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News: India achieved a major milestone in its civil nuclear programme as the 500 MWe Prototype Fast Breeder Reactor at Kalpakkam attained criticality, marking the start of a controlled nuclear chain reaction.
About Prototype Fast Breeder Reactor (PFBR)
- The Prototype Fast Breeder Reactor is India’s first fast breeder reactor, a nuclear reactor that produces more fissile material than it consumes using fast neutrons and plutonium-based fuel.
- Developed by: The reactor was indigenously developed by Indira Gandhi Centre for Atomic Research.
- Built by: It was built and commissioned by Bharatiya Nabhikiya Vidyut Nigam Limited.
- Operated by: It is operated by the BHAVINI under the Department of Atomic Energy (DAE).
- Working Mechanism of PFBR:
- Fuel use: The reactor uses Uranium-Plutonium Mixed Oxide (MOX) fuel, where plutonium undergoes fission using fast neutrons.
- Neutron process: Fast neutrons convert fertile Uranium-238 into fissile Plutonium-239, sustaining the chain reaction.
- Breeding process: This conversion enables the reactor to produce more fuel than it consumes, which is the core principle of breeder reactors.
- Coolant system: The reactor uses liquid sodium coolant, which efficiently removes heat and allows fast neutrons to persist.
- Thorium pathway: The reactor is designed to use Thorium-232, which can be converted into Uranium-233 for the third stage.
- Key Features:
- High fuel efficiency: It can extract more energy from uranium, improving resource utilization.
- Support to nuclear programme: It acts as a bridge between Stage I and Stage III of India’s nuclear programme.
- Closed fuel cycle: It enables recycling of nuclear materials, reducing waste.
- Energy security role: It supports long-term clean and reliable base-load power generation.
About Criticality in Nuclear Reactors
- It is the stage where a nuclear chain reaction becomes self-sustaining and stable.
- Operational importance: It marks readiness of the reactor for power generation.
- States of Criticality:
- Subcritical state: In this state, neutron losses are greater than production, so the chain reaction gradually dies out and the reactor shuts down.
- Critical state: In this state, neutron production equals neutron loss, so the chain reaction becomes stable and self-sustaining, and power remains constant.
- Supercritical state: In this state, neutron production exceeds losses, so the chain reaction increases rapidly, and reactor power rises.
- Safety aspect: Controlled criticality is essential for safe reactor operation.
About India’s 3 Stage Nuclear Programme
- It is a long-term strategy to achieve energy security using uranium and vast thorium reserves.
- Formulated by: It was formulated by Homi Bhabha in the 1950s.
- Aim: It aims to ensure energy independence, efficient fuel use, and utilisation of abundant thorium reserves.
- Three stages are:
- Stage 1: Pressurised Heavy Water Reactors using natural uranium.
- Stage 2: Fast Breeder Reactors using plutonium-based fuel.
- Stage 3: Advanced systems using thorium to produce Uranium-233.
