26 Nov

Greenhouse Gases and their Impacts on the Environment

window.dataLayer = window.dataLayer || []; function gtag(){dataLayer.push(arguments);} gtag(‘js’, new Date()); gtag(‘config’, ‘G-EF1EZD2YQV’);

Table of Contents

• What are GHGs?
• Importance of GHGs
• What is the Green House Effect?
• What are the sources of GHGs?
• Which are the most important GHGs?
• Impact of these GHGs on Environment
• What can be done to mitigate the impacts?
• Conclusion
• FAQs

What are GHGs?

Any gas that has the property of absorbing infrared radiation (net heat energy) emitted from Earth’s surface and reradiating it back to Earth’s surface, thus contributing to the greenhouse effect. Carbon dioxide, methane, and water vapour are the most important greenhouse gases. Greenhouse gases have a profound effect on the energy budget of the Earth system despite making up only a fraction of all atmospheric gases

Importance of GHGs

GHGs trap some of the Earth’s outgoing energy, thus retaining heat in the atmosphere. This heat trapping causes changes in the radiative balance of the Earth—the balance between energy received from the sun and emitted from Earth—that alter climate and weather patterns at global and regional scales.

What is the Green House Effect?

Imagine for a moment the Earth had no atmosphere. The sun, roughly 93 million miles from Earth, sends electromagnetic radiation, warming the Earth’s surface. This warming would, in turn, release electromagnetic radiation back into space. Without an atmosphere with greenhouse gases to capture some of that heat, the energy would return to space, and the Earth would be much colder than it is today. Without the greenhouse effect, the global mean temperature would be -18°C and therefore uninhabitable for humans.

The greenhouse effect occurs mostly in our troposphere, which is our lower atmosphere. Our troposphere is composed mainly of nitrogen and oxygen. Argon, carbon dioxide, water vapour, methane, and other gases are in low concentrations and comprise about 1% of the troposphere.

These gases can capture electromagnetic radiation that would otherwise be radiated back into space. These gases are known as “greenhouse gases” because they trap this energy, or heat, in the atmosphere and warm the Earth. The ability of these greenhouse gases to capture and retain heat that otherwise would have been lost, thereby warming the Earth, is called the greenhouse effect. Thanks to the greenhouse effect, our planet’s average temperature is a comfortable 15°C.

What are the sources of GHSs?

The origins of greenhouse gases are diverse, ranging from volcanic eruptions to industrial emissions. Natural processes and human activities release these gases into the atmosphere, each adding to the layers of complexity in our climate system.

Natural Sources

These include volcanic eruptions, which release gases and particulates into the atmosphere, natural biological processes in soil, and ocean releases.

Human Activities

Human sources are diverse, encompassing fossil fuel combustion in energy and transportation, industrial processes, agricultural practices that release methane and nitrous oxide, and deforestation, which impacts carbon storage capacities.

Which are the most important GHGs?

Carbon dioxide (or CO2) is a colourless, odourless gas consisting of one part carbon and two parts oxygen. CO2 is a natural component of our planet’s atmosphere and is one of the most commonly known greenhouse gases. Because humanity releases more carbon dioxide –primarily through burning fossil fuels like coal and oil– into the atmosphere than current biological processes can remove, the amount and concentration of carbon dioxide in the atmosphere and ocean increases yearly.

Methane (CH4), a primary constituent of natural gas, is a greenhouse gas, and its presence in the atmosphere affects our climate system and the Earth’s temperature. Although CO2 has a longer-lasting effect on our climate, methane has a much higher Global Warming Potential (GWP) than carbon dioxide.

According to the Environmental Defence Fund, methane accounts for at least 25% of today’s global warming. Agriculture (primarily through manure and gastroenteric releases, but also through rice cultivation) is responsible for around a quarter of the methane emissions, followed by the energy sector.

Nitrous oxide (N2O), also known as laughing gas, contributes to the greenhouse effect.

In addition to natural sources, agriculture and fertilisers produce nitrous oxide. Around 40% of the total N2O emissions globally come from human activities. The IPCC has calculated that nitrous oxide comprises about 6% of all greenhouse gas emissions, and its emissions rose 30% in the past forty years.

