Date : 31/10/2023
Relevance:GS Paper 3 – Science and Technology, Environment and Ecology
Keywords: ICE, BEVs, High Energy Density, Low Carbon Emission
Context-
- In the automotive industry, there is growing interest in an internal combustion engine fueled by ammonia. This innovative approach is gaining attention because it explores alternative propulsion methods without completely abandoning traditional Internal Combustion Engine (ICE) systems or transitioning to Battery Electric Vehicles (BEVs).
- Malaysian energy giant Petroliam Nasional (Petronas) and Singapore's sovereign wealth fund GIC will invest in a project to produce five million tonnes of green ammonia a year in India by 2030.
Internal Combustion Engine (ICE) Systems:
1. Definition and Operation:
ICE systems utilize traditional engines that combust fossil fuels (such as petrol or diesel) to generate power. The fuel-air mixture ignites, creating an explosion that propels the vehicle forward.
2. Applications:
These systems are commonly found in a range of vehicles, including cars, trucks, and motorcycles, powering their wheels through combustion-driven mechanisms.
3. Environmental Impact:
ICE vehicles emit exhaust gasses, contributing to air pollution and greenhouse gas emissions, making them a concern for environmental sustainability.
Battery Electric Vehicles (BEVs):
1. Definition and Power Source:
BEVs are electric vehicles powered exclusively by rechargeable batteries, which drive an electric motor. These batteries need to be charged using electricity from the grid.
2. Charging and Energy Sources:
BEVs require electricity for charging, sourced from various outlets, including renewable energy, making them a cleaner and greener alternative to traditional vehicles.
3. Emission Reduction:
BEVs produce zero tailpipe emissions, making them environmentally friendly and contributing significantly to reducing air pollution.
Major Applications of Ammonia:
1. Agriculture:
Ammonia is crucial in the production of ammonia-based fertilizers like ammonium nitrate and urea, vital for crop growth.
2. Chemical Industry:
It serves as a fundamental ingredient in producing substances such as nitric acid, ammonium sulfate, and various nitrogen-based compounds. Additionally, ammonia is used in manufacturing synthetic fibers like nylon.
3. Manufacturing and Household:
In industrial settings, it functions as a refrigerant in refrigeration systems and air conditioning. It's also utilized in dye manufacturing and as a pH regulator in dyeing processes. Moreover, it's an ingredient in household cleaning products.
Advantages of Using Ammonia as a Fuel:
1. High Energy Density:
Ammonia possesses high energy density, suitable for long-term applications, being nine times more energy-dense than lithium-ion batteries and three times that of compressed hydrogen.
2. Low Carbon Emissions:
Ammonia has the potential to produce nearly zero carbon dioxide emissions during combustion, making it eco-friendly, especially in comparison to fossil fuels.
3. Bridge Fuel:
It can act as a transitional fuel, reducing reliance on traditional fossil fuels, thereby enhancing energy security and diversifying the energy mix.
Challenges Associated with Using Ammonia as a Fuel:
1. Environmental Impact:
Despite low CO2 emissions, current ammonia engines emit pollutants, including unburned ammonia and nitrogen oxides, leading to environmental and health risks.
2. Production Challenges:
Traditional ammonia production processes are energy-intensive and reliant on fossil fuels. Green ammonia production, using renewable energy, faces hurdles in terms of cost and scalability.
3. Toxicity and Safety Concerns
Ammonia is highly toxic and corrosive, posing risks to both humans and the environment if not handled carefully. Accidents or mishandling could have severe consequences.
4. Fuel Quality Standards:
Establishing consistent quality standards for ammonia as a fuel is complex, especially considering variations in production sources and impurity levels.
The Way ahead
1. Research and Development:
Ammonia is crucial in the production of ammonia-based fertilizers like ammonium nitrate and urea, vital for crop growth.
2. Safety Training:
It serves as a fundamental ingredient in producing substances such as nitric acid, ammonium sulfate, and various nitrogen-based compounds. Additionally, ammonia is used in manufacturing synthetic fibers like nylon.
3. Market Incentives:
In industrial settings, it functions as a refrigerant in refrigeration systems and air conditioning. It's also utilized in dye manufacturing and as a pH regulator in dyeing processes. Moreover, it's an ingredient in household cleaning products.
4. Ammonia Hybrids:
In industrial settings, it functions as a refrigerant in refrigeration systems and air conditioning. It's also utilized in dye manufacturing and as a pH regulator in dyeing processes. Moreover, it's an ingredient in household cleaning products.
Probable Questions for UPSC Mains Exam
- Discuss the potential of ammonia as a fuel in the automotive industry, highlighting its advantages and challenges. How can technological innovations and research contribute to mitigating these challenges, making ammonia-powered engines a viable and sustainable alternative? (10 marks, 150 words)
- Evaluate the environmental impact of ammonia-powered engines in comparison to traditional Internal Combustion Engine (ICE) systems and Battery Electric Vehicles (BEVs). Analyze the role of stringent quality standards, safety protocols, and market incentives in promoting the widespread adoption of ammonia as a clean and eco-friendly fuel source in various sectors, emphasizing its implications for environmental sustainability. (15 marks, 250 words)
Source- Business Standard
