Climate change and agriculture

Refer to caption and image description
Human greenhouse gas emissions by sector, in the year 2010. "AFOLU" stands for "agriculture, forestry, and other land use".
Graph of net crop production worldwide and in selected tropical countries. Raw data from the United Nations.

Climate change and agriculture are interrelated processes, both of which take place on a global scale. Climate change affects agriculture in a number of ways, including through changes in average temperatures, rainfall, and climate extremes (e.g., heat waves); changes in pests and diseases; changes in atmospheric carbon dioxide and ground-level ozone concentrations; changes in the nutritional quality of some foods;[1] and changes in sea level.[2]

Climate change is already affecting agriculture, with effects unevenly distributed across the world.[3] Future climate change will likely negatively affect crop production in low latitude countries, while effects in northern latitudes may be positive or negative.[3] Climate change will probably increase the risk of food insecurity for some vulnerable groups, such as the poor.[4] Animal agriculture is also responsible for greenhouse gas production of CO2 and a percentage of the world's methane, and future land infertility, and the displacement of local species.

Agriculture contributes to climate change both by anthropogenic emissions of greenhouse gases and by the conversion of non-agricultural land such as forests into agricultural land.[5] Agriculture, forestry and land-use change contributed around 20 to 25% to global annual emissions in 2010.[6]

A range of policies can reduce the risk of negative climate change impacts on agriculture[7][8] and greenhouse gas emissions from the agriculture sector.[9][10][11]

Impact of climate change on agriculture

refer to caption and image description
For each plant variety, there is an optimal temperature for vegetative growth, with growth dropping off as temperatures increase or decrease. Similarly, there is a range of temperatures at which a plant will produce seed. Outside of this range, the plant will not reproduce. As the graphs show, corn will fail to reproduce at temperatures above 95 °F (35 °C) and soybean above 102 °F (38.8 °C).[12]

Despite technological advances, such as improved varieties, genetically modified organisms, and irrigation systems, weather is still a key factor in agricultural productivity, as well as soil properties and natural communities. The effect of climate on agriculture is related to variabilities in local climates rather than in global climate patterns. The Earth's average surface temperature has increased by 1.5 °F (0.83 °C) since 1880. Consequently, agronomists consider any assessment has to be individually consider each local area.

On the other hand, agricultural trade has grown in recent years, and now provides significant amounts of food, on a national level to major importing countries, as well as comfortable income to exporting ones. The international aspect of trade and security in terms of food implies the need to also consider the effects of climate change on a global scale.

A 2008 study published in Science suggested that, due to climate change, "southern Africa could lose more than 30% of its main crop, maize, by 2030. In South Asia losses of many regional staples, such as rice, millet and maize could top 10%".[13][14]

The Intergovernmental Panel on Climate Change (IPCC) has produced several reports that have assessed the scientific literature on climate change. The IPCC Third Assessment Report, published in 2001, concluded that the poorest countries would be hardest hit, with reductions in crop yields in most tropical and sub-tropical regions due to decreased water availability, and new or changed insect pest incidence. In Africa and Latin America many rainfed crops are near their maximum temperature tolerance, so that yields are likely to fall sharply for even small climate changes; falls in agricultural productivity of up to 30% over the 21st century are projected. Marine life and the fishing industry will also be severely affected in some places.

Climate change induced by increasing greenhouse gases is likely to affect crops differently from region to region. For example, average crop yield is expected to drop down to 50% in Pakistan according to the Met Office scenario whereas corn production in Europe is expected to grow up to 25% in optimum hydrologic conditions.

More favourable effects on yield tend to depend to a large extent on realization of the potentially beneficial effects of carbon dioxide on crop growth and increase of efficiency in water use. Decrease in potential yields is likely to be caused by shortening of the growing period, decrease in water availability and poor vernalization.

In the long run, the climatic change could affect agriculture in several ways :

  • productivity, in terms of quantity and quality of crops
  • agricultural practices, through changes of water use (irrigation) and agricultural inputs such as herbicides, insecticides and fertilizers
  • environmental effects, in particular in relation of frequency and intensity of soil drainage (leading to nitrogen leaching), soil erosion, reduction of crop diversity
  • rural space, through the loss and gain of cultivated lands, land speculation, land renunciation, and hydraulic amenities.
  • adaptation, organisms may become more or less competitive, as well as humans may develop urgency to develop more competitive organisms, such as flood resistant or salt resistant varieties of rice.

They are large uncertainties to uncover, particularly because there is lack of information on many specific local regions, and include the uncertainties on magnitude of climate change, the effects of technological changes on productivity, global food demands, and the numerous possibilities of adaptation.

Most agronomists believe that agricultural production will be mostly affected by the severity and pace of climate change, not so much by gradual trends in climate. If change is gradual, there may be enough time for biota adjustment. Rapid climate change, however, could harm agriculture in many countries, especially those that are already suffering from rather poor soil and climate conditions, because there is less time for optimum natural selection and adaption.

But much remains unknown about exactly how climate change may affect farming and food security, in part because the role of farmer behaviour is poorly captured by crop-climate models. For instance, Evan Fraser, a geographer at the University of Guelph in Ontario Canada, has conducted a number of studies that show that the socio-economic context of farming may play a huge role in determining whether a drought has a major, or an insignificant impact on crop production.[15][16] In some cases, it seems that even minor droughts have big impacts on food security (such as what happened in Ethiopia in the early 1980s where a minor drought triggered a massive famine), versus cases where even relatively large weather-related problems were adapted to without much hardship.[17] Evan Fraser combines socio-economic models along with climatic models to identify “vulnerability hotspots”[16] One such study has identified US maize (corn) production as particularly vulnerable to climate change because it is expected to be exposed to worse droughts, but it does not have the socio-economic conditions that suggest farmers will adapt to these changing conditions.[18] Other studies rely instead on projections of key agro-meteorological or agro-climate indices, such as growing season length, plant heat stress, or start of field operations, identified by land management stakeholders and that provide useful information on mechanisms driving climate change impact on agriculture.[19][20]

Pest insects and climate change

Global warming could lead to an increase in pest insect populations, harming yields of staple crops like wheat, soybeans, and corn.[21] While warmer temperatures create longer growing seasons, and faster growth rates for plants, it also increases the metabolic rate and number of breeding cycles of insect populations.[21] Insects that previously had only two breeding cycles per year could gain an additional cycle if warm growing seasons extend, causing a population boom. Temperate places and higher latitudes are more likely to experience a dramatic change in insect populations.[22]

The University of Illinois conducted studies to measure the effect of warmer temperatures on soybean plant growth and Japanese beetle populations.[23] Warmer temperatures and elevated CO2 levels were simulated for one field of soybeans, while the other was left as a control. These studies found that the soybeans with elevated CO2 levels grew much faster and had higher yields, but attracted Japanese beetles at a significantly higher rate than the control field.[23] The beetles in the field with increased CO2 also laid more eggs on the soybean plants and had longer lifespans, indicating the possibility of a rapidly expanding population. DeLucia projected that if the project were to continue, the field with elevated CO2 levels would eventually show lower yields than that of the control field.[23]

The increased CO2 levels deactivated three genes within the soybean plant that normally create chemical defenses against pest insects. One of these defenses is a protein that blocks digestion of the soy leaves in insects. Since this gene was deactivated, the beetles were able to digest a much higher amount of plant matter than the beetles in the control field. This led to the observed longer lifespans and higher egg-laying rates in the experimental field.[23]

There are a few proposed solutions to the issue of expanding pest populations. One proposed solution is to increase the number of pesticides used on future crops.[24] This has the benefit of being relatively cost effective and simple, but may be ineffective. Many pest insects have been building up an immunity to these pesticides. Another proposed solution is to utilize biological control agents.[24] This includes things like planting rows of native vegetation in between rows of crops. This solution is beneficial in its overall environmental impact. Not only are more native plants getting planted, but pest insects are no longer building up an immunity to pesticides. However, planting additional native plants requires more room, which destroys additional acres of public land. The cost is also much higher than simply using pesticides.[25]

Plant diseases and climate change

Although research is limited, research has shown that climate change may alter the developmental stages of pathogens that can affect crops.[26] The biggest consequence of climate change on the dispersal of pathogens is that the geographical distribution of hosts and pathogens could shift, which would result in more crop losses.[26] This could affect competition and recovery from disturbances of plants. It has been predicted that the effect of climate change will add a level of complexity to figuring out how to maintain sustainable agriculture.[26]

Observed impacts

Effects of regional climate change on agriculture have been limited.[27] Changes in crop phenology provide important evidence of the response to recent regional climate change.[28] Phenology is the study of natural phenomena that recur periodically, and how these phenomena relate to climate and seasonal changes.[29] A significant advance in phenology has been observed for agriculture and forestry in large parts of the Northern Hemisphere.[27]

Droughts have been occurring more frequently because of global warming and they are expected to become more frequent and intense in Africa, southern Europe, the Middle East, most of the Americas, Australia, and Southeast Asia.[30] Their impacts are aggravated because of increased water demand, population growth, urban expansion, and environmental protection efforts in many areas.[31] Droughts result in crop failures and the loss of pasture grazing land for livestock.[32]

Examples

Banana farm at Chinawal village in Jalgaon district, India

As of the decade starting in 2010, many hot countries have thriving agricultural sectors.

