declines from the equator to the poles, some studies claim that this characteristic is unverified in aquatic ecosystems, especially in marine ecosystems. The latitudinal distribution of parasites does not appear to follow this rule.
In 2016, an alternative hypothesis ("the fractal biodiversity") was proposed to explain the biodiversity latitudinal gradient. In this study, the species pool size and the fractal nature of ecosystems were combined to clarify some general patterns of this gradient. This hypothesis considers temperature, moisture, and net primary production (NPP) as the main variables of an ecosystem niche and as the axis of the ecological hypervolume. In this way, it is possible to build fractal hypervolumes, whose fractal dimension rises to three moving towards the equator.
Brazil's Atlantic Forest is considered one such hotspot, containing roughly 20,000 plant species, 1,350 vertebrates and millions of insects, about half of which occur nowhere else. The island of Madagascar and India are also particularly notable. Colombia is characterized by high biodiversity, with the highest rate of species by area unit worldwide and it has the largest number of endemics (species that are not found naturally anywhere else) of any country. About 10% of the species of the Earth can be found in Colombia, including over 1,900 species of bird, more than in Europe and North America combined, Colombia has 10% of the world's mammals species, 14% of the amphibian species and 18% of the bird species of the world.Madagascar dry deciduous forests and lowland rainforests possess a high ratio of endemism. Since the island separated from mainland Africa 66 million years ago, many species and ecosystems have evolved independently.Indonesia's 17,000 islands cover 735,355 square miles (1,904,560 km2) and contain 10% of the world's flowering plants, 12% of mammals and 17% of reptiles, amphibians and birds—along with nearly 240 million people. Many regions of high biodiversity and/or endemism arise from specialized habitats which require unusual adaptations, for example, alpine environments in high mountains, or Northern European peat bogs.
Accurately measuring differences in biodiversity can be difficult. Selection bias amongst researchers may contribute to biased empirical research for modern estimates of biodiversity. In 1768, Rev. Gilbert White succinctly observed of his Selborne, Hampshire"all nature is so full, that that district produces the most variety which is the most examined."
The history of biodiversity during the Phanerozoic (the last 540 million years), starts with rapid growth during the Cambrian explosion—a period during which nearly every phylum of multicellular organisms first appeared. Over the next 400 million years or so, invertebrate diversity showed little overall trend and vertebrate diversity shows an overall exponential trend. This dramatic rise in diversity was marked by periodic, massive losses of diversity classified as mass extinction events. A significant loss occurred when rainforests collapsed in the carboniferous. The worst was the Permian-Triassic extinction event, 251 million years ago. Vertebrates took 30 million years to recover from this event.
The fossil record suggests that the last few million years featured the greatest biodiversity in history. However, not all scientists support this view, since there is uncertainty as to how strongly the fossil record is biased by the greater availability and preservation of recent geologic sections. Some scientists believe that corrected for sampling artifacts, modern biodiversity may not be much different from biodiversity 300 million years ago., whereas others consider the fossil record reasonably reflective of the diversification of life. Estimates of the present global macroscopic species diversity vary from 2 million to 100 million, with a best estimate of somewhere near 9 million, the vast majority arthropods. Diversity appears to increase continually in the absence of natural selection.
The existence of a global carrying capacity, limiting the amount of life that can live at once, is debated, as is the question of whether such a limit would also cap the number of species. While records of life in the sea show a logistic pattern of growth, life on land (insects, plants and tetrapods) shows an exponential rise in diversity. As one author states, "Tetrapods have not yet invaded 64 percent of potentially habitable modes and it could be that without human influence the ecological and taxonomic diversity of tetrapods would continue to increase exponentially until most or all of the available eco-space is filled."
It also appears that the diversity continues to increase over time, especially after mass extinctions.
On the other hand, changes through the Phanerozoic correlate much better with the hyperbolic model (widely used in population biology, demography and macrosociology, as well as fossil biodiversity) than with exponential and logistic models. The latter models imply that changes in diversity are guided by a first-order positive feedback (more ancestors, more descendants) and/or a negative feedback arising from resource limitation. Hyperbolic model implies a second-order positive feedback. The hyperbolic pattern of the world population growth arises from a second-order positive feedback between the population size and the rate of technological growth. The hyperbolic character of biodiversity growth can be similarly accounted for by a feedback between diversity and community structure complexity. The similarity between the curves of biodiversity and human population probably comes from the fact that both are derived from the interference of the hyperbolic trend with cyclical and stochastic dynamics.
Most biologists agree however that the period since human emergence is part of a new mass extinction, named the Holocene extinction event, caused primarily by the impact humans are having on the environment. It has been argued that the present rate of extinction is sufficient to eliminate most species on the planet Earth within 100 years.
