Experimental probe of weak value amplification and geometric phase through the complex zeroes of the response function

TL;DR

This paper experimentally links weak value amplification to the complex zeros of a system's response function, revealing new universal relationships that could enhance high-precision measurements in quantum systems.

Contribution

It demonstrates a fundamental relationship between weak values and complex zeros of the response function using optical weak measurements, enabling larger amplification beyond traditional limits.

Findings

Large weak value amplification achieved from response function minima

Complex zeros relate to geometric phase gradients in light

Universal relationships may improve quantum measurement techniques

Abstract

The extraordinary concept of weak value amplification has attracted considerable attention for addressing foundational questions in