Jalgaon district, India, has an average temperature which ranges from 20.2 °C in December to 29.8 °C in May, and an average precipitation of 750 mm/year.[33] It produces bananas at a rate that would make it the world's seventh-largest banana producer if it were a country.[34]

During the period 1990-2012, Nigeria had an average temperature which ranged from a low of 24.9 °C in January to a high of 30.4 °C in April.[35] According to the Food and Agriculture Organization of the United Nations (FAO), Nigeria is by far the world's largest producer of yams, producing over 38 million tonnes in 2012. The second through 8th largest yam producers were all nearby African countries, with the largest non-African producer, Papua New Guinea, producing less than 1% of Nigerian production.[36]

In 2013, according to the FAO, Brazil and India were by far the world's leading producers of sugarcane, with a combined production of over 1 billion tonnes, or over half of worldwide production.[37]

In the summer of 2018, heat waves probably linked to climate change cause much lower than average yield in many parts of the world, especially in Europe. Depending on conditions during August, more crop failures could rise global food prices.[38] losses are compared to those of 1945, the worst harvest in memory. last year was the third time in four years that global wheat, rice and maize production failed to meet demand, forcing governments and food companies to release stocks from storage. India last week released 50% of its food stocks. Lester Brown, the head of Worldwatch, an independent research organisation, predicted thatfood prices will rise in the next few months.

Overall food shortages are not expected this year. But, for prevent hunger, instability, new waves of Climate refugees international help to countries who will luck the money to buy enough food and stopping conflicts will be needed[39][40](see also Climate change adaptation).

Projections

As part of the IPCC's Fourth Assessment Report, Schneider et al. (2007) projected the potential future effects of climate change on agriculture.[41] With low to medium confidence, they concluded that for about a 1 to 3 °C global mean temperature increase (by 2100, relative to the 1990–2000 average level) there would be productivity decreases for some cereals in low latitudes, and productivity increases in high latitudes. In the IPCC Fourth Assessment Report, "low confidence" means that a particular finding has about a 2 out of 10 chance of being correct, based on expert judgement. "Medium confidence" has about a 5 out of 10 chance of being correct.[42] Over the same time period, with medium confidence, global production potential was projected to:[41]

  • increase up to around 3 °C,
  • very likely decrease above about 3 °C.

Most of the studies on global agriculture assessed by Schneider et al. (2007) had not incorporated a number of critical factors, including changes in extreme events, or the spread of pests and diseases. Studies had also not considered the development of specific practices or technologies to aid adaptation to climate change.[43]

The US National Research Council (US NRC, 2011)[44] assessed the literature on the effects of climate change on crop yields. US NRC (2011)[45] stressed the uncertainties in their projections of changes in crop yields.

Writing in the journal Nature Climate Change, Matthew Smith and Samuel Myers (2018) estimated that food crops could see a reduction of protein, iron and zinc content in common food crops of 3 to 17%.[46] This is the projected result of food grown under the expected atmospheric carbon-dioxide levels of 2050. Using data from the UN Food and Agriculture Organization as well as other public sources, the authors analyzed 225 different staple foods, such as wheat, rice, maize, vegetables, roots and fruits.[47]

Refer to caption
Projected changes in crop yields at different latitudes with global warming. This graph is based on several studies.[44]
Refer to caption
Projected changes in yields of selected crops with global warming. This graph is based on several studies.[44]

Their central estimates of changes in crop yields are shown above. Actual changes in yields may be above or below these central estimates.[45] US NRC (2011)[44] also provided an estimated the "likely" range of changes in yields. "Likely" means a greater than 67% chance of being correct, based on expert judgement. The likely ranges are summarized in the image descriptions of the two graphs.

Food security

The IPCC Fourth Assessment Report also describes the impact of climate change on food security.[48] Projections suggested that there could be large decreases in hunger globally by 2080, compared to the (then-current) 2006 level.[49] Reductions in hunger were driven by projected social and economic development. For reference, the Food and Agriculture Organization has estimated that in 2006, the number of people undernourished globally was 820 million.[50] Three scenarios without climate change (SRES A1, B1, B2) projected 100-130 million undernourished by the year 2080, while another scenario without climate change (SRES A2) projected 770 million undernourished. Based on an expert assessment of all of the evidence, these projections were thought to have about a 5-in-10 chance of being correct.[42]

The same set of greenhouse gas and socio-economic scenarios were also used in projections that included the effects of climate change.[49] Including climate change, three scenarios (SRES A1, B1, B2) projected 100-380 million undernourished by the year 2080, while another scenario with climate change (SRES A2) projected 740-1,300 million undernourished. These projections were thought to have between a 2-in-10 and 5-in-10 chance of being correct.[42]

Projections also suggested regional changes in the global distribution of hunger.[49] By 2080, sub-Saharan Africa may overtake Asia as the world's most food-insecure region. This is mainly due to projected social and economic changes, rather than climate change.[48]

In South America, a phenomenon known as the El Nino Oscillation Cycle, between floods and drought on the Pacific Coast has made as much as a 35% difference in Global yields of wheat and grain.[51]

Looking at the four key components of food security we can see the impact climate change has had. Food “Access to food is largely a matter of household and individual-level income and of capabilities and rights” (Wheeler et al.,2013). Access has been affected by the thousands of crops being destroyed, how communities are dealing with climate shocks and adapting to climate change. Prices on food will rise due to the shortage of food production due to conditions not being favourable for crop production. Utilization is affected by floods and drought where water resources are contaminated, and the changing temperatures create vicious stages and phases of disease. Availability is affected by the contamination of the crops, as there will be no food process for the products of these crops as a result. Stability is affected through price ranges and future prices as some food sources are becoming scarce due to climate change, so prices will rise.

Individual studies

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Projections by Cline (2008).[52]

Cline (2008)[52] looked at how climate change might affect agricultural productivity in the 2080s. His study assumes that no efforts are made to reduce anthropogenic greenhouse gas emissions, leading to global warming of 3.3 °C above the pre-industrial level. He concluded that global agricultural productivity could be negatively affected by climate change, with the worst effects in developing countries (see graph opposite).

Lobell et al. (2008a)[53] assessed how climate change might affect 12 food-insecure regions in 2030. The purpose of their analysis was to assess where adaptation measures to climate change should be prioritized. They found that without sufficient adaptation measures, South Asia and South Africa would likely suffer negative impacts on several crops which are important to large food insecure human populations.

Battisti and Naylor (2009)[54] looked at how increased seasonal temperatures might affect agricultural productivity. Projections by the IPCC suggest that with climate change, high seasonal temperatures will become widespread, with the likelihood of extreme temperatures increasing through the second half of the 21st century. Battisti and Naylor (2009)[54] concluded that such changes could have very serious effects on agriculture, particularly in the tropics. They suggest that major, near-term, investments in adaptation measures could reduce these risks.

"Climate change merely increases the urgency of reforming trade policies to ensure that global food security needs are met"[55] said C. Bellmann, ICTSD Programmes Director. A 2009 ICTSD-IPC study by Jodie Keane[56] suggests that climate change could cause farm output in sub-Saharan Africa to decrease by 12% by 2080 - although in some African countries this figure could be as much as 60%, with agricultural exports declining by up to one fifth in others. Adapting to climate change could cost the agriculture sector $14bn globally a year, the study finds.

Regional

Africa

African crop production. Raw data from the United Nations.