In 2011, in his Biodiversity-related Niches Differentiation Theory, Roberto Cazzolla Gatti proposed that species themselves are the architects of biodiversity, by proportionally increasing the number of potentially available niches in a given ecosystem. This study led to the idea that biodiversity is autocatalytic. An ecosystem of interdependent species can be, therefore, considered as an emergentautocatalytic set (a self-sustaining network of mutually "catalytic" entities), where one (group of) species enables the existence of (i.e., creates niches for) other species. This view offers a possible answer to the fundamental question of why so many species can coexist in the same ecosystem.
New species are regularly discovered (on average between 5–10,000 new species each year, most of them insects) and many, though discovered, are not yet classified (estimates are that nearly 90% of all arthropods are not yet classified). Most of the terrestrial diversity is found in tropical forests and in general, the land has more species than the ocean; some 8.7 million species may exist on Earth, of which some 2.1 million live in the ocean.
"Ecosystem services are the suite of benefits that ecosystems provide to humanity." The natural species, or biota, are the caretakers of all ecosystems. It is as if the natural world is an enormous bank account of capital assets capable of paying life sustaining dividends indefinitely, but only if the capital is maintained.
These services come in three flavors:
Provisioning services which involve the production of renewable resources (e.g.: food, wood, fresh water)
Regulating services which are those that lessen environmental change (e.g.: climate regulation, pest/disease control)
Cultural services represent human value and enjoyment (e.g.: landscape aesthetics, cultural heritage, outdoor recreation and spiritual significance)
There have been many claims about biodiversity's effect on these ecosystem services, especially provisioning and regulating services. After an exhaustive survey through peer-reviewed literature to evaluate 36 different claims about biodiversity's effect on ecosystem services, 14 of those claims have been validated, 6 demonstrate mixed support or are unsupported, 3 are incorrect and 13 lack enough evidence to draw definitive conclusions.
Greater species diversity
of plants increases fodder yield (synthesis of 271 experimental studies).
of plants (i.e. diversity within a single species) increases overall crop yield (synthesis of 575 experimental studies). Although another review of 100 experimental studies reports mixed evidence.
of trees increases overall wood production (Synthesis of 53 experimental studies). However, there is not enough data to draw a conclusion about the effect of tree trait diversity on wood production.
Greater species diversity
of fish increases the stability of fisheries yield (Synthesis of 8 observational studies)
of natural pest enemies decreases herbivorous pest populations (Data from two separate reviews; Synthesis of 266 experimental and observational studies; Synthesis of 18 observational studies. Although another review of 38 experimental studies found mixed support for this claim, suggesting that in cases where mutual intraguild predation occurs, a single predatory species is often more effective
of plants decreases disease prevalence on plants (Synthesis of 107 experimental studies)
of plants increases resistance to plant invasion (Data from two separate reviews; Synthesis of 105 experimental studies; Synthesis of 15 experimental studies)
of plants increases carbon sequestration, but note that this finding only relates to actual uptake of carbon dioxide and not long term storage, see below; Synthesis of 479 experimental studies)
of plants increases soil organic matter (Synthesis of 85 experimental studies)
Services with mixed evidence
None to date
Greater species diversity of plants may or may not decrease herbivorous pest populations. Data from two separate reviews suggest that greater diversity decreases pest populations (Synthesis of 40 observational studies; Synthesis of 100 experimental studies). One review found mixed evidence (Synthesis of 287 experimental studies), while another found contrary evidence (Synthesis of 100 experimental studies)
Greater species diversity of animals may or may not decrease disease prevalence on those animals (Synthesis of 45 experimental and observational studies), although a 2013 study offers more support showing that biodiversity may in fact enhance disease resistance within animal communities, at least in amphibian frog ponds. Many more studies must be published in support of diversity to sway the balance of evidence will be such that we can draw a general rule on this service.
Greater species and trait diversity of plants may or may not increase long term carbon storage (Synthesis of 33 observational studies)
Greater pollinator diversity may or may not increase pollination (Synthesis of 7 observational studies), but a publication from March 2013 suggests that increased native pollinator diversity enhances pollen deposition (although not necessarily fruit set as the authors would have you believe, for details explore their lengthy supplementary material).
Greater species diversity of plants reduces primary production (Synthesis of 7 experimental studies)
greater genetic and species diversity of a number of organisms reduces freshwater purification (Synthesis of 8 experimental studies, although an attempt by the authors to investigate the effect of detritivore diversity on freshwater purification was unsuccessful due to a lack of available evidence (only 1 observational study was found
Effect of species diversity of plants on biofuel yield (In a survey of the literature, the investigators only found 3 studies)
Effect of species diversity of fish on fishery yield (In a survey of the literature, the investigators only found 4 experimental studies and 1 observational study)
Effect of species diversity on the stability of biofuel yield (In a survey of the literature, the investigators did not find any studies)
Effect of species diversity of plants on the stability of fodder yield (In a survey of the literature, the investigators only found 2 studies)
Effect of species diversity of plants on the stability of crop yield (In a survey of the literature, the investigators only found 1 study)
Effect of genetic diversity of plants on the stability of crop yield (In a survey of the literature, the investigators only found 2 studies)
Effect of diversity on the stability of wood production (In a survey of the literature, the investigators could not find any studies)
Effect of species diversity of multiple taxa on erosion control (In a survey of the literature, the investigators could not find any studies – they did, however, find studies on the effect of species diversity and root biomass)
Effect of diversity on flood regulation (In a survey of the literature, the investigators could not find any studies)
Effect of species and trait diversity of plants on soil moisture (In a survey of the literature, the investigators only found 2 studies)
Other sources have reported somewhat conflicting results and in 1997 Robert Costanza and his colleagues reported the estimated global value of ecosystem services (not captured in traditional markets) at an average of $33 trillion annually.
