Quantum sensor
This article provides insufficient context for those unfamiliar with the subject.(October 2009) |
A quantum sensor is a device that exploits quantum correlations, such as quantum entanglement, to achieve a sensitivity or resolution that is better than can achieved using only classical systems.[1]
A quantum sensor can measure the effect of the quantum state of another system on itself. The mere act of measurement influences the quantum state and alters the probability and uncertainty associated with its state during measurement.
The Defense Advanced Research Projects Agency has recently[when?] launched a research program in optical quantum sensors that seeks to exploit ideas from quantum metrology and quantum imaging, such as quantum lithography and the NOON state,[2] in order to achieve these goals with optical sensor systems such as lidar.[3][4]
Quantum sensor is also a term used in other settings where entangled quantum systems are exploited to make better atomic clocks[5] or more sensitive magnetometers.[6][7]
A good example of an early quantum sensor is an APD avalanche photodiode such as the AD500-8 TO52S1 as these have been used to detect entangled photons and in fact with additional cooling and sensor improvements can be used where PMTs once ruled the market such as medical imaging. These are also now being used by First Sensor in the form of 2-D and even 3-D stacked arrays as a direct replacement for conventional sensors based on silicon diodes.
References
- ^ K.T.Kapale, et al., Concepts of Physics 2 (2005) 225.
- ^ Y. Israel, S. Rosen, Y. Silberberg Phys. Rev. Lett. 112 (2014) 103604.
- ^ DARPA Quantum Sensor Program.
- ^ BROAD AGENCY ANNOUNCEMENT (BAA) 07-22 Quantum Sensors
- ^ J.J.Bollinger, et al., Phys. Rev. A 54 (1996) R4649.
- ^ M.Auzinsh et al., Phys. Rev. Lett. 93 (2004) 173002.
- ^ A.Guillaume & J.P.Dowling, Phys. Rev. A 73 (2006) 040304(R).