In Africa, IPCC (2007:13)[57] projected that climate variability and change would severely compromise agricultural production and access to food. This projection was assigned "high confidence."

Africa's geography makes it particularly vulnerable to climate change, and seventy per cent of the population rely on rain-fed agriculture for their livelihoods. Tanzania's official report on climate change suggests that the areas that usually get two rainfalls in the year will probably get more, and those that get only one rainy season will get far less. As of 2005, the net result was expected to be that 33% less maize—the country's staple crop—would be grown.[58]

Asia

In East and Southeast Asia, IPCC (2007:13)[57] projected that crop yields could increase up to 20% by the mid-21st century. In Central and South Asia, projections suggested that yields might decrease by up to 30%, over the same time period. These projections were assigned "medium confidence." Taken together, the risk of hunger was projected to remain very high in several developing countries.

More detailed analysis of rice yields by the International Rice Research Institute forecast 20% reduction in yields over the region per degree Celsius of temperature rise. Rice becomes sterile if exposed to temperatures above 35 degrees for more than one hour during flowering and consequently produces no grain.

A 2013 study by the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT) aimed to find science-based, pro-poor approaches and techniques that would enable Asia's agricultural systems to cope with climate change, while benefitting poor and vulnerable farmers. The study's recommendations ranged from improving the use of climate information in local planning and strengthening weather-based agro-advisory services, to stimulating diversification of rural household incomes and providing incentives to farmers to adopt natural resource conservation measures to enhance forest cover, replenish groundwater and use renewable energy.[59] A 2014 study found that warming had increased maize yields in the Heilongjiang region of China had increased by between 7 and 17% per decade as a result of rising temperatures.[60]

Due to climate change, livestock production will be decreased in Bangladesh by diseases, scarcity of forage, heat stress and breeding strategies.[61]

Australia and New Zealand

Hennessy et al.. (2007:509)[62] assessed the literature for Australia and New Zealand. They concluded that without further adaptation to climate change, projected impacts would likely be substantial: By 2030, production from agriculture and forestry was projected to decline over much of southern and eastern Australia, and over parts of eastern New Zealand; In New Zealand, initial benefits were projected close to major rivers and in western and southern areas. Hennessy et al.. (2007:509)[62] placed high confidence in these projections.

Europe

With high confidence, IPCC (2007:14)[57] projected that in Southern Europe, climate change would reduce crop productivity. In Central and Eastern Europe, forest productivity was expected to decline. In Northern Europe, the initial effect of climate change was projected to increase crop yields.

Latin America

The major agricultural products of Latin American regions include livestock and grains, such as maize, wheat, soybeans, and rice.[63][64] Increased temperatures and altered hydrological cycles are predicted to translate to shorter growing seasons, overall reduced biomass production, and lower grain yields.[64][65] Brazil, Mexico and Argentina alone contribute 70-90% of the total agricultural production in Latin America.[64] In these and other dry regions, maize production is expected to decrease.[63][64] A study summarizing a number of impact studies of climate change on agriculture in Latin America indicated that wheat is expected to decrease in Brazil, Argentina and Uruguay.[64] Livestock, which is the main agricultural product for parts of Argentina, Uruguay, southern Brazil, Venezuela, and Colombia is likely to be reduced.[63][64] Variability in the degree of production decrease among different regions of Latin America is likely.[63] For example, one 2003 study that estimated future maize production in Latin America predicted that by 2055 maize in eastern Brazil will have moderate changes while Venezuela is expected to have drastic decreases.[63]

Suggested potential adaptation strategies to mitigate the impacts of global warming on agriculture in Latin America include using plant breeding technologies and installing irrigation infrastructure.[64]

Climate justice and subsistence farmers in Latin America

Several studies that investigated the impacts of climate change on agriculture in Latin America suggest that in the poorer countries of Latin America, agriculture composes the most important economic sector and the primary form of sustenance for small farmers.[63][64][65][66] Maize is the only grain still produced as a sustenance crop on small farms in Latin American nations.[64] Scholars argue that the projected decrease of this grain and other crops will threaten the welfare and the economic development of subsistence communities in Latin America.[63][64][65] Food security is of particular concern to rural areas that have weak or non-existent food markets to rely on in the case food shortages.[67]

According to scholars who considered the environmental justice implications of climate change, the expected impacts of climate change on subsistence farmers in Latin America and other developing regions are unjust for two reasons.[66][68] First, subsistence farmers in developing countries, including those in Latin America are disproportionately vulnerable to climate change[68] Second, these nations were the least responsible for causing the problem of anthropogenic induced climate.[68]

According to researchers John F. Morton and T. Roberts, disproportionate vulnerability to climate disasters is socially determined.[66][68] For example, socioeconomic and policy trends affecting smallholder and subsistence farmers limit their capacity to adapt to change.[66] According to W. Baethgen who studied the vulnerability of Latin American agriculture to climate change, a history of policies and economic dynamics has negatively impacted rural farmers.[64] During the 1950s and through the 1980s, high inflation and appreciated real exchange rates reduced the value of agricultural exports.[64] As a result, farmers in Latin America received lower prices for their products compared to world market prices.[64] Following these outcomes, Latin American policies and national crop programs aimed to stimulate agricultural intensification.[64] These national crop programs benefitted larger commercial farmers more. In the 1980s and 1990s low world market prices for cereals and livestock resulted in decreased agricultural growth and increased rural poverty.[64]

In the book, Fairness in Adaptation to Climate Change, the authors describe the global injustice of climate change between the rich nations of the north, who are the most responsible for global warming and the southern poor countries and minority populations within those countries who are most vulnerable to climate change impacts.[68]

Adaptive planning is challenged by the difficulty of predicting local scale climate change impacts.[66] An expert that considered opportunities for climate change adaptation for rural communities argues that a crucial component to adaptation should include government efforts to lessen the effects of food shortages and famines.[69] This researcher also claims that planning for equitable adaptation and agricultural sustainability will require the engagement of farmers in decision making processes.[69]

North America

A number of studies have been produced which assess the impacts of climate change on agriculture in North America. The IPCC Fourth Assessment Report of agricultural impacts in the region cites 26 different studies.[70] With high confidence, IPCC (2007:14–15)[57] projected that over the first few decades of this century, moderate climate change would increase aggregate yields of rain-fed agriculture by 5–20%, but with important variability among regions. Major challenges were projected for crops that are near the warm end of their suitable range or which depend on highly utilized water resources.

Droughts are becoming more frequent and intense in arid and semiarid western North America as temperatures have been rising, advancing the timing and magnitude of spring snow melt floods and reducing river flow volume in summer.[71] Direct effects of climate change include increased heat and water stress, altered crop phenology, and disrupted symbiotic interactions. These effects may be exacerbated by climate changes in river flow, and the combined effects are likely to reduce the abundance of native trees in favor of non-native herbaceous and drought-tolerant competitors, reduce the habitat quality for many native animals, and slow litter decomposition and nutrient cycling. Climate change effects on human water demand and irrigation may intensify these effects.[72]

The US Global Change Research Program (2009) assessed the literature on the impacts of climate change on agriculture in the United States, finding that many crops will benefit from increased atmospheric CO2 concentrations and low levels of warming, but that higher levels of warming will negatively affect growth and yields; that extreme weather events will likely reduce crop yields; that weeds, diseases and insect pests will benefit from warming, and will require additional pest and weed control; and that increasing CO2 concentrations will reduce the land's ability to supply adequate livestock feed, while increased heat, disease, and weather extremes will likely reduce livestock productivity.[73]

Polar regions

Anisimov et al.. (2007:655)[74] assessed the literature for the polar region (Arctic and Antarctica). With medium confidence, they concluded that the benefits of a less severe climate were dependent on local conditions. One of these benefits was judged to be increased agricultural and forestry opportunities.

The Guardian reported on how climate change had affected agriculture in Iceland. Rising temperatures had made the widespread sowing of barley possible, which had been untenable twenty years ago. Some of the warming was due to a local (possibly temporary) effect via ocean currents from the Caribbean, which had also affected fish stocks.[75]

Small islands

In a literature assessment, Mimura et al. (2007:689)[76] concluded that on small islands, subsistence and commercial agriculture would very likely be adversely affected by climate change. This projection was assigned "high confidence."