Since the stone age, species loss has accelerated above the average basal rate, driven by human activity. Estimates of species losses are at a rate 100-10,000 times as fast as is typical in the fossil record. Biodiversity also affords many non-material benefits including spiritual and aesthetic values, knowledge systems and education.
Agricultural diversity can be divided into two categories: intraspecific diversity, which includes the genetic variation within a single species, like the potato (Solanum tuberosum) that is composed of many different forms and types (e.g. in the U.S. they might compare russet potatoes with new potatoes or purple potatoes, all different, but all part of the same species, S. tuberosum).
The other category of agricultural diversity is called interspecific diversity and refers to the number and types of different species. Thinking about this diversity we might note that many small vegetable farmers grow many different crops like potatoes and also carrots, peppers, lettuce, etc.
Agricultural diversity can also be divided by whether it is 'planned' diversity or 'associated' diversity. This is a functional classification that we impose and not an intrinsic feature of life or diversity. Planned diversity includes the crops which a farmer has encouraged, planted or raised (e.g. crops, covers, symbionts, and livestock, among others), which can be contrasted with the associated diversity that arrives among the crops, uninvited (e.g. herbivores, weed species and pathogens, among others).
The control of associated biodiversity is one of the great agricultural challenges that farmers face. On monoculture farms, the approach is generally to eradicate associated diversity using a suite of biologically destructive pesticides, mechanized tools and transgenic engineering techniques, then to rotate crops. Although some polyculture farmers use the same techniques, they also employ integrated pest management strategies as well as more labor-intensive strategies, but generally less dependent on capital, biotechnology, and energy.
Interspecific crop diversity is, in part, responsible for offering variety in what we eat. Intraspecific diversity, the variety of alleles within a single species, also offers us a choice in our diets. If a crop fails in a monoculture, we rely on agricultural diversity to replant the land with something new. If a wheat crop is destroyed by a pest we may plant a hardier variety of wheat the next year, relying on intraspecific diversity. We may forgo wheat production in that area and plant a different species altogether, relying on interspecific diversity. Even an agricultural society that primarily grows monocultures relies on biodiversity at some point.
The Irish potato blight of 1846 was a major factor in the deaths of one million people and the emigration of about two million. It was the result of planting only two potato varieties, both vulnerable to the blight, Phytophthora infestans, which arrived in 1845
When rice grassy stunt virus struck rice fields from Indonesia to India in the 1970s, 6,273 varieties were tested for resistance. Only one was resistant, an Indian variety and known to science only since 1966. This variety formed a hybrid with other varieties and is now widely grown.
Coffee rust attacked coffee plantations in Sri Lanka, Brazil and Central America in 1970. A resistant variety was found in Ethiopia. The diseases are themselves a form of biodiversity.
Although about 80 percent of humans' food supply comes from just 20 kinds of plants, humans use at least 40,000 species. Many people depend on these species for food, shelter and clothing. Earth's surviving biodiversity provides resources for increasing the range of food and other products suitable for human use, although the present extinction rate shrinks that potential.
Biodiversity's relevance to human health is becoming an international political issue, as scientific evidence builds on the global health implications of biodiversity loss. This issue is closely linked with the issue of climate change, as many of the anticipated health risks of climate change are associated with changes in biodiversity (e.g. changes in populations and distribution of disease vectors, scarcity of fresh water, impacts on agricultural biodiversity and food resources etc.). This is because the species most likely to disappear are those that buffer against infectious disease transmission, while surviving species tend to be the ones that increase disease transmission, such as that of West Nile Virus, Lyme disease and Hantavirus, according to a study done co-authored by Felicia Keesing, an ecologist at Bard College and Drew Harvell, associate director for Environment of the Atkinson Center for a Sustainable Future (ACSF) at Cornell University.
The growing demand and lack of drinkable water on the planet presents an additional challenge to the future of human health. Partly, the problem lies in the success of water suppliers to increase supplies and failure of groups promoting the preservation of water resources. While the distribution of clean water increases, in some parts of the world it remains unequal. According to the World Health Organisation (2018), only 71% of the global population used a safely managed drinking-water service.
