Effect Of agriculture On climate change

Effect of Agriculture on Climate change

Edited By Irshad Anwar | Updated on Jul 02, 2025 05:13 PM IST

Climate change has adverse impacts on agriculture that include crop yields disruption interference in water supply, and health or land degrading. Agricultural activities are the contributors to this factor through greenhouse gas emissions due to deforestation, cattle, and fertilizers. Rising temperatures and erratic monsoons often threaten India's major crops such as wheat and rice. This topic of Biology is part of the chapter of Class 12 on Environmental Issues, which is especially important for competitive entrance exams such as NEET, AIIMS, nursing and paramedical exams.

This Story also Contains

How Agricultural Activities Contribute to Climate Change
Agriculture's Impact on Climate Change in India
Climatic Change Impact on Agriculture
Impact Of Climate Change On Agriculture In India
How to Reduce the Impact of Climate Change on Agriculture
Tips, Tricks, and Strategies to Prepare for Agriculture's Impact on Climate Change
Weightage of Questions from Agriculture's Impact on Climate Change in Different Exams
Types of Questions asked on Agriculture's Impact on Climate Change in different Exams

How Agricultural Activities Contribute to Climate Change

Some of the greenhouse gas emissions from agriculture are among the leading causes of global warming. They trap heat in the atmosphere. These include:

Methane emissions from enteric fermentation of livestock, ruminants such as cattle and sheep
Production of methane from waterlogged rice cultivation
Nitrous oxide, a very potent GHG, released as fertilizer is used
Cuts down carbon-absorbing forests due to the deforestation of farmland.
Fossil fuel use in mechanical farming, transport, and irrigation
Production of pesticides and fertilizers

Agriculture contributes to 10–12% of the global inputs of greenhouse gases; however, when indirect impacts of deforestation are added to it the total input may add up to even higher.

Also Read:

Agriculture's Impact on Climate Change in India

More than half the country's population of India presently lives off agriculture as a source of livelihood.
Agriculture forms a major share of greenhouse gas emissions from the country, primarily through rice paddies; mainly by releasing methane end.
Livestock farming (methane from enteric fermentation)
Burning crop residues, like stubble burning in Punjab and Haryana, then emit carbon dioxide and particulate matter into the environment.

NEET Highest Scoring Chapters & Topics

Know Most Scoring Concepts in NEET 2024 Based on Previous Year Analysis.

Know More

Table: Sources of Agricultural Greenhouse Gas Emissions in India

Source	Contribution to Emissions
Livestock (Methane)	32%
Rice Cultivation	24%
Crop Residue Burning	15%
Fertilizer Use	20%
Other	9%

Climatic Change Impact on Agriculture

The impact of climate change on agriculture is described below:

Increased Temperatures

Higher global temperatures cause heat stress to crops, thus lowering their productivity. For instance:

The yield of wheat and maize would decrease by 10–20% for each rise in temperature by 1°C.
Even the quality of grains, fruits, and vegetables will degrade, and their nutritional values will also be impacted due to high heat.

Altered Pattern of Rainfall

Monsoon is extremely crucial for Indian agriculture; however, erratic monsoon rain forms due to climate change, which leads to:

Droughts in certain regions of the world, cause water shortages and crop failures.
Flooding in another region creates soil erosion and damage to crops.
Reduced supply of irrigation water as a result of water shortage.

Soil Degradation And Desertification

Climate change accelerates soil degradation in several ways:

High temperatures lead to increased evaporation that dries soils
Heavy rains during such extreme climatic events can strip away fertile topsoils
Increased drought spells lead to desertification in vulnerable parts of the globe

Impact Of Climate Change On Agriculture In India

India is a monsoon-dependent country and thus highly vulnerable to climatic change. Major impacts would include the following:

Yields of staple foods, rice and wheat, are likely to have substantially reduced yields.
The availability of water for irrigation will no longer be predictable, and regions like Punjab and Haryana will suffer from water stress.
Destructive cyclones, droughts, and floods are causing extreme climatic conditions in the states of Maharashtra, Odisha, and West Bengal and damaging crops.

How to Reduce the Impact of Climate Change on Agriculture

Reducing climate change's impact on agriculture is crucial for sustainable food production and involves adopting practices that enhance resilience and minimize environmental harm.