Poverty impacts

Researchers at the Overseas Development Institute (ODI) have investigated the potential impacts climate change could have on agriculture, and how this would affect attempts at alleviating poverty in the developing world.[77] They argued that the effects from moderate climate change are likely to be mixed for developing countries. However, the vulnerability of the poor in developing countries to short term impacts from climate change, notably the increased frequency and severity of adverse weather events is likely to have a negative impact. This, they say, should be taken into account when defining agricultural policy.[77]

Mitigation and adaptation in developing countries

The Intergovernmental Panel on Climate Change (IPCC) has reported that agriculture is responsible for over a quarter of total global greenhouse gas emissions.[78] Given that agriculture’s share in global gross domestic product (GDP) is about 4%, these figures suggest that agriculture is highly greenhouse gas intensive. Innovative agricultural practices and technologies can play a role in climate change mitigation [79] and adaptation. This adaptation and mitigation potential is nowhere more pronounced than in developing countries where agricultural productivity remains low; poverty, vulnerability and food insecurity remain high; and the direct effects of climate change are expected to be especially harsh. Creating the necessary agricultural technologies and harnessing them to enable developing countries to adapt their agricultural systems to changing climate will require innovations in policy and institutions as well. In this context, institutions and policies are important at multiple scales.

Travis Lybbert and Daniel Sumner[80] suggest six policy principles: (1) The best policy and institutional responses will enhance information flows, incentives and flexibility. (2) Policies and institutions that promote economic development and reduce poverty will often improve agricultural adaptation and may also pave the way for more effective climate change mitigation through agriculture. (3) Business as usual among the world’s poor is not adequate. (4) Existing technology options must be made more available and accessible without overlooking complementary capacity and investments. (5) Adaptation and mitigation in agriculture will require local responses, but effective policy responses must also reflect global impacts and inter-linkages. (6) Trade will play a critical role in both mitigation and adaptation, but will itself be shaped importantly by climate change.

The Agricultural Model Intercomparison and Improvement Project (AgMIP)[81] was developed in 2010 to evaluate agricultural models and intercompare their ability to predict climate impacts. In sub-Saharan Africa and South Asia, South America and East Asia, AgMIP regional research teams (RRTs) are conducting integrated assessments to improve understanding of agricultural impacts of climate change (including biophysical and economic impacts) at national and regional scales. Other AgMIP initiatives include global gridded modeling, data and information technology (IT) tool development, simulation of crop pests and diseases, site-based crop-climate sensitivity studies, and aggregation and scaling.

Crop development models

Models for climate behavior are frequently inconclusive. In order to further study effects of global warming on agriculture, other types of models, such as crop development models, yield prediction, quantities of water or fertilizer consumed, can be used. Such models condense the knowledge accumulated of the climate, soil, and effects observed of the results of various agricultural practices. They thus could make it possible to test strategies of adaptation to modifications of the environment.

Because these models are necessarily simplifying natural conditions (often based on the assumption that weeds, disease and insect pests are controlled), it is not clear whether the results they give will have an in-field reality. However, some results are partly validated with an increasing number of experimental results.

Other models, such as insect and disease development models based on climate projections are also used (for example simulation of aphid reproduction or septoria (cereal fungal disease) development).

Scenarios are used in order to estimate climate changes effects on crop development and yield. Each scenario is defined as a set of meteorological variables, based on generally accepted projections. For example, many models are running simulations based on doubled carbon dioxide projections, temperatures raise ranging from 1 °C up to 5 °C, and with rainfall levels an increase or decrease of 20%. Other parameters may include humidity, wind, and solar activity. Scenarios of crop models are testing farm-level adaptation, such as sowing date shift, climate adapted species (vernalisation need, heat and cold resistance), irrigation and fertilizer adaptation, resistance to disease. Most developed models are about wheat, maize, rice and soybean.

Temperature potential effect on growing period

Duration of crop growth cycles are above all, related to temperature. An increase in temperature will speed up development. In the case of an annual crop, the duration between sowing and harvesting will shorten (for example, the duration in order to harvest corn could shorten between one and four weeks). The shortening of such a cycle could have an adverse effect on productivity because senescence would occur sooner.

Effect of elevated carbon dioxide on crops

Carbon dioxide is essential to plant growth. Rising CO2 concentration in the atmosphere can have both positive and negative consequences.

Increased CO2 is expected to have positive physiological effects by increasing the rate of photosynthesis. This is known as 'carbon dioxide fertilisation'. Currently, the amount of carbon dioxide in the atmosphere is 410 parts per million. In comparison, the amount of oxygen is 210,000 ppm. This means that often plants may be starved of carbon dioxide as the enzyme that fixes CO2, RuBisCo, also fixes oxygen in the process of photorespiration. The effects of an increase in carbon dioxide would be higher on C3 crops (such as wheat) than on C4 crops (such as maize), because the former is more susceptible to carbon dioxide shortage. Studies have shown that increased CO2 leads to fewer stomata developing on plants[82] which leads to reduced water usage.[83] Under optimum conditions of temperature and humidity, the yield increase could reach 36%, if the levels of carbon dioxide are doubled. A study in 2014 posited that CO2 fertilisation is underestimated due to not explicitly representing CO2 diffusion inside leaves.[84]

Further, few studies have looked at the impact of elevated carbon dioxide concentrations on whole farming systems. Most models study the relationship between CO2 and productivity in isolation from other factors associated with climate change, such as an increased frequency of extreme weather events, seasonal shifts, and so on.

In 2005, the Royal Society in London concluded that the purported benefits of elevated carbon dioxide concentrations are "likely to be far lower than previously estimated when factors such as increasing ground-level ozone are taken into account."[85]

Myers et al. 2014, reported based on a meta study, that elevated CO2 levels reduced the nutrient concentrations (zinc, iron, and less so protein) of plants, with C3 grasses and legumes specifically affected and C4 plants not so much.[86]

Effect on quality

According to the IPCC's TAR, "The importance of climate change impacts on grain and forage quality emerges from new research. For rice, the amylose content of the grain—a major determinant of cooking quality—is increased under elevated CO2" (Conroy et al., 1994). Cooked rice grain from plants grown in high-CO2 environments would be firmer than that from today's plants. However, concentrations of iron and zinc, which are important for human nutrition, would be lower (Seneweera and Conroy, 1997). Moreover, the protein content of the grain decreases under combined increases of temperature and CO2 (Ziska et al., 1997).[87] Studies using FACE have shown that increases in CO2 lead to decreased concentrations of micronutrients in crop plants,[88] including decreased B vitamins in rice.[89][90] This may have knock-on effects on other parts of ecosystems as herbivores will need to eat more food to gain the same amount of protein.[91]

Studies have shown that higher CO2 levels lead to reduced plant uptake of nitrogen (and a smaller number showing the same for trace elements such as zinc) resulting in crops with lower nutritional value.[92][93] This would primarily impact on populations in poorer countries less able to compensate by eating more food, more varied diets, or possibly taking supplements.

Reduced nitrogen content in grazing plants has also been shown to reduce animal productivity in sheep, which depend on microbes in their gut to digest plants, which in turn depend on nitrogen intake.[92] Because of the lack of water available to crops in warmer countries they struggle to survive as they suffer from dehydration, taking into account the increasing demand for water outside of agriculture as well as other agricultural demands.[94]

Agricultural surfaces and climate changes

Climate change may increase the amount of arable land in high-latitude region by reduction of the amount of frozen lands. A 2005 study reports that temperature in Siberia has increased three degree Celsius in average since 1960 (much more than the rest of the world).[95] However, reports about the impact of global warming on Russian agriculture[96] indicate conflicting probable effects : while they expect a northward extension of farmable lands,[97] they also warn of possible productivity losses and increased risk of drought.[98]

Sea levels are expected to get up to one meter higher by 2100, though this projection is disputed. A rise in the sea level would result in an agricultural land loss, in particular in areas such as South East Asia. Erosion, submergence of shorelines, salinity of the water table due to the increased sea levels, could mainly affect agriculture through inundation of low-lying lands.