Some of the health issues influenced by biodiversity include dietary health and nutrition security, infectious disease, medical science and medicinal resources, social and psychological health. Biodiversity is also known to have an important role in reducing disaster risk and in post-disaster relief and recovery efforts.
Biodiversity provides critical support for drug discovery and the availability of medicinal resources. A significant proportion of drugs are derived, directly or indirectly, from biological sources: at least 50% of the pharmaceutical compounds on the US market are derived from plants, animals and microorganisms, while about 80% of the world population depends on medicines from nature (used in either modern or traditional medical practice) for primary healthcare. Only a tiny fraction of wild species has been investigated for medical potential. Biodiversity has been critical to advances throughout the field of bionics. Evidence from market analysis and biodiversity science indicates that the decline in output from the pharmaceutical sector since the mid-1980s can be attributed to a move away from natural product exploration ("bioprospecting") in favor of genomics and synthetic chemistry, indeed claims about the value of undiscovered pharmaceuticals may not provide enough incentive for companies in free markets to search for them because of the high cost of development; meanwhile, natural products have a long history of supporting significant economic and health innovation. Marine ecosystems are particularly important, although inappropriate bioprospecting can increase biodiversity loss, as well as violating the laws of the communities and states from which the resources are taken.
Many industrial materials derive directly from biological sources. These include building materials, fibers, dyes, rubber, and oil. Biodiversity is also important to the security of resources such as water, timber, paper, fiber, and food. As a result, biodiversity loss is a significant risk factor in business development and a threat to long term economic sustainability.
Leisure, cultural and aesthetic value
Biodiversity enriches leisure activities such as hiking, birdwatching or natural history study. Biodiversity inspires musicians, painters, sculptors, writers and other artists. Many cultures view themselves as an integral part of the natural world which requires them to respect other living organisms.
Popular activities such as gardening, fishkeeping and specimen collecting strongly depend on biodiversity. The number of species involved in such pursuits is in the tens of thousands, though the majority do not enter commerce.
The relationships between the original natural areas of these often exotic animals and plants and commercial collectors, suppliers, breeders, propagators and those who promote their understanding and enjoyment are complex and poorly understood. The general public responds well to exposure to rare and unusual organisms, reflecting their inherent value.
Philosophically it could be argued that biodiversity has intrinsic aesthetic and spiritual value to mankindin and of itself. This idea can be used as a counterweight to the notion that tropical forests and other ecological realms are only worthy of conservation because of the services they provide.
"There is now unequivocal evidence that biodiversity loss reduces the efficiency by which ecological communities capture biologically essential resources, produce biomass, decompose and recycle biologically essential nutrients... There is mounting evidence that biodiversity increases the stability of ecosystem functions through time... Diverse communities are more productive because they contain key species that have a large influence on productivity and differences in functional traits among organisms increase total resource capture... The impacts of diversity loss on ecological processes might be sufficiently large to rival the impacts of many other global drivers of environmental change... Maintaining multiple ecosystem processes at multiple places and times requires higher levels of biodiversity than does a single process at a single place and time."
It plays a part in regulating the chemistry of our atmosphere and water supply. Biodiversity is directly involved in water purification, recycling nutrients and providing fertile soils. Experiments with controlled environments have shown that humans cannot easily build ecosystems to support human needs; for example insect pollination cannot be mimicked, though there have been attempts to create artificial pollinators using unmanned aerial vehicles. The economic activity of pollination alone represented between $2.1–14.6 billions in 2003.
Discovered and predicted total number of species on land and in the oceans
According to Mora and colleagues, the total number of terrestrial species is estimated to be around 8.7 million while the number of oceanic species is much lower, estimated at 2.2 million. The authors note that these estimates are strongest for eukaryotic organisms and likely represent the lower bound of prokaryote diversity. Other estimates include:
1.5-3 million fungi, estimates based on data from the tropics, long-term non-tropical sites and molecular studies that have revealed cryptic speciation. Some 0.075 million species of fungi had been documented by 2001)
The number of microbial species is not reliably known, but the Global Ocean Sampling Expedition dramatically increased the estimates of genetic diversity by identifying an enormous number of new genes from near-surface plankton samples at various marine locations, initially over the 2004–2006 period. The findings may eventually cause a significant change in the way science defines species and other taxonomic categories.
Since the rate of extinction has increased, many extant species may become extinct before they are described. Not surprisingly, in the animalia the most studied groups are birds and mammals, whereas fishes and arthropods are the least studied animals groups.
No longer do we have to justify the existence of humid tropical forests on the feeble grounds that they might carry plants with drugs that cure human disease. Gaia theory forces us to see that they offer much more than this. Through their capacity to evapotranspirate vast volumes of water vapor, they serve to keep the planet cool by wearing a sunshade of white reflecting cloud. Their replacement by cropland could precipitate a disaster that is global in scale.