Sustainable Farming Practices

Sustainable farming has a tendency to minimize the effects of agriculture on climate change immensely. These include;

Organic farming: Minimum use of synthetic fertilizers and pesticides; that is likely to minimize the emission of nitrous oxide.
Agroforestry: Planting trees on agricultural land in order to sequester carbon and prevent soil erosion.
Conservation tillage: Minimization of soil disturbance preserves the soil structure, consequently reducing carbon release into the atmosphere.

Better Water Management

Water conservation through efficient irrigation systems that minimize stress during droughts. Techniques include:

Drip irrigation: Releases water directly to the plant roots, thereby reducing water evaporation
Harvesting rainwater: Collected rainwater for dry use

Reduction of Emission of Methane by Livestock

Several methods of reducing methane emission:

Livestock diet improvement: Livestock with better food quality yields a lower release of methane while digesting.
Chemical controls of methane: Use of feeding elements that can inhibit production within the ruminating animals

Crop Rotation and Diversification

Crop rotation and agricultural diversity on a site enhance soil productivity and minimize pest incidence, and subsequently pesticide application.

Afforestation and Reforestation

Reforestation revives biodiversity and tackles the direct consequences of historical deforestation for agricultural purposes.

Government Programs and Policies

In India, government programs have established some of the following initiatives:

The National Mission for Sustainable Agriculture, NMSA features sustainability in farming.
The Pradhan Mantri Krishi Sinchayee Yojana (PMKSY): It focuses on the improvement of agricultural water use efficiency.

Tips, Tricks, and Strategies to Prepare for Agriculture's Impact on Climate Change

Study Aids: Find diagrams or flowcharts that could identify how human practices related to agriculture could be linked to climate change, perhaps focusing on details such as greenhouse gas emissions and deforestation.
Mnemonics: Use a mnemonic like "CROP" - Carbon, Resources, Overuse, Practices to remember what aspects of agriculture contribute to climate change
Multimedia: Find videos or animations that describe how climate change might affect agriculture, with examples of lower yields and changed agricultural practices.
Real-Life Connection: Associate agricultural activities, for instance, overuse of fertilizers with real-life consequences, such as water pollution and changes in weather conditions.
Flashcards: Flashcards can be used to memorize words like "sustainable agriculture," "soil erosion," and "carbon sequestration," and check how well you understand their relevance to climate change.

Weightage of Questions from Agriculture's Impact on Climate Change in Different Exams

Exam Type	Weightage of Agriculture's Impact on Climate Change
CBSE Board Exams	5-7%
NEET	2-3%
Nursing Entrance Exams	3-5%
Paramedical Entrance Exams	2-4%

Types of Questions asked on Agriculture's Impact on Climate Change in different Exams

Exam Type	Types of Questions
CBSE Board Exams	Definitions and concepts related to agriculture and climate change Examples of agricultural practices affecting climate change Short answer questions on mitigation strategies
NEET	MCQs on greenhouse gas emissions and their sources in agriculture Assertion and reason questions related to sustainable practices Long answer questions on the impact of climate change on crop yield
Nursing Entrance Exams	True/False questions on agricultural practices and their environmental effects Scenario-based questions on health impacts related to climate change in agriculture
Paramedical Entrance Exams	Questions on the relationship between agriculture and climate change Case studies on the effects of climate change on agricultural health and sustainability

Conclusion

Agriculture is an industry that contributes to climate change. Agriculture contributes to greenhouse gas emissions in many ways. One of the most important ways agriculture contributes to climate change is through fertilisers. This fertilizer contains nitrates that do not exist in nature, and when these nitrates break down, methane gas is released into the atmosphere. Sectors such as meat, dairy, and poultry contribute most of the world's greenhouse gases, accounting for about one-third of anthropogenic greenhouse gas emissions. Agriculture is one way to reduce carbon emissions while meeting ever-increasing demand. One strategy for doing this is to change the focus of cattle production to include the development of larger crops.

Also Read:

Biodegradable and Non Biodegradable Substances	Biochemical Oxygen Demand
Air Water and Soil Pollution	Air Pollution Control
Difference between Renewable and Non-Renewable Sources	Ozone Layer Depletion

Frequently Asked Questions (FAQs)

1. How does agriculture contribute to climate change?

The primary ways agriculture contributes to climate change are greenhouse gas emissions stemming from livestock and rice paddies, methane, and fertilizers, resulting in nitrous oxide. Furthermore, clearing forests for agricultural space plays a critical role in the global problem through the reduction of carbon sequestration.

