Related papers: Approaching the quantum limit of energy resolution in animal magnetoreception

Approaching the quantum limit of energy resolution in animal magnetoreception

URL: http://arxiv.org/abs/2410.07186v2
Date: Fri, 17 Jan 2025 18:18:24 GMT
Title: Approaching the quantum limit of energy resolution in animal magnetoreception
Authors: I. K. Kominis, E. Gkoudinakis,
Abstract summary: A large number of magnetic sensors, like superconducting quantum interference devices, were shown to satisfy the energy resolution limit. This limit states that the magnetic sensitivity of the sensor, when translated into a product of energy with time, is bounded below by Planck's constant, hbar. Here we explore biological magnetometers, in particular three magnetoreception mechanisms thought to underly animals' geomagnetic field sensing.
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Abstract: A large number of magnetic sensors, like superconducting quantum interference devices, optical pumping and nitrogen vacancy magnetometers, were shown to satisfy the energy resolution limit. This limit states that the magnetic sensitivity of the sensor, when translated into a product of energy with time, is bounded below by Planck's constant, hbar. This bound implies a fundamental limitation as to what can be achieved in magnetic sensing. Here we explore biological magnetometers, in particular three magnetoreception mechanisms thought to underly animals' geomagnetic field sensing: the radical-pair, the magnetite and the MagR mechanism. We address the question of how close these mechanisms approach the energy resolution limit. At the quantitative level, the utility of the energy resolution limit is that it informs the workings of magnetic sensing in model-independent ways, and thus can provide subtle consistency checks for theoretical models and estimated or measured parameter values, particularly needed in complex biological systems. At the qualitative level, the closer the energy resolution is to hbar, the more "quantum" is the sensor. This offers an alternative route towards understanding the quantum biology of magnetoreception. It also quantifies the room for improvement, illuminating what Nature has achieved, and stimulating the engineering of biomimetic sensors exceeding Nature's magnetic sensing performance.

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