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Quantum Non-Demolition Measurements: Observing Without Destroying

Kumar Prafull

Table of Contents

  1. Introduction
  2. What Is a Quantum Non-Demolition (QND) Measurement?
  3. Motivation and Applications
  4. Quantum Measurement Backaction
  5. Conditions for QND Measurements
  6. Commutativity and Conserved Observables
  7. QND vs Projective and Weak Measurements
  8. QND Hamiltonian Interactions
  9. Example: Photon Number QND Measurement
  10. Example: QND of Atomic Population
  11. Gravitational Wave Detection and QND
  12. QND in Cavity QED and Circuit QED
  13. QND with Optomechanical Systems
  14. Measurement of Quantum Jumps
  15. Role in Quantum Error Correction
  16. Quantum State Preparation via QND
  17. Measurement-Based Quantum Feedback
  18. Challenges and Limitations
  19. Experimental Realizations
  20. Conclusion

1. Introduction

Quantum non-demolition (QND) measurements allow the extraction of information about a quantum system without altering the observable being measured. They provide a way to monitor quantum systems repeatedly and precisely without collapse-induced destruction of the state.

2. What Is a Quantum Non-Demolition (QND) Measurement?

A QND measurement determines the value of an observable while preserving its future measurability. Repeated measurements yield the same outcome, indicating that the observable is unaffected by the act of measurement.

3. Motivation and Applications

  • Monitor quantum systems continuously
  • Prepare and stabilize quantum states
  • Enable quantum feedback and control
  • Support quantum error correction protocols
  • Essential in high-precision and low-noise measurements

4. Quantum Measurement Backaction

Standard quantum measurements perturb the system due to backaction. In QND, the observable commutes with the system’s Hamiltonian and the measurement operator, eliminating such disturbance.

5. Conditions for QND Measurements

  1. The observable \( \hat{O} \) must commute with the system Hamiltonian:
    \[
    [\hat{H}, \hat{O}] = 0
    \]
  2. The interaction Hamiltonian must couple the system to the probe without disturbing \( \hat{O} \).

6. Commutativity and Conserved Observables

If \( \hat{O} \) is a conserved quantity (\( [\hat{O}, H] = 0 \)), its value remains unchanged over time. Measuring such observables does not collapse the state destructively, satisfying QND conditions.

7. QND vs Projective and Weak Measurements

TypeCollapseRepeatabilitySystem Disturbance
ProjectiveYesNoHigh
WeakNoLimitedMinimal
QNDYes/NoYesMinimal (on observable)

8. QND Hamiltonian Interactions

A typical interaction Hamiltonian is:
\[
H_{ ext{int}} = \hbar g \hat{O} \otimes \hat{P}
\]
where \( \hat{O} \) is the system observable and \( \hat{P} \) is the conjugate observable of the measurement apparatus (probe).

9. Example: Photon Number QND Measurement

In cavity QED, atoms interact dispersively with a cavity. The phase shift in atomic levels reveals the number of photons \( n \) without absorbing them, leaving the photon number unchanged.

10. Example: QND of Atomic Population

In atomic ensembles, measuring population differences via Faraday rotation of probe light enables QND of spin projection, crucial for spin squeezing and quantum memory.

11. Gravitational Wave Detection and QND

QND techniques are proposed to overcome quantum limits in interferometric gravitational wave detectors (LIGO). They suppress backaction from radiation pressure noise.

12. QND in Cavity QED and Circuit QED

  • In cavity QED: Non-destructive readout of photon numbers
  • In circuit QED: Qubit state measured via dispersive shift of cavity frequency, preserving coherence of non-measured degrees of freedom

13. QND with Optomechanical Systems

QND of mechanical displacement or energy levels is achieved via radiation pressure interaction between light and moving mirrors in optical cavities.

14. Measurement of Quantum Jumps

QND enables observation of quantum jumps between energy levels in real time, revealing discrete nature of quantum state evolution.

15. Role in Quantum Error Correction

QND syndrome extraction allows detection of errors without destroying the encoded quantum information, essential for fault-tolerant quantum computing.

16. Quantum State Preparation via QND

Repeated QND measurements conditionally project the system into desired eigenstates, facilitating quantum state engineering and purification.

17. Measurement-Based Quantum Feedback

QND enables real-time monitoring and adaptive feedback to stabilize quantum systems or implement error-corrective control protocols.

18. Challenges and Limitations

  • Technical noise and decoherence
  • Imperfect isolation from other observables
  • Implementation of true non-demolition interactions in large systems

19. Experimental Realizations

QND has been realized in:

  • Microwave cavities with Rydberg atoms
  • Circuit QED with superconducting qubits
  • Atomic ensembles and squeezed light
  • Optomechanical systems and cold atoms

20. Conclusion

Quantum non-demolition measurements provide a vital tool for quantum control, sensing, and information processing. By enabling repeated, non-invasive observation, they push the boundaries of measurement precision and quantum system manipulation.

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Kumar Prafull

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