2. What are the effects of climate change on agriculture?

Climate changes lead to unpredictable weather. With increased droughts and floods, crop yields and food security suffer. High temperatures also reduce crop quality and increase pest infestations.

3. What are sustainable agricultural practices to mitigate climate change?

Some of the sustainable practices include crop rotation, agroforestry, organic farming, and efficient water management. They do so by improving soil health, reducing emissions, and making agricultural systems more resilient to climate variability.

4. How does climate change impact food security?

Climate change threatens food security through its impacts on agricultural production and access to water resources. That could push up prices and raise the vulnerability of large populations that depend on agriculture for their livelihoods.

5. How to reduce the impact of climate change on agriculture?

Crop rotation, improved irrigation techniques, and climate-resilient crop varieties are some of the sustainable practices that farmers can use to limit adverse effects on agriculture concerning climate change. Agroforestry and enhancing soil health by organic amendments also help increase resilience to climate variability.

6. What are 10 causes of climate change?

The 10 causes of climate change are:

Emissions
Deforestation
Industry
Agriculture
Waste
Transportation
Land-use
Degradation
Extraction
Pollution

7. How do rice paddies contribute to methane emissions?

Rice paddies contribute to methane emissions through a process called anaerobic decomposition. When rice fields are flooded, the underwater soil becomes oxygen-deprived. In these conditions, certain microorganisms break down organic matter and produce methane as a byproduct. This methane then bubbles up through the water and is released into the atmosphere.

8. How does soil degradation from intensive agriculture affect climate change?

Soil degradation from intensive agriculture affects climate change by: 1) Releasing stored carbon from soil into the atmosphere. 2) Reducing the soil's capacity to sequester carbon. 3) Decreasing plant productivity, which lowers CO2 absorption. 4) Increasing the need for fertilizers, leading to more N2O emissions.

9. How does the use of pesticides in agriculture indirectly contribute to climate change?

Pesticides indirectly contribute to climate change in several ways: 1) Their production is energy-intensive, leading to CO2 emissions. 2) They can reduce soil biodiversity, affecting the soil's ability to store carbon. 3) Some pesticides can inhibit soil microorganisms that play a role in natural nitrogen fixation, potentially increasing the need for synthetic fertilizers. 4) Pesticide runoff can harm aquatic ecosystems, which play a role in carbon sequestration.

10. How do different irrigation methods impact greenhouse gas emissions?

Different irrigation methods impact greenhouse gas emissions in various ways: 1) Flood irrigation can lead to higher methane emissions, especially in rice cultivation. 2) Sprinkler systems may have higher energy requirements, leading to more CO2 emissions. 3) Drip irrigation is generally more efficient, reducing water use and associated emissions. The choice of irrigation method also affects soil moisture, which influences N2O emissions from fertilized soils.

11. How do agricultural subsidies influence farming practices and their impact on climate change?

Agricultural subsidies can significantly influence farming practices and their climate impact. Subsidies that encourage overproduction or support emission-intensive practices (like those for certain livestock or crops) can exacerbate agriculture's climate impact. Conversely, subsidies for sustainable practices or climate-smart agriculture can promote more environmentally friendly farming methods. The structure of subsidy systems can thus play a crucial role in either mitigating or contributing to climate change.

12. What is the relationship between agriculture and the water cycle in the context of climate change?

Agriculture and the water cycle are closely linked in the context of climate change. Agricultural practices like irrigation can alter local water cycles by increasing evaporation and changing precipitation patterns. Conversely, climate change affects water availability for agriculture through altered rainfall patterns and increased drought frequency. This relationship creates a feedback loop that can exacerbate climate impacts.