Water Vapour is Earth’s most abundant greenhouse gas and is responsible for about half of Earth’s greenhouse effect. As temperatures increase, the rate of water evaporation also increases. This water vapour remains in the lower atmosphere, where it absorbs radiation and pushes it down to the Earth’s surface, causing already hot temperatures to continue to rise. This creates a feedback loop, as water vapour is a greenhouse gas that becomes more abundant the warmer the planet becomes.

Hydrofluorocarbons refrigerants are found in everything from air conditioning systems to home refrigerators, grocery store freezers, and industrial warehouses. The majority of the gases used in refrigerants are hydrofluorocarbons, or HFCs. HFCs are hundreds to thousands of times more potent a greenhouse gas than carbon dioxide. Therefore, limiting the emissions of these gases is crucial to limit global warming, as is ensuring their safe disposal.

Sulphur hexafluoride (SF6) is the most potent of all greenhouse gases, with a global warming potential 23,900 times the baseline of CO2. SF6 is synthetic and does not have a natural sink or effective disposal methods. Thus, when emitted, SF6 simply accumulates in the atmosphere. SF6’s atmospheric lifetime can be up to 3,200 years, well beyond CO2 ‘s atmospheric lifetime.

The energy industry is SF6’s biggest consumer– it consumes more than 80% of the gas. SF6 is mostly used inside switchgear – an essential component of any electricity grid.  They are also used inside wind turbines, meaning neither wind energy, nor electricity, in general, can be claimed to be completely environmentally friendly.

Impact of these GHGs on Environment

Impact of GHGs on the environment is understood using two main indicators:

Global Warming Potential – a relative measure of how much heat a greenhouse gas traps in the atmosphere; and the atmospheric lifetime – which measures the lifetime of the gas in the atmosphere.

The first indicator expresses itself in CO2 equivalent (how much more or less the effect on the climate is of this greenhouse gas compared to the CO2 effect set as a reference equal to 1). This effect on the climate is known as the global warming potential, or GWP. GWP is defined as the amount of heat absorbed by any greenhouse gas in the atmosphere as a multiple of the heat that would be absorbed by the same mass of carbon dioxide (CO2). The second indicator, atmospheric lifetime, indicates the time it takes for the gas to disappear from the atmosphere.

GHGs’ Impacts on Environment includes:

Greenhouse gases drive significant changes in our climate, altering weather patterns and influencing global temperatures and sea levels. Their impact is profound, affecting biodiversity, human health, and the global economy.

Extreme Weather Events Increases in greenhouse gases are linked to more severe weather patterns, including hurricanes, droughts, and heavy rainfall.

Rising Sea Levels and Melting Ice Caps As temperatures rise, ice caps melt, and sea levels rise, which can lead to coastal erosion and affect low-lying communities.

Effects on Biodiversity and Ecosystems Flora and fauna struggle to adapt to changing climates, leading to biodiversity and ecosystem services shifts.

Socio-Economic Implications Climate change can impact food security, water resources, and general health, leading to economic losses globally.

Consequences of enhanced greenhouse effects include rising global temperatures, altered weather patterns, and significant ecological impacts.

What can be done to mitigate the impacts?

Mitigating the effects of greenhouse gases is possible through various strategies, from technological innovations in energy production to shifts in agricultural practices. Each approach offers a pathway to reduce emissions and curb global warming.

Transition to Renewable Energy Sources: such as solar, wind, hydro, and geothermal to decrease reliance on fossil fuels.

Enhancing Energy Efficiency: in buildings, industries, and transportation can significantly cut emissions.

Sustainable Transportation Solutions: include promoting electric vehicles, enhancing public transportation systems, and developing cycling infrastructures.

Carbon Sequestration Techniques: such as afforestation, reforestation, and technological carbon capture and storage, can directly remove CO₂ from the atmosphere.

Sustainable Agricultural Practices: such as improved crop rotation, reduced fertiliser use, and capturing methane from livestock can diminish agriculture’s carbon footprint.