Low-lying areas such as Bangladesh, India and Vietnam will experience major loss of rice crop if sea levels rise as expected by the end of the century. Vietnam for example relies heavily on its southern tip, where the Mekong Delta lies, for rice planting. Any rise in sea level of no more than a meter will drown several km2 of rice paddies, rendering Vietnam incapable of producing its main staple and export of rice.[99]

Erosion and fertility

The warmer atmospheric temperatures observed over the past decades are expected to lead to a more vigorous hydrological cycle, including more extreme rainfall events. Erosion and soil degradation is more likely to occur. Soil fertility would also be affected by global warming. Increased erosion in agricultural landscapes from anthropogenic factors can occur with losses of up to 22% of soil carbon in 50 years.[100] However, because the ratio of soil organic carbon to nitrogen is mediated by soil biology such that it maintains a narrow range, a doubling of soil organic carbon is likely to imply a doubling in the storage of nitrogen in soils as organic nitrogen, thus providing higher available nutrient levels for plants, supporting higher yield potential. The demand for imported fertilizer nitrogen could decrease, and provide the opportunity for changing costly fertilisation strategies.

Due to the extremes of climate that would result, the increase in precipitations would probably result in greater risks of erosion, whilst at the same time providing soil with better hydration, according to the intensity of the rain. The possible evolution of the organic matter in the soil is a highly contested issue: while the increase in the temperature would induce a greater rate in the production of minerals, lessening the soil organic matter content, the atmospheric CO2 concentration would tend to increase it.

Potential effects of global climate change on pests, diseases and weeds

A very important point to consider is that weeds would undergo the same acceleration of cycle as cultivated crops, and would also benefit from carbonaceous fertilization. Since most weeds are C3 plants, they are likely to compete even more than now against C4 crops such as corn. However, on the other hand, some results make it possible to think that weedkillers could increase in effectiveness with the temperature increase.[101]

Global warming would cause an increase in rainfall in some areas, which would lead to an increase of atmospheric humidity and the duration of the wet seasons. Combined with higher temperatures, these could favor the development of fungal diseases. Similarly, because of higher temperatures and humidity, there could be an increased pressure from insects and disease vectors.

Glacier retreat and disappearance

The continued retreat of glaciers will have a number of different quantitative impacts. In the areas that are heavily dependent on water runoff from glaciers that melt during the warmer summer months, a continuation of the current retreat will eventually deplete the glacial ice and substantially reduce or eliminate runoff. A reduction in runoff will affect the ability to irrigate crops and will reduce summer stream flows necessary to keep dams and reservoirs replenished.

Approximately 2.4 billion people live in the drainage basin of the Himalayan rivers.[102] India, China, Pakistan, Afghanistan, Bangladesh, Nepal and Myanmar could experience floods followed by severe droughts in coming decades.[103] In India alone, the Ganges provides water for drinking and farming for more than 500 million people.[104][105] The west coast of North America, which gets much of its water from glaciers in mountain ranges such as the Rocky Mountains and Sierra Nevada, also would be affected.[106]

Ozone and UV-B

Some scientists think agriculture could be affected by any decrease in stratospheric ozone, which could increase biologically dangerous ultraviolet radiation B. Excess ultraviolet radiation B can directly affect plant physiology and cause massive amounts of mutations, and indirectly through changed pollinator behavior, though such changes are not simple to quantify.[107] However, it has not yet been ascertained whether an increase in greenhouse gases would decrease stratospheric ozone levels.

In addition, a possible effect of rising temperatures is significantly higher levels of ground-level ozone, which would substantially lower yields.[108]

ENSO effects on agriculture

ENSO (El Niño Southern Oscillation) will affect monsoon patterns more intensely in the future as climate change warms up the ocean's water. Crops that lie on the equatorial belt or under the tropical Walker circulation, such as rice, will be affected by varying monsoon patterns and more unpredictable weather. Scheduled planting and harvesting based on weather patterns will become less effective.

Areas such as Indonesia where the main crop consists of rice will be more vulnerable to the increased intensity of ENSO effects in the future of climate change. University of Washington professor, David Battisti, researched the effects of future ENSO patterns on the Indonesian rice agriculture using [IPCC]'s 2007 annual report[109] and 20 different logistical models mapping out climate factors such as wind pressure, sea-level, and humidity, and found that rice harvest will experience a decrease in yield. Bali and Java, which holds 55% of the rice yields in Indonesia, will be likely to experience 9–10% probably of delayed monsoon patterns, which prolongs the hungry season. Normal planting of rice crops begin in October and harevest by January. However, as climate change affects ENSO and consequently delays planting, harvesting will be late and in drier conditions, resulting in less potential yields.[110]

Impact of agriculture on climate change

refer to caption and image description
Greenhouse gas emissions from agriculture, by region, 1990-2010.

The agricultural sector is a driving force in the gas emissions and land use effects thought to cause climate change. In addition to being a significant user of land and consumer of fossil fuel, agriculture contributes directly to greenhouse gas emissions through practices such as rice production and the raising of livestock;[111] according to the Intergovernmental Panel on Climate Change, the three main causes of the increase in greenhouse gases observed over the past 250 years have been fossil fuels, land use, and agriculture.[112]

Land use

Agriculture contributes to greenhouse gas increases through land use in four main ways:

Together, these agricultural processes comprise 54% of methane emissions, roughly 80% of nitrous oxide emissions, and virtually all carbon dioxide emissions tied to land use.[113]

The planet's major changes to land cover since 1750 have resulted from deforestation in temperate regions: when forests and woodlands are cleared to make room for fields and pastures, the albedo of the affected area increases, which can result in either warming or cooling effects, depending on local conditions.[114] Deforestation also affects regional carbon reuptake, which can result in increased concentrations of CO2, the dominant greenhouse gas.[115] Land-clearing methods such as slash and burn compound these effects by burning biomatter, which directly releases greenhouse gases and particulate matter such as soot into the air.

Livestock

Livestock and livestock-related activities such as deforestation and increasingly fuel-intensive farming practices are responsible for over 18%[116] of human-made greenhouse gas emissions, including:

Livestock activities also contribute disproportionately to land-use effects, since crops such as corn and alfalfa are cultivated in order to feed the animals.

In 2010, enteric fermentation accounted for 43% of the total greenhouse gas emissions from all agricultural activity in the world.[117] The meat from ruminants has a higher carbon equivalent footprint than other meats or vegetarian sources of protein based on a global meta-analysis of lifecycle assessment studies.[118] Methane production by animals, principally ruminants, is estimated 15-20% global production of methane.[119][120]

Worldwide, livestock production occupies 70% of all land used for agriculture, or 30% of the land surface of the Earth.[116] The way livestock is grazed also decides the fertility of the land in the future, not circulating grazing can lead to unhealthy soil and the expansion of livestock farms effects the habitats of local animals and has led to the drop in population of many local species from being displaced.