13. How does the use of greenhouses in agriculture relate to climate change?

Greenhouses in agriculture relate to climate change in complex ways: 1) They can increase energy use for heating, lighting, and cooling, potentially increasing emissions. 2) However, they can also improve resource use efficiency, reducing water and fertilizer needs. 3) Greenhouses can extend growing seasons and allow cultivation in non-traditional

14. What is the concept of "virtual water" in agriculture and how does it relate to climate change?

"Virtual water" refers to the water used in the production of a good or service, particularly in agriculture. It relates to climate change because water-intensive crops grown in water-scarce regions can lead to unsustainable water use, potentially exacerbating climate impacts. Additionally, the transportation of water-intensive products from water-rich to water-poor areas (instead of producing locally) can increase transportation-related emissions. Understanding virtual water can help in making more climate-friendly agricultural and trade decisions.

15. How does agriculture contribute to greenhouse gas emissions?

Agriculture contributes to greenhouse gas emissions in several ways: 1) Carbon dioxide (CO2) is released when forests are cleared for farmland. 2) Methane (CH4) is produced by livestock digestion and manure management. 3) Nitrous oxide (N2O) is emitted from fertilized soils and manure. These gases trap heat in the atmosphere, leading to global warming.

16. What role do fertilizers play in agricultural greenhouse gas emissions?

Fertilizers contribute to greenhouse gas emissions in two main ways: 1) The production of synthetic fertilizers is energy-intensive, releasing CO2. 2) When applied to soil, fertilizers can lead to increased emissions of nitrous oxide (N2O), a potent greenhouse gas. Excess nitrogen not used by plants can be converted to N2O by soil microbes.

17. How does livestock farming contribute to methane emissions?

Livestock farming contributes to methane emissions primarily through: 1) Enteric fermentation - the digestive process in ruminant animals like cattle and sheep, which produces methane as a byproduct. 2) Manure management - the decomposition of animal waste in anaerobic conditions, such as in large manure lagoons, produces methane.

18. How does deforestation for agriculture impact climate change?

Deforestation for agriculture significantly impacts climate change by: 1) Releasing stored carbon from trees and soil into the atmosphere as CO2. 2) Reducing the Earth's capacity to absorb CO2 through photosynthesis. 3) Altering local and regional weather patterns. 4) Decreasing biodiversity, which can affect ecosystem resilience to climate change.

19. What is the "albedo effect" and how does agriculture influence it?

The albedo effect refers to the ability of Earth's surface to reflect sunlight. Agriculture influences this by changing land cover. For example, deforestation for cropland can increase albedo (more reflection) in some areas, while irrigation can decrease it (less reflection). These changes can affect local and regional climate patterns.

20. What is the concept of "carbon sequestration" in agriculture?

Carbon sequestration in agriculture refers to the process of capturing and storing atmospheric carbon dioxide in soil, plants, and other organic matter. This can be achieved through practices like no-till farming, cover cropping, and agroforestry. By increasing soil organic matter, these methods can help mitigate climate change by removing CO2 from the atmosphere.

21. How can changing dietary habits impact agricultural emissions?

Changing dietary habits can significantly impact agricultural emissions by: 1) Reducing consumption of high-emission foods like beef and dairy. 2) Increasing consumption of plant-based proteins and locally sourced foods. 3) Minimizing food waste. These changes can lead to reduced demand for emission-intensive agricultural practices and products.

22. What is the concept of "food miles" and how does it relate to climate change?

"Food miles" refers to the distance food travels from where it's produced to where it's consumed. This concept relates to climate change because longer transportation distances typically result in higher greenhouse gas emissions from vehicles. However, it's important to note that transportation is often a smaller factor in food's overall carbon footprint compared to production methods.

23. What is the concept of "climate-smart agriculture"?

Climate-smart agriculture is an approach that aims to transform agricultural systems to support food security under climate change. It focuses on three main objectives: 1) Sustainably increasing agricultural productivity and incomes. 2) Adapting and building resilience to climate change. 3) Reducing and/or removing greenhouse gas emissions where possible.

24. What is "agroforestry" and how can it help mitigate climate change?

Agroforestry is a land use management system where trees or shrubs are grown around or among crops or pastureland. It can help mitigate climate change by: 1) Increasing carbon sequestration in biomass and soil. 2) Reducing soil erosion and improving soil health. 3) Providing shade and windbreaks, reducing the need for energy-intensive cooling or heating. 4) Diversifying farm income, making agricultural systems more resilient to climate impacts.