During the last century, decreases in biodiversity have been increasingly observed. In 2007, German Federal Environment Minister Sigmar Gabriel cited estimates that up to 30% of all species will be extinct by 2050. Of these, about one eighth of known plant species are threatened with extinction. Estimates reach as high as 140,000 species per year (based on Species-area theory). This figure indicates unsustainable ecological practices, because few species emerge each year. Almost all scientists acknowledge that the rate of species loss is greater now than at any time in human history, with extinctions occurring at rates hundreds of times higher than background extinction rates. As of 2012, some studies suggest that 25% of all mammal species could be extinct in 20 years.
In absolute terms, the planet has lost 58% of its biodiversity since 1970 according to a 2016 study by the World Wildlife Fund. The Living Planet Report 2014 claims that "the number of mammals, birds, reptiles, amphibians, and fish across the globe is, on average, about half the size it was 40 years ago". Of that number, 39% accounts for the terrestrial wildlife gone, 39% for the marine wildlife gone and 76% for the freshwater wildlife gone. Biodiversity took the biggest hit in Latin America, plummeting 83 percent. High-income countries showed a 10% increase in biodiversity, which was canceled out by a loss in low-income countries. This is despite the fact that high-income countries use five times the ecological resources of low-income countries, which was explained as a result of a process whereby wealthy nations are outsourcing resource depletion to poorer nations, which are suffering the greatest ecosystem losses.
A 2017 study published in PLOS One found that the biomass of insect life in Germany had declined by three-quarters in the last 25 years. Dave Goulson of Sussex University stated that their study suggested that humans "appear to be making vast tracts of land inhospitable to most forms of life, and are currently on course for ecological Armageddon. If we lose the insects then everything is going to collapse."
In 2006, many species were formally classified as rare or endangered or threatened; moreover, scientists have estimated that millions more species are at risk which have not been formally recognized. About 40 percent of the 40,177 species assessed using the IUCN Red List criteria are now listed as threatened with extinction—a total of 16,119.
invasive species (feral horses & household pets, zebra mussels, Miconia tree, kudzu, introduction for biocontrol)
problematic native species (overabundant native deer or kangaroo, overabundant algae due to loss of native grazing fish, locust-type plagues)
introduced genetic material (pesticide-resistant crops, genetically modified insects for biocontrol, genetically modified trees or salmon, escaped hatchery salmon, restoration projects using non-local seed stock)
pathogens & microbes (plague affecting rodents or rabbits, Dutch elm disease or chestnut blight, Chytrid fungus affecting amphibians outside of Africa)
household sewage & urban wastewater (discharge from municipal waste treatment plants, leaking septic systems, untreated sewage, outhouses, oil or sediment from roads, fertilizers and pesticides from lawns and golf-courses, road salt)
industrial & military effluents (toxic chemicals from factories, illegal dumping of chemicals, mine tailings, arsenic from gold mining, leakage from fuel tanks, PCBs in river sediments)
agricultural & forestry effluents (nutrient loading from fertilizer run-off, herbicide run-off, manure from feedlots, nutrients from aquaculture, soil erosion)
garbage & solid waste (municipal waste, litter & dumped possessions, flotsam & jetsam from recreational boats, waste that entangles wildlife, construction debris)
air-borne pollutants (acid rain, smog from vehicle emissions, excess nitrogen deposition, radioactive fallout, wind dispersion of pollutants or sediments from farm fields, smoke from forest fires or wood stoves)
excess energy (noise from highways or airplanes, sonar from submarines that disturbs whales, heated water from power plants, lamps attracting insects, beach lights disorienting turtles, atmospheric radiation from ozone holes)
10. catastrophic geological events
earthquakes, tsunamis, avalanches, landslides, & volcanic eruptions and gas emissions
11. climate changes
ecosystem encroachment (inundation of shoreline ecosystems & drowning of coral reefs from sea level rise, dune encroachment from desertification)
changes in geochemical regimes (ocean acidification, changes in atmospheric CO2 affecting plant growth, loss of sediment leading to broad-scale subsidence)
changes in temperature regimes (heat waves, cold spells, oceanic temperature changes, melting of glaciers/sea ice)
changes in precipitation & hydrological regimes (droughts, rain timing, loss of snow cover, increased severity of floods)
severe weather events (thunderstorms, tropical storms, hurricanes, cyclones, tornadoes, hailstorms, ice storms or blizzards, dust storms, erosion of beaches during storms)
Deforestation and increased road-building in the Amazon Rainforest cause significant concern because of increased human encroachment upon wild areas, increased resource extraction and further threats to biodiversity.
Habitat size and numbers of species are systematically related. Physically larger species and those living at lower latitudes or in forests or oceans are more sensitive to reduction in habitat area. Conversion to "trivial" standardized ecosystems (e.g., monoculture following deforestation) effectively destroys habitat for the more diverse species that preceded the conversion. Even the simplest forms of agriculture affect diversity – through clearing/draining the land, discouraging weeds and "pests", and encouraging just a limited set of domesticated plant and animal species. In some countries lack of property rights or lax law/regulatory enforcement necessarily leads to biodiversity loss (degradation costs having to be supported by the community).