See also

Notes

  1. Milius, Susan (December 13, 2017). "Worries grow that climate change will quietly steal nutrients from major food crops". Science News. Retrieved January 21, 2018.
  2. Hoffmann, U., Section B: Agriculture - a key driver and a major victim of global warming, in: Lead Article, in: Chapter 1, in Hoffmann 2013, pp. 3, 5
  3. 1 2 Porter, J.R., et al., Executive summary, in: Chapter 7: Food security and food production systems (archived 5 November 2014), in IPCC AR5 WG2 A 2014, pp. 488–489
  4. Paragraph 4, in: SUMMARY AND RECOMMENDATIONS, in: HLPE 2012, p. 12
  5. Section 4.2: Agriculture’s current contribution to greenhouse gas emissions, in: HLPE 2012, pp. 67–69
  6. Blanco, G., et al., Section 5.3.5.4: Agriculture, Forestry, Other Land Use, in: Chapter 5: Drivers, Trends and Mitigation (archived 30 December 2014), in: IPCC AR5 WG3 2014, p. 383. Emissions aggregated using 100-year global warming potentials from the IPCC Second Assessment Report.
  7. Porter, J.R., et al., Section 7.5: Adaptation and Managing Risks in Agriculture and Other Food System Activities, in Chapter 7: Food security and food production systems (archived 5 November 2014), in IPCC AR5 WG2 A 2014, pp. 513–520
  8. Oppenheimer, M., et al., Section 19.7. Assessment of Response Strategies to Manage Risks, in: Chapter 19: Emergent risks and key vulnerabilities (archived 5 November 2014), in IPCC AR5 WG2 A 2014, p. 1080
  9. SUMMARY AND RECOMMENDATIONS, in: HLPE 2012, pp. 12–23
  10. Current climate change policies are described in Annex I NC 2014 and Non-Annex I NC 2014
  11. Smith, P., et al., Executive summary, in: Chapter 5: Drivers, Trends and Mitigation (archived 30 December 2014), in: IPCC AR5 WG3 2014, pp. 816–817
  12.  This article incorporates public domain material from the US Global Change Research Program (USGCRP) document: Corn and Soybean Temperature Response "Archived copy". Archived from the original on 12 May 2013. Retrieved 30 May 2013. , in: Agriculture, in: Karl, T.R.; et al. (2009), Global Climate Change Impacts in the United States, Cambridge University Press, ISBN 978-0-521-14407-0
  13. "Climate 'could devastate crops'". BBC News. 31 January 2008.
  14. Lobell DB, Burke MB, Tebaldi C, Mastrandrea MD, Falcon WP, Naylor RL (2008). "Prioritizing climate change adaptation needs for food security in 2030". Science. 319 (5863): 607–10. doi:10.1126/science.1152339. PMID 18239122.
  15. Fraser, E (2007a). "Travelling in antique lands: Studying past famines to understand present vulnerabilities to climate change". Climate Change. 83 (4): 495–514. doi:10.1007/s10584-007-9240-9.
  16. 1 2 Simelton, E.; Fraser, E.; Termansen, M. (2009). "Typologies of crop-drought vulnerability: an empirical analysis of the socio-economic factors that influence the sensitivity and resilience to drought of three major food crops in China (1961–2001)". Environmental Science & Policy. 12 (4): 438–452. doi:10.1016/j.envsci.2008.11.005.
  17. Fraser, E.; Termansen, M.; Sun, N.; Guan, D.; Simelton, E.; Dodds, P.; Feng, K.; Yu, Y. (2008). "Quantifying socio economic characteristics of drought sensitive regions: evidence from Chinese provincial agricultural data". Comptes Rendus Geoscience. 340 (9–10): 679–688. doi:10.1016/j.crte.2008.07.004.
  18. Fraser, E. D. G.; Simelton, E.; Termansen, M.; Gosling, S. N.; South, A. (2013). "'Vulnerability hotspots': integrating socio-economic and hydrological models to identify where cereal production may decline due to climate change induced drought". Agricultural and Forest Meteorology. 170: 195–205. doi:10.1016/j.agrformet.2012.04.008.
  19. Harding, A. E.; Rivington, M.; Mineter, M. J.; Teff, S. F. B. (2015). "Agro-meteorological indices and climate model uncertainty over the UK". Climatic Change. 128 (1): 113–126. doi:10.1007/s10584-014-1296-8.
  20. Monier, E.; Xu, L.; Snyder, R. L. (2016). "Uncertainty in future agro-climate projections in the United States and benefits of greenhouse gas mitigation". Environmental Research Letters. 11 (5): 055001. doi:10.1088/1748-9326/11/5/055001.
  21. 1 2 "Global Warming Could Trigger Insect Population Boom". Live Science. Retrieved 2017-05-02.
  22. Stange, Erik (November 2010). "Climate Change Impact: Insects". Norwegian Institute for Nature Research.
  23. 1 2 3 4 "Crops, Beetles, and Carbon Dioxide:". Union of Concerned Scientists. Retrieved 2017-05-02.
  24. 1 2 "Agricultural Adaptation to Climate Change".
  25. Stange, Erik (November 2010). "Climate Change Impact: Insects". Norwegian Institute for Nature Research.
  26. 1 2 3 Coakley, Stella (1999). "Climate Change and Plant Disease Management". Phytopathol. 37: 399–426. doi:10.1146/annurev.phyto.37.1.399. PMID 11701829.
  27. 1 2 Rosenzweig, C (2007). "Executive summary". In ML Parry; et al. Chapter 1: Assessment of Observed Changes and Responses in Natural and Managed Systems. Climate change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge University Press (CUP): Cambridge, UK: Print version: CUP. This version: IPCC website. ISBN 978-0-521-88010-7. Retrieved 2011-06-25.
  28. Rosenzweig, C (2007). "1.3.6.1 Crops and livestock". In ML Parry; et al. Chapter 1: Assessment of Observed Changes and Responses in Natural and Managed Systems. Climate change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge University Press (CUP): Cambridge, UK: Print version: CUP. This version: IPCC website. ISBN 978-0-521-88010-7. Retrieved 2011-06-25.
  29. ML Parry; et al., eds. (2007). "Definition of "phenology"". Appendix I: Glossary. Climate change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge University Press (CUP): Cambridge, UK: Print version: CUP. This version: IPCC website. ISBN 978-0-521-88010-7. Retrieved 2011-06-25.
  30. Dai, A. (2011). "Drought under global warming: A review". Wiley Interdisciplinary Reviews: Climate Change. 2: 45–65. doi:10.1002/wcc.81.
  31. Mishra, A. K.; Singh, V. P. (2011). "Drought modeling – A review". Journal of Hydrology. 403: 157–175. doi:10.1016/j.jhydrol.2011.03.049.
  32. Ding, Y.; Hayes, M. J.; Widhalm, M. (2011). "Measuring economic impacts of drought: A review and discussion" (Submitted manuscript). Disaster Prevention and Management. 20 (4): 434–446. doi:10.1108/09653561111161752.
  33. institutt, NRK og Meteorologisk. "Weather statistics for Jalgaon". yr.no. Retrieved 2016-01-27.
  34. Damodaran, Harish. "The story of Jalgaon district in Maharashtra as the 'new' banana republic". Indian Express.
  35. "Climate Change Knowledge Portal 2.0". World Bank. Retrieved 2016-01-27.
  36. "FAOSTAT Agricultural production". Food and Agriculture Association of the United Nations. Archived from the original on 13 July 2011.
  37. "Crop production". Food and Agriculture Organization of the United Nations. Retrieved 2015-01-27.
  38. BERWYN, BOB (28 July 1018). "This Summer's Heat Waves Could Be the Strongest Climate Signal Yet" (Climate change). Inside Climate News. Retrieved 9 August 2018.
  39. Vidal, John; Stewart, Heather. "Heatwave devastates Europe's crops" (Climate Change). The Guardian. Retrieved 9 August 2018.
  40. Graziano da Silva, FAO Director-General José. "Conference Fortieth Session". Food and Agriculture Organization of the United Nations. Retrieved 9 August 2018.
  41. 1 2 Schneider, SH (2007). "19.3.1 Introduction to Table 19.1". In ML Parry; et al. Chapter 19: Assessing Key Vulnerabilities and the Risk from Climate Change. Climate change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge University Press (CUP): Cambridge, UK: Print version: CUP. This version: IPCC website. ISBN 978-0-521-88010-7. Retrieved 2011-05-04.
  42. 1 2 3 Parry, ML (2007). "Box TS.2. Communication of uncertainty in the Working Group II Fourth Assessment". In ML Parry; et al. Technical summary. Climate change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge University Press (CUP): Cambridge, UK: Print version: CUP. This version: IPCC website. ISBN 978-0-521-88010-7. Retrieved 2011-05-04.
  43. Schneider, SH (2007). "19.3.2.1 Agriculture". In ML Parry; et al. Chapter 19: Assessing Key Vulnerabilities and the Risk from Climate Change. Climate change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge University Press (CUP): Cambridge, UK: Print version: CUP. This version: IPCC website. p. 790. ISBN 978-0-521-88010-7. Retrieved 2011-05-04.
  44. 1 2 3 4 Figure 5.1, p.161, in: Sec 5.1 FOOD PRODUCTION, PRICES, AND HUNGER, in: Ch 5: Impacts in the Next Few Decades and Coming Centuries, in: US NRC 2011
  45. 1 2 Sec 5.1 FOOD PRODUCTION, PRICES, AND HUNGER, pp.160-162, in: Ch 5: Impacts in the Next Few Decades and Coming Centuries, in US NRC 2011
  46. Smith, Matthew R.; Myers, Samuel S. (2018-08-27). "Impact of anthropogenic CO2 emissions on global human nutrition". Nature Climate Change. 8 (9): 834–839. doi:10.1038/s41558-018-0253-3. ISSN 1758-678X.
  47. Davis, Nicola (2018-08-27). "Climate change will make hundreds of millions more people nutrient deficient". the Guardian. Retrieved 2018-08-29.
  48. 1 2 Easterling, WE (2007). "5.6.5 Food security and vulnerability". In ML Parry; et al. Chapter 5: Food, Fibre, and Forest Products. Climate change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge University Press. ISBN 978-0-521-88010-7.
  49. 1 2 3 Easterling, WE (2007). "Executive summary". In ML Parry; et al. Chapter 5: Food, Fibre, and Forest Products. Climate change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge University Press. ISBN 978-0-521-88010-7.
  50. "World hunger increasing". Food and Agriculture Organization (FAO) Newsroom. 30 October 2006. Retrieved 2011-07-07.
  51. Howden, M. e. (2007). Adapting Agriculture to Climate Change. Proceedings of the National Academy of Sciences of the United States of America 104/50, 19691-19696
  52. 1 2 Cline 2008
  53. Lobell & others 2008a (paywall). Lobell & others 2008b can be freely accessed.
  54. 1 2 Battisti & Naylor 2009
  55. Ending hunger will require trade policy reform, Press Release, International Centre for Trade and Sustainable Development, 12 October 2009.
  56. Climate change, agriculture and aid for trade, by Jodie Keane, ICTSD-IPC
  57. 1 2 3 4 IPCC (2007). "Summary for Policymakers: C. Current knowledge about future impacts". Climate Change 2007: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change [M.L. Parry et al. (eds.)]. Cambridge University Press.
  58. John Vidal (30 June 2005). "In the land where life is on hold". The Guardian. UK. Retrieved 2008-01-22.
  59. Vulnerability to Climate Change: Adaptation Strategies and layers of Resilience, ICRISAT, Policy Brief No. 23, February 2013