What is India doing to mitigate the impact of GHGs on the environment?

India has launched several transformative initiatives to address climate change, promote renewable energy, and build a sustainable future. An overview of key government-led programs and global commitments:

International Solar Alliance (ISA)

India’s sun-rich regions, such as Rajasthan, offer immense potential for solar energy. To harness this, India launched the International Solar Alliance (ISA) in 2015, in partnership with France. This coalition brings together countries with high solar exposure to promote clean energy solutions and reduce reliance on fossil fuels. ISA aims to accelerate solar deployment across member nations and foster energy security through sustainable practices.

One Sun, One World, One Grid (OSOWOG)

Proposed by Prime Minister Narendra Modi during the first ISA Assembly in 2018, the OSOWOG initiative envisions a globally interconnected solar grid. The goal is to transmit solar power across borders, enabling clean energy access to over 140 countries. Jointly supported by India, the UK, ISA, and the World Bank, OSOWOG is a strategic step toward solving global energy challenges through renewable integration.

Swachh Bharat Abhiyan

Launched under the leadership of Prime Minister Modi, the Swachh Bharat Mission aimed to improve sanitation and hygiene across India. Covering thousands of towns and villages, the campaign led to the construction of over 100 million toilets and declared all districts “Open Defecation Free” by October 2, 2019 — commemorating Mahatma Gandhi’s 150th birth anniversary. The initiative significantly improved public health and rural infrastructure.

India’s Climate Commitments at COP26 

At the COP26 Summit in Glasgow, India announced five major climate goals, known as Panchamrit, to guide its environmental strategy:

• Achieve net zero emissions by 2070
• Source 50% of energy from renewables by 2030
• Cut carbon emissions by 1 billion tonnes by 2030
• Expand non-fossil energy capacity to 500 GW by 2030
• Reduce carbon intensity by 45% by 2030, compared to 2005 levels
• These pledges reflect India’s proactive role in global climate governance.

Rise of Climate Tech in India’s Startup Ecosystem

Climate tech refers to innovative solutions that reduce emissions and promote sustainable alternatives. India, now the third-largest startup hub globally, has seen rapid growth in climate-focused ventures. According to the Economic Survey 2021–22, startups span over 56 sectors, with climate tech emerging as a key area alongside IT, healthcare, education, and agriculture.

These startups are developing scalable solutions for clean energy, carbon capture, green mobility, and sustainable agriculture — aligning with India’s climate goals.

Policy Push & Tech Innovation

With increasing public awareness and strong government backing, India’s climate-tech sector is thriving. The Panchamrit framework has catalyzed innovation, investment, and collaboration across industries. Startups are leveraging this momentum to build impactful, scalable solutions for environmental challenges.

Conclusion

Tackling the challenges posed by greenhouse gases requires a united approach that blends innovation, strong policy frameworks, and active community participation. These gases, which significantly contribute to global warming and climate instability, demand careful study and decisive action. By identifying their sources and understanding their far-reaching impacts on ecosystems, economies, and human health, societies can design effective strategies to reduce emissions and promote cleaner alternatives. Collaboration across governments, industries, and individuals is vital to achieving international climate targets. With shared responsibility and sustained effort, we can pave the way toward a resilient and sustainable future for all.

FAQs

1. What are greenhouse gases (GHGs)?

Greenhouse gases are atmospheric gases like carbon dioxide, methane, and nitrous oxide that trap heat and contribute to global warming.

2. What is the greenhouse effect?

The greenhouse effect is the natural process by which GHGs absorb and re-radiate heat, keeping Earth’s temperature suitable for life. Excessive GHGs, however, cause harmful climate change.

3. Why are greenhouse gases important?

They regulate Earth’s temperature, but in excess, they disrupt ecosystems, increase extreme weather events, and threaten human health.

4. What are the main sources of greenhouse gases?

Major sources include fossil fuel combustion, agriculture, deforestation, and industrial processes

5. Which are the most significant greenhouse gases?

Carbon dioxide (CO₂), methane (CH₄), nitrous oxide (N₂O), and fluorinated gases are the most impactful.