Co-extinctions are a form of habitat destruction. Co-extinction occurs when the extinction or decline in one species accompanies similar processes in another, such as in plants and beetles.
A 2019 report has revealed that bees and other pollinating insects have been wiped out of almost a quarter of their habitats across the United Kingdom. The population crashes have been happening since the 1980s and are affecting biodiversity. The increase in industrial farming and pesticide use, combined with diseases, invasive species, and climate change is threatening the future of these insects and the agriculture they support.
Barriers such as large rivers, seas, oceans, mountains and deserts encourage diversity by enabling independent evolution on either side of the barrier, via the process of allopatric speciation. The term invasive species is applied to species that breach the natural barriers that would normally keep them constrained. Without barriers, such species occupy new territory, often supplanting native species by occupying their niches, or by using resources that would normally sustain native species.
The number of species invasions has been on the rise at least since the beginning of the 1900s. Species are increasingly being moved by humans (on purpose and accidentally). In some cases the invaders are causing drastic changes and damage to their new habitats (e.g.: zebra mussels and the emerald ash borer in the Great Lakes region and the lion fish along the North American Atlantic coast). Some evidence suggests that invasive species are competitive in their new habitats because they are subject to less pathogen disturbance. Others report confounding evidence that occasionally suggest that species-rich communities harbor many native and exotic species simultaneously while some say that diverse ecosystems are more resilient and resist invasive plants and animals. An important question is, "do invasive species cause extinctions?" Many studies cite effects of invasive species on natives, but not extinctions. Invasive species seem to increase local (i.e.: alpha diversity) diversity, which decreases turnover of diversity (i.e.: beta diversity). Overall gamma diversity may be lowered because species are going extinct because of other causes, but even some of the most insidious invaders (e.g.: Dutch elm disease, emerald ash borer, chestnut blight in North America) have not caused their host species to become extinct. Extirpation, population decline and homogenization of regional biodiversity are much more common. Human activities have frequently been the cause of invasive species circumventing their barriers, by introducing them for food and other purposes. Human activities therefore allow species to migrate to new areas (and thus become invasive) occurred on time scales much shorter than historically have been required for a species to extend its range.
Not all introduced species are invasive, nor all invasive species deliberately introduced. In cases such as the zebra mussel, invasion of US waterways was unintentional. In other cases, such as mongooses in Hawaii, the introduction is deliberate but ineffective (nocturnalrats were not vulnerable to the diurnal mongoose). In other cases, such as oil palms in Indonesia and Malaysia, the introduction produces substantial economic benefits, but the benefits are accompanied by costly unintended consequences.
Finally, an introduced species may unintentionally injure a species that depends on the species it replaces. In Belgium, Prunus spinosa from Eastern Europe leafs much sooner than its West European counterparts, disrupting the feeding habits of the Thecla betulae butterfly (which feeds on the leaves). Introducing new species often leaves endemic and other local species unable to compete with the exotic species and unable to survive. The exotic organisms may be predators, parasites, or may simply outcompete indigenous species for nutrients, water and light.
At present, several countries have already imported so many exotic species, particularly agricultural and ornamental plants, that their indigenous fauna/flora may be outnumbered. For example, the introduction of kudzu from Southeast Asia to Canada and the United States has threatened biodiversity in certain areas.
Endemic species can be threatened with extinction through the process of genetic pollution, i.e. uncontrolled hybridization, introgression and genetic swamping. Genetic pollution leads to homogenization or replacement of local genomes as a result of either a numerical and/or fitness advantage of an introduced species.
Hybridization and introgression are side-effects of introduction and invasion. These phenomena can be especially detrimental to rare species that come into contact with more abundant ones. The abundant species can interbreed with the rare species, swamping its gene pool. This problem is not always apparent from morphological (outward appearance) observations alone. Some degree of gene flow is normal adaptation and not all gene and genotype constellations can be preserved. However, hybridization with or without introgression may, nevertheless, threaten a rare species' existence.
In agriculture and animal husbandry, the Green Revolution popularized the use of conventional hybridization to increase yield. Often hybridized breeds originated in developed countries and were further hybridized with local varieties in the developing world to create high yield strains resistant to local climate and diseases. Local governments and industry have been pushing hybridization. Formerly huge gene pools of various wild and indigenous breeds have collapsed causing widespread genetic erosion and genetic pollution. This has resulted in the loss of genetic diversity and biodiversity as a whole.
Genetic erosion and genetic pollution have the potential to destroy unique genotypes, threatening future access to food security. A decrease in genetic diversity weakens the ability of crops and livestock to be hybridized to resist disease and survive changes in climate.
Global warming is a major threat to global biodiversity. For example, coral reefs – which are biodiversity hotspots – will be lost within the century if global warming continues at the current rate.