  60. Meng, Q.; Hou, P.; Lobell, D. B.; Wang, H.; Cui, Z.; Zhang, F.; Chen, X. (2013). "The benefits of recent warming for maize production in high latitude China". Climatic Change. 122: 341–349. doi:10.1007/s10584-013-1009-8.
  61. Chowdhury, Q M Monzur Kader (2016). "IMPACT OF CLIMATE CHANGE ON LIVESTOCK IN BANGLADESH: A REVIEW OF WHAT WE KNOW AND WHAT WE NEED TO KNOW" (PDF). American Journal of Agricultural Science Engineering and Technology. 3 (2): 18–25 via e-palli.
  62. 1 2 Hennessy, K.; et al. (2007). "Chapter 11: Australia and New Zealand: Executive summary". In M.L. Parry et al. Climate Change 2007: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press.
  63. 1 2 3 4 5 6 7 JONES, P; THORNTON, P (April 2003). "The potential impacts of climate change on maize production in Africa and Latin America in 2055". Global Environmental Change. 13 (1): 51–59. doi:10.1016/S0959-3780(02)00090-0.
  64. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Baethgen, WE (1997). "Vulnerability of the agricultural sector of Latin America to climate change". Climate Research. 9: 1–7. doi:10.3354/cr009001.
  65. 1 2 3 Mendelsohn, R.; Dinar, A. (1 August 1999). "Climate Change, Agriculture, and Developing Countries: Does Adaptation Matter?". The World Bank Research Observer. 14 (2): 277–293. doi:10.1093/wbro/14.2.277.
  66. 1 2 3 4 5 Morton, J. F. (6 December 2007). "The impact of climate change on smallholder and subsistence agriculture". Proceedings of the National Academy of Sciences. 104 (50): 19680–19685. doi:10.1073/pnas.0701855104. PMC 2148357. PMID 18077400.
  67. Timmons Roberts, J. (2009). "The International Dimension of Climate Justice and the Need for International Adaptation Funding". Environmental Justice. 2 (4): 185–190. doi:10.1089/env.2009.0029.
  68. 1 2 3 4 5 Davies, Mark; Guenther, Bruce; Leavy, Jennifer; Mitchell, Tom; Tanner, Thomas. "Climate Change Adaptation, Disaster Risk Reduction and Social Protection: Complementary Roles in Agriculture and Rural Growth?". IDS Working Papers. 2009 (320): 01–37. doi:10.1111/j.2040-0209.2009.00320_2 (inactive 2018-09-11).
  69. 1 2 al.], edited by W. Neil Adger, Jouni Paavola, Saleemul Huq... [et (2006). Fairness in adaptation to climate change ([Online-Ausg.] ed.). Cambridge, Mass.: MIT Press. ISBN 978-0-262-01227-0.
  70. Field, C.B.; et al. (2007). "Sec. 14.4.4 Agriculture, forestry and fisheries". In ML Parry. Chapter 14: North America. Climate change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge University Press. ISBN 978-0-521-88010-7.
  71. Smith, Adam. "Billion-Dollar Weather and Climate Disasters: Table of Events - National Centers for Environmental Information (NCEI)".
  72. Perry, Laura G.; Andersen, Douglas C.; Reynolds, Lindsay V.; Nelson, S. Mark; Shafroth, Patrick B. (2012). "Vulnerability of riparian ecosystems to elevated CO2 and climate change in arid and semiarid western North America" (PDF). Global Change Biology. 18 (3): 821–842. doi:10.1111/j.1365-2486.2011.02588.x. Archived from the original (PDF) on 26 May 2013.
  73. USGCRP (2009). "Agriculture". In Karl, T.R.; Melillo. J.; Peterson, T.; Hassol, S.J. Global Climate Change Impacts in the United States. Cambridge University Press. ISBN 978-0-521-14407-0.
  74. Anisimov, O.A.; et al. (2007). "Chapter 15: Polar regions (Arctic and Antarctic): Executive summary". In M.L. Parry et al. Climate Change 2007: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press.
  75. Paul Brown (30 June 2005). "Frozen assets". The Guardian. Retrieved 2008-01-22.
  76. Mimura, N.; et al. (2007). "Chapter 16: Small islands: Executive summary". In M.L. Parry et al. Climate Change 2007: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press.
  77. 1 2 "Climate change, agricultural policy and poverty reduction – how much do we know?". Overseas Development Institute. 2007. Retrieved 2007. Check date values in: |accessdate= (help)
  78. IPCC. 2007. Climate Change 2007: Synthesis Report. Contributions of Working Groups I, Ii, and Iiito the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Geneva: IPCC
  79. Basak R. 2016. Benefits and costs of climate change mitigation technologies in paddy rice: Focus on Bangladesh and Vietnam. CCAFS Working Paper no. 160. Copenhagen, Denmark: CGIAR Research Program on Climate Change, Agriculture and Food Security (CCAFS). http://cgspace.cgiar.org/rest/bitstreams/79059/retrieve
  80. "Agricultural Technologies for Climate Change Mitigation and Adaptation in Developing Countries:Policy Options for Innovation and Technology Diffusion" (PDF). International Centre for Trade and Sustainable Development. May 2010. Retrieved 23 October 2011.
  81. "Agricultural Model Intercomparison and Improvement Project: Phase I Activities by a Global Community of Science". Imperial College Press/ World Scientific Publishing. April 2015.
  82. F. Woodward; C. Kelly (1995). "The influence of CO2 concentration on stomatal density". New Phytologist. 131 (3): 311–327. doi:10.1111/j.1469-8137.1995.tb03067.x.
  83. Bert G. Drake; Gonzalez-Meler, Miquel A.; Long, Steve P. (1997). "More efficient plants: A Consequence of Rising Atmospheric CO2?". Annual Review of Plant Physiology and Plant Molecular Biology. 48 (1): 609–639. doi:10.1146/annurev.arplant.48.1.609. PMID 15012276.
  84. Sun, Y.; Gu, L.; Dickinson, R. E.; Norby, R. J.; Pallardy, S. G.; Hoffman, F. M. (13 October 2014). "Impact of mesophyll diffusion on estimated global land CO2 fertilization". Proceedings of the National Academy of Sciences. 111 (44): 15774–15779. doi:10.1073/pnas.1418075111. PMC 4226101. PMID 25313079.
  85. Royal Society (2005) [Impact of climate change on crops worse than previously thought http://royalsociety.org/General_WF.aspx?pageid=7317&terms= Impact of climate change on crops worse than previously thought] archived
  86. Dietterich; et al. (2015). "Impacts of elevated atmospheric CO2 on nutrient content of important food crops". Nature. 2: 150036. doi:10.1038/sdata.2015.36. PMC 4508823. PMID 26217490.
  87. "Climate Change 2001: Working Group II: Impacts, Adaptation and Vulnerability" Archived 5 August 2009 at the Wayback Machine. IPCC
  88. Loladze, I (2002). "Rising atmospheric CO2 and human nutrition: toward globally imbalanced plant stoichiometry?". Trends in Ecology & Evolution. 17 (10): 457–461. doi:10.1016/S0169-5347(02)02587-9.
  89. Zhu, C.; Kobayashi, K.; Loladze, I.; Zhu, J.; Jiang, Q.; Xu, X.; Liu, G.; Seneweera, S.; Ebi, K. L.; Drewnowski, A.; Fukagawa, N. K.; Ziska, L. H. (23 May 2018). "Carbon dioxide (CO2) levels this century will alter the protein, micronutrients, and vitamin content of rice grains with potential health consequences for the poorest rice-dependent countries". Science Advances. 4 (5): eaaq1012. doi:10.1126/sciadv.aaq1012. PMC 5966189. PMID 29806023. Retrieved July 2, 2018.
  90. Susan Milius (May 23, 2018). "As CO2 increases, rice loses B vitamins and other nutrients". Sciencenews.org. Retrieved July 2, 2018.
  91. Carlos E. Coviella; John T. Trumble (1999). "Effects of Elevated Atmospheric Carbon Dioxide on Insect-Plant Interactions". Conservation Biology. 13 (4): 700–712. doi:10.1046/j.1523-1739.1999.98267.x. JSTOR 2641685.
  92. 1 2 The Food, the Bad, and the Ugly Scherer, Glenn Grist July, 2005
  93. Plague of plenty New Scientist Archive
  94. "Climate Change and Irish Agriculture" (PDF).
  95. German Research Indicates Warming in Siberia, Global Warming Today, Global Warming Today
  96. Federal Service for Hydrometeorology and Environmental Monitoring 5Roshydromet), Strategic Forecast of Climate Change in the Russian Federation 2010–2015 and Its Impact on Sectors of the Russian Economy (Moscow 2005)
  97. The Danger of Climate Change for Russia – Expected Losses and Recommendations, By Alexey O. Kokorin and Inna G. Gritsevich, Moscow, russian analytical digest 23/07
  98. Global warming 'will hurt Russia', 14:23 03 October 2003, NewScientist.com news service
  99. "Coping With Climate Change." Rice Today, IRRI. July–Sept (2007): 10–15. "Archived copy" (PDF). Archived from the original (PDF) on 27 March 2009. Retrieved 2009-10-07.
  100. Doetterl, Sebastian; Oost, Kristof Van; Six, Johan (2012-05-01). "Towards constraining the magnitude of global agricultural sediment and soil organic carbon fluxes". Earth Surface Processes and Landforms. 37 (6): 642–655. doi:10.1002/esp.3198. hdl:2078.1/123112. ISSN 1096-9837.
  101. "Early Summer Weed Control" (PDF). -.
  102. Big melt threatens millions, says UN Archived 19 February 2008 at the Wayback Machine.
  103. "People's Daily Online - Glaciers melting at alarming speed".
  104. "Ganges, Indus may not survive: climatologists".
  105. "Himalaya glaciers melt unnoticed". 10 November 2004 via bbc.co.uk.
  106. Glaciers Are Melting Faster Than Expected, UN Reports
  107. Ozone layer least fragile on record Brown, Paul The Guardian April 2005
  108. Dead link: "Archived copy". Archived from the original on 27 June 2005. Retrieved 2009-10-07.
  109. IPCC. Climate Change 2007: Synthesis Report. United Nations Environment Programme, 2007:Ch5, 8, and 10.
  110. Battisti, David S. et al. "Assessing risks of climate variability and climate change for Indonesian rice agriculture." Proceedings of the National Academy of Sciences of the United States of America. No.19 (2007): 7752–7757.
  111. Food and Agriculture Organization of the UN Archived 25 June 2008 at the Wayback Machine. retrieved 25 June 2007
  112. Intergovernmental Panel on Climate Change Archived 1 May 2007 at the Wayback Machine. (IPCC)
  113. Intergovernmental Panel on Climate Change Special Report on Emissions Scenarios retrieved 26 June 2007
  114. "Intergovernmental Panel on Climate Change" (PDF).
  115. IPCC Technical Summary retrieved 25 June 2007
  116. 1 2 3 Steinfeld, Henning; Gerber, Pierre; Wassenaar, T. D.; Castel, Vincent; Haan, Cees de (1 January 2006). Livestock's Long Shadow: Environmental Issues and Options (PDF). Food & Agriculture Org. ISBN 9789251055717. Archived from the original on 25 June 2008 via Google Books. ,
  117. Food and Agriculture Organization of the United Nations (2013) "FAO STATISTICAL YEARBOOK 2013 World Food and Agriculture". See data in Table 49.
  118. Ripple, William J.; Pete Smith; Helmut Haberl; Stephen A. Montzka; Clive McAlpine & Douglas H. Boucher. 2014. "Ruminants, climate change and climate policy". Nature Climate Change. Volume 4 No. 1. P 2-5.
  119. Cicerone, R. J., and R. S. Oremland. 1988 "Biogeochemical Aspects of Atmospheric Methane"
  120. Yavitt, J. B. 1992. Methane, biogeochemical cycle. Pages 197–207 in Encyclopedia of Earth System Science, Vol. 3. Acad.Press, London, England.