25. How does climate change impact crop yields, and how does this create a feedback loop?

Climate change impacts crop yields through altered temperature and precipitation patterns, extreme weather events, and changes in pest and disease prevalence. This can lead to reduced yields in many regions. The feedback loop occurs when farmers respond by expanding agricultural land (often through deforestation) or intensifying production with more fertilizers and pesticides, which in turn contributes to further climate change.

26. How does climate change affect the nutritional content of crops, and what are the implications?

Climate change can affect crop nutritional content through: 1) Increased CO2 levels, which can reduce protein and mineral content in some crops. 2) Heat stress, which can alter plant metabolism and nutrient uptake. 3) Changes in water availability, affecting nutrient transport in plants. The implications include potential nutrient deficiencies in human and animal diets, which could lead to increased demand for diverse or fortified foods, potentially changing agricultural practices and emissions.

27. How does the loss of agricultural biodiversity contribute to climate change vulnerability?

Loss of agricultural biodiversity contributes to climate change vulnerability by: 1) Reducing genetic diversity, which limits options for breeding climate-resilient crops. 2) Creating monocultures that are more susceptible to pests and diseases, potentially leading to crop failures. 3) Decreasing the resilience of agricultural ecosystems to extreme weather events. 4) Limiting dietary diversity, which can impact food security in the face of changing growing conditions.

28. What is the concept of "carbon farming" and how does it relate to climate change mitigation?

Carbon farming refers to agricultural practices specifically designed to sequester carbon in soil and plant material. These practices include no-till farming, cover cropping, composting, and managed grazing. By increasing the amount of carbon stored in agricultural landscapes, carbon farming aims to mitigate climate change by removing CO2 from the atmosphere while also improving soil health and agricultural resilience.

29. How does the timing of planting and harvesting affect agricultural greenhouse gas emissions?

The timing of planting and harvesting can affect greenhouse gas emissions in several ways: 1) Proper timing can optimize crop growth, reducing the need for inputs like fertilizers. 2) It can affect soil moisture levels, influencing N2O emissions. 3) Timing can impact the amount of crop residue left on fields, affecting soil carbon storage. 4) In multiple cropping systems, timing determines fallow periods, which can influence soil emissions. Adapting planting and harvesting times to changing climate patterns can also help maintain yields without increasing inputs and associated emissions.

30. What is "precision agriculture" and how can it contribute to reducing agricultural emissions?

Precision agriculture is an approach that uses technology to optimize crop production by precisely managing inputs like water, fertilizers, and pesticides. It can reduce agricultural emissions by: 1) Minimizing over-application of fertilizers, reducing N2O emissions. 2) Improving irrigation efficiency, reducing water use and associated energy emissions. 3) Optimizing fuel use in farm machinery through GPS-guided systems. 4) Enabling variable rate application of inputs based on field conditions, reducing overall use and associated emissions.

31. What is the role of genetically modified organisms (GMOs) in the context of agriculture and climate change?

GMOs play a complex role in agriculture and climate change. They can potentially reduce emissions by: 1) Increasing crop yields, reducing the need for land expansion. 2) Enhancing pest resistance, reducing pesticide use. 3) Improving drought tolerance, reducing water use. However, concerns exist about their long-term ecological impacts and the intensive farming practices often associated with GMO cultivation, which may contribute to soil degradation and biodiversity loss.

32. How do different types of animal feed impact livestock's contribution to climate change?

Different types of animal feed can significantly impact livestock's contribution to climate change: 1) Grain-based feeds often have a higher carbon footprint due to the emissions associated with crop production and processing. 2) Grass-fed systems can potentially sequester more carbon in pasture soils but may lead to higher methane emissions from ruminant digestion. 3) Feed additives like certain oils or seaweed have shown potential to reduce methane emissions from cattle. The choice of feed thus affects both direct emissions from animals and the overall carbon footprint of livestock production.

33. What is the concept of "regenerative agriculture" and how does it address climate change?

Regenerative agriculture is an approach that focuses on rehabilitating and enhancing the entire farm ecosystem. It addresses climate change by: 1) Increasing soil organic matter, sequestering more carbon. 2) Improving soil structure and water retention, reducing erosion and runoff. 3) Enhancing biodiversity, which increases ecosystem resilience. 4) Minimizing synthetic inputs, reducing associated emissions. This approach aims to work with natural systems to improve both agricultural productivity and environmental health.