Climate change has proven to affect biodiversity and evidence supporting the altering effects is widespread. Increasing atmospheric carbon dioxide certainly affects plant morphology and is acidifying oceans, and temperature affects species ranges, phenology, and weather, but, mercifully, the major impacts that have been predicted are still potential futures. We have not documented major extinctions yet, even as climate change drastically alters the biology of many species.
In 2004, an international collaborative study on four continents estimated that 10 percent of species would become extinct by 2050 because of global warming. "We need to limit climate change or we wind up with a lot of species in trouble, possibly extinct," said Dr. Lee Hannah, a co-author of the paper and chief climate change biologist at the Center for Applied Biodiversity Science at Conservation International.
A recent study predicts that up to 35% of the world terrestrial carnivores and ungulates will be at higher risk of extinction by 2050 because of the joint effects of predicted climate and land-use change under business-as-usual human development scenarios.
Climate change has advanced the time of evening when Brazilian free-tailed bats (Tadarida brasiliensis) emerge to feed. This change is believed to be related to the drying of regions as temperatures rise. This earlier emergence exposes the bats to greater predation increased competition with other insectivores who feed in the twilight or daylight hours.
The world's population numbered nearly 7.6 billion as of mid-2017 (which is approximately one billion more inhabitants compared to 2005) and is forecast to reach 11.1 billion in 2100. Sir David King, former chief scientific adviser to the UK government, told a parliamentary inquiry: "It is self-evident that the massive growth in the human population through the 20th century has had more impact on biodiversity than any other single factor." At least until the middle of the 21st century, worldwide losses of pristine biodiverse land will probably depend much on the worldwide human birth rate. Biologists such as Paul R. Ehrlich and Stuart Pimm have noted that human population growth and overconsumption are the main drivers of species extinction.
According to a 2014 study by the World Wildlife Fund, the global human population already exceeds planet's biocapacity – it would take the equivalent of 1.5 Earths of biocapacity to meet our current demands. The report further points that if everyone on the planet had the Footprint of the average resident of Qatar, we would need 4.8 Earths and if we lived the lifestyle of a typical resident of the US, we would need 3.9 Earths.
1. Over the last 50 years, the state of nature has deteriorated at an unprecedented and accelerating rate.
2. The main drivers of this deterioration have been changes in land and sea use, exploitation of living beings, climate change, pollution, and invasive species. These five drivers, in turn, are caused by societal behaviors, from consumption to governance.
3. Damage to ecosystems undermines 35 of 44 selected UN targets, including the UN General Assembly's Sustainable Development Goals for poverty, hunger, health, water, cities' climate, oceans, and land. It can cause problems with food, water and humanity's air supply.
4. To fix the problem, humanity will need a transformative change, including sustainable agriculture, reductions in consumption and waste, fishing quotas and collaborative water management. On page 8 the report proposes on page 8 of the summary " enabling visions of a good quality of life that do not entail ever-increasing material consumption" as one of the main measures. The report states that "Some pathways chosen to achieve the goals related to energy, economic growth, industry and infrastructure and sustainable consumption and production (Sustainable Development Goals 7, 8, 9 and 12), as well as targets related to poverty, food security and cities (Sustainable Development Goals 1, 2 and 11), could have substantial positive or negative impacts on nature and therefore on the achievement of other Sustainable Development Goals"
A schematic image illustrating the relationship between biodiversity, ecosystem services, human well-being and poverty. The illustration shows where conservation action, strategies, and plans can influence the drivers of the current biodiversity crisis at local, regional, to global scales.
Conservation biology is reforming around strategic plans to protect biodiversity. Preserving global biodiversity is a priority in strategic conservation plans that are designed to engage public policy and concerns affecting local, regional and global scales of communities, ecosystems and cultures. Action plans identify ways of sustaining human well-being, employing natural capital, market capital and ecosystem services.
Removal of exotic species will allow the species that they have negatively impacted to recover their ecological niches. Exotic species that have become pests can be identified taxonomically (e.g., with Digital Automated Identification SYstem (DAISY), using the barcode of life). Removal is practical only given large groups of individuals due to the economic cost.
Gene banks are collections of specimens and genetic material. Some banks intend to reintroduce banked species to the ecosystem (e.g., via tree nurseries).
Reduction and better targeting of pesticides allows more species to survive in agricultural and urbanized areas.
Location-specific approaches may be less useful for protecting migratory species. One approach is to create wildlife corridors that correspond to the animals' movements. National and other boundaries can complicate corridor creation.
Protected areas are meant for affording protection to wild animals and their habitat which also includes forest reserves and biosphere reserves. Protected areas have been set up all over the world with the specific aim of protecting and conserving plants and animals. Some scientists have called on the global community to designate as protected areas of 30 percent of the planet by 2030, and 50 percent by 2050, in order to mitigate biodiversity loss from anthropogenic causes.