References

  • Annex I NC (24 October 2014), 6th national communications (NC6) from Parties included in Annex I to the Convention including those that are also Parties to the Kyoto Protocol, United Nations Framework Convention on Climate Change, Archived from the original on 2 August 2014 . Archived
  • Battisti, David; Naylor (2009), "Historical warnings of future food insecurity with unprecedented seasonal heat", Science, 323 (5911): 240–4, doi:10.1126/science.1164363, PMID 19131626, retrieved 13 April 2012 .
  • Cline, W.R. (March 2008), "Global Warming and Agriculture", Finance and Development, 45 (1), Archived from the original on 17 August 2014 . Archived
  • HLPE (June 2012), Food security and climate change. A report by the High Level Panel of Experts (HLPE) on Food Security and Nutrition of the Committee on World Food Security, Rome, Italy: Food and Agriculture Organization of the United Nations, Archived from the original on 12 December 2014 . Archived .
  • Hoffmann, U., ed. (2013), Trade and Environment Review 2013: Wake up before it is too late: Make agriculture truly sustainable now for food security in a changing climate, Geneva, Switzerland: United Nations Conference on Trade and Development (UNCTAD), ISSN 1810-5432, Archived from the original on 28 November 2014 . Archived .
  • IPCC AR5 WG2 A (2014), Field, C.B.; et al., eds., Climate Change 2014: Impacts, Adaptation, and Vulnerability. Part A: Global and Sectoral Aspects. Contribution of Working Group II (WG2) to the Fifth Assessment Report (AR5) of the Intergovernmental Panel on Climate Change (IPCC), Cambridge University Press . Also available at IPCC Working Group 2. Archives: Main IPCC website: 16 December 2014; IPCC WG2: 5 November 2014.
  • IPCC AR5 WG3 (2014), Edenhofer, O.; et al., eds., Climate Change 2014: Mitigation of Climate Change. Contribution of Working Group III (WG3) to the Fifth Assessment Report (AR5) of the Intergovernmental Panel on Climate Change (IPCC), Cambridge University Press, archived from the original on 27 November 2014 . Also available at mitigation2014.org. Archives: Main IPCC website: 27 November 2014; mitigation2014.org: 30 December 2014.
  • Lobell, David; Burke, Tebaldi, Mastrandrea, Falcon, Naylor (2008a), "Prioritizing climate change adaptation needs for food security in 2030", Science, 319 (5863): 607–10, doi:10.1126/science.1152339, PMID 18239122, retrieved 13 April 2012 .
  • Lobell, D.; et al. (2008b), Prioritizing climate change adaptation needs for food security - Policy Brief, Center on Food Security and the Environment, Stanford University . Archived 27 September 2014.
  • Non-Annex I NC (11 December 2014), Non-Annex I national communications, United Nations Framework Convention on Climate Change, Archived from the original on 13 September 2014 . Archived .
  • US NRC (2011), Climate Stabilization Targets: Emissions, Concentrations, and Impacts over Decades to Millennia, Washington, D.C., USA: National Academies Press, archived from the original on 27 March 2014
  • “4) Differences between agricultural and forest land.” Rainforest Conservation Fund, www.rainforestconservation.org/rainforest-primer/7-special-topics/b-agriculture/4-differences-between-agricultural-and-forest-land/.
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