34. What is the "nitrogen cycle" and how does agriculture disrupt it, contributing to climate change?

The nitrogen cycle is the biogeochemical cycle by which nitrogen is converted into various chemical forms as it circulates among the atmosphere, terrestrial, and marine ecosystems. Agriculture disrupts this cycle primarily through the use of synthetic nitrogen fertilizers. This leads to excess nitrogen in the environment, which can be converted to nitrous oxide (a potent greenhouse gas) by soil microbes. Additionally, nitrogen runoff can cause eutrophication in water bodies, further impacting ecosystems and potentially releasing more greenhouse gases.

35. How does soil erosion from agricultural practices contribute to climate change?

Soil erosion contributes to climate change in several ways: 1) It releases stored soil carbon into the atmosphere as CO2. 2) It reduces the soil's capacity to store carbon by depleting organic matter. 3) It decreases soil fertility, potentially leading to increased fertilizer use and associated emissions. 4) Eroded soil can clog waterways, affecting aquatic ecosystems that play a role in carbon cycling. 5) It can lead to expanded agricultural land use to compensate for lost productivity, potentially causing deforestation.

36. What is the "heat island effect" and how can urban agriculture help mitigate it?

The heat island effect occurs when urban areas are significantly warmer than surrounding rural areas due to human activities and infrastructure. Urban agriculture can help mitigate this effect by: 1) Increasing vegetation cover, which provides shade and evaporative cooling. 2) Reducing the amount of heat-absorbing surfaces like concrete and asphalt. 3) Improving air quality through plant photosynthesis. 4) Potentially reducing the energy needed for food transportation. By helping to cool cities, urban agriculture can indirectly reduce energy use for cooling and associated greenhouse gas emissions.

37. How does the global trade of agricultural products impact climate change?

Global trade of agricultural products impacts climate change through: 1) Emissions from long-distance transportation. 2) Encouraging specialization that may lead to monocultures and associated environmental issues. 3) Potentially driving deforestation in some regions to meet global demand. 4) Disconnecting production from local ecosystems, which can lead to less sustainable practices. However, trade can also potentially reduce emissions by allowing food production in the most suitable areas. The net impact depends on the specific products, production methods, and transportation modes involved.

38. What is "biochar" and how can it be used in agriculture to mitigate climate change?

Biochar is a type of charcoal produced by burning organic matter in a low-oxygen environment. In agriculture, it can mitigate climate change by: 1) Sequestering carbon in a stable form when added to soil. 2) Improving soil fertility, potentially reducing the need for fertilizers. 3) Enhancing soil water retention, which can reduce irrigation needs. 4) Potentially reducing soil N2O emissions. While promising, the long-term impacts and optimal use of biochar in different agricultural systems are still being researched.

39. What is "agroecology" and how does it approach the challenge of climate change in agriculture?

Agroecology is an approach to farming that applies ecological principles to agricultural systems. It addresses climate change by: 1) Promoting biodiversity, which enhances ecosystem resilience. 2) Minimizing external inputs, reducing associated emissions. 3) Emphasizing soil health and natural pest control, potentially increasing carbon sequestration. 4) Integrating traditional knowledge with modern science to develop locally adapted, sustainable farming systems. Agroecology aims to create productive agricultural systems that work with, rather than against, natural processes.

40. How do different tillage practices impact soil carbon storage and greenhouse gas emissions?

Different tillage practices significantly impact soil carbon storage and emissions: 1) Conventional tillage disrupts soil structure, exposing stored carbon to oxidation and release as CO2. 2) No-till or reduced tillage practices minimize soil disturbance, helping to maintain soil carbon stocks. 3) Conservation tillage can increase soil organic matter over time, enhancing carbon sequestration. 4) Tillage practices also affect soil moisture and aeration, influencing N2O emissions from fertilized soils. The choice of tillage method thus plays a crucial role in the overall greenhouse gas balance of agricultural systems.

41. What is the concept of "carbon leakage" in the context of agricultural policies and climate change?

Carbon leakage in agriculture refers to the phenomenon where emissions-reducing policies in one region lead to increased emissions elsewhere. For example, strict regulations on agricultural emissions in one country might lead to increased imports from countries with less stringent rules, potentially increasing global emissions. This concept highlights the importance of considering global supply chains and implementing coordinated international policies to effectively address agriculture's role in climate change.