National park and nature reserve is the area selected by governments or private organizations for special protection against damage or degradation with the objective of biodiversity and landscape conservation. National parks are usually owned and managed by national or state governments. A limit is placed on the number of visitors permitted to enter certain fragile areas. Designated trails or roads are created. The visitors are allowed to enter only for study, cultural and recreation purposes. Forestry operations, grazing of animals and hunting of animals are regulated and the exploitation of habitat or wildlife is banned.
The forests play a vital role in harboring more than 45,000 floral and 81,000 faunal species of which 5150 floral and 1837 faunal species are endemic. Plant and animal species confined to a specific geographical area are called endemic species. In reserved forests, rights to activities like hunting and grazing are sometimes given to communities living on the fringes of the forest, who sustain their livelihood partially or wholly from forest resources or products. The unclassed forests cover 6.4 percent of the total forest area and they are marked by the following characteristics:
They are large inaccessible forests.
Many of these are unoccupied.
They are ecologically and economically less important.
In zoological parks or zoos, live animals are kept for public recreation, education and conservation purposes. Modern zoos offer veterinary facilities, provide opportunities for threatened species to breed in captivity and usually build environments that simulate the native habitats of the animals in their care. Zoos play a major role in creating awareness about the need to conserve nature.
In botanical gardens, plants are grown and displayed primarily for scientific and educational purposes. They consist of a collection of living plants, grown outdoors or under glass in greenhouses and conservatories. Also, a botanical garden may include a collection of dried plants or herbarium and such facilities as lecture rooms, laboratories, libraries, museums and experimental or research plantings.
Focusing on limited areas of higher potential biodiversity promises greater immediate return on investment than spreading resources evenly or focusing on areas of little diversity but greater interest in biodiversity.
A second strategy focuses on areas that retain most of their original diversity, which typically require little or no restoration. These are typically non-urbanized, non-agricultural areas. Tropical areas often fit both criteria, given their natively high diversity and relative lack of development.
A great deal of work is occurring to preserve the natural characteristics of Hopetoun Falls, Australia while continuing to allow visitor access.
Global agreements such as the Convention on Biological Diversity, give "sovereign national rights over biological resources" (not property). The agreements commit countries to "conserve biodiversity", "develop resources for sustainability" and "share the benefits" resulting from their use. Biodiverse countries that allow bioprospecting or collection of natural products, expect a share of the benefits rather than allowing the individual or institution that discovers/exploits the resource to capture them privately. Bioprospecting can become a type of biopiracy when such principles are not respected.
Biodiversity is taken into account in some political and judicial decisions:
The relationship between law and ecosystems is very ancient and has consequences for biodiversity. It is related to private and public property rights. It can define protection for threatened ecosystems, but also some rights and duties (for example, fishing and hunting rights).
Law regarding species is more recent. It defines species that must be protected because they may be threatened by extinction. The U.S. Endangered Species Act is an example of an attempt to address the "law and species" issue.
Laws regarding gene pools are only about a century old. Domestication and plant breeding methods are not new, but advances in genetic engineering have led to tighter laws covering distribution of genetically modified organisms, gene patents and process patents. Governments struggle to decide whether to focus on for example, genes, genomes, or organisms and species.
Uniform approval for use of biodiversity as a legal standard has not been achieved, however. Bosselman argues that biodiversity should not be used as a legal standard, claiming that the remaining areas of scientific uncertainty cause unacceptable administrative waste and increase litigation without promoting preservation goals.
India passed the Biological Diversity Act in 2002 for the conservation of biological diversity in India. The Act also provides mechanisms for equitable sharing of benefits from the use of traditional biological resources and knowledge.
Taxonomic and size relationships
Less than 1% of all species that have been described have been studied beyond simply noting their existence. The vast majority of Earth's species are microbial. Contemporary biodiversity physics is "firmly fixated on the visible [macroscopic] world". For example, microbial life is metabolically and environmentally more diverse than multicellular life (see e.g., extremophile). "On the tree of life, based on analyses of small-subunit ribosomal RNA, visible life consists of barely noticeable twigs. The inverse relationship of size and population recurs higher on the evolutionary ladder—to a first approximation, all multicellular species on Earth are insects".Insect extinction rates are high—supporting the Holocene extinction hypothesis.
Diversity study (botany)
The number of morphological attributes that can be scored for diversity study is generally limited and prone to environmental influences; thereby reducing the fine resolution required to ascertain the phylogenetic relationships. DNA based markers- microsatellites otherwise known as simple sequence repeats (SSR) were therefore used for the diversity studies of certain species and their wild relatives.
In the case of cowpea, a study conducted to assess the level of genetic diversity in cowpea germplasm and related wide species, where the relatedness among various taxa was compared, primers useful for classification of taxa identified, and the origin and phylogeny of cultivated cowpea classified show that SSR markers are useful in validating with species classification and revealing the center of diversity.
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