Optical Atomic Clock

Brief Context

Context Researchers from six countries have conducted the world’s largest and most accurate comparison of optical atomic clocks across three continents. What is the Current Definition of a Second? Present Standard (since 1967): One second equals the time taken for 9,192,631,770 cycles of radiation produced by the caesium-133 atom when it changes between two energy states.

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Syllabus: GS3/ Science and Technology

Context

• Researchers from six countries have conducted the world’s largest and most accurate comparison of optical atomic clocks across three continents. 
• It is a major step towards redefining the SI unit of time — the second — using optical clocks instead of current caesium-based atomic clocks.

What is the Current Definition of a Second?

• Present Standard (since 1967): One second equals the time taken for 9,192,631,770 cycles of radiation produced by the caesium-133 atom when it changes between two energy states.
  • Caesium was chosen for its high accuracy and consistency.
• India’s Timekeeping: The National Physical Laboratory (NPL) in Delhi maintains India’s time standard using five caesium clocks.
  • The clocks’ output is disseminated to various applications around India via the INSAT satellites, telecommunication signals, and fibre links.

What are Optical Atomic Clocks?

• Like caesium clocks, Optical Atomic Clocks measure time based on an atom’s internal energy transitions, but use optical (visible light) frequencies instead of microwaves.
• Common Atoms Used in Optical Clocks: Strontium-87 (Sr), Ytterbium-171 (Yb) and Ytterbium ions (Yb⁺), Indium-115 ions (In⁺) and Charged Strontium-88 (Sr⁺).

Why Replace Caesium with Optical Clocks?

• Higher Frequency, Better Precision: Optical clocks use higher-frequency visible light, enabling more oscillations per second and thus more precise time measurement than caesium clocks.
  • Caesium clocks use radiation at 9.19 billion Hz,
  • Strontium clocks use 429 trillion Hz,
  • Ytterbium clocks use 642 trillion Hz.
• Unmatched Stability: Some optical clocks are so stable that they drift by just one second in 15 billion years, making them 10,000 times more precise than caesium clocks.
• Atomic Transition Principle : Like caesium clocks, optical clocks measure time by counting how atoms shift between fixed energy levels.
  • But instead of microwaves, they use lasers to stimulate and detect these shifts, resulting in much more stable and accurate frequency measurements.

Significance of the Development

• Lays Foundation for Redefining the Second, likely by 2030.
• Supports High-Precision Applications like:
  • Satellite navigation (GPS, NavIC, Galileo)
  • Radio astronomy (e.g., black hole imaging)
  • Climate science (tracking gravity changes due to ice/water loss)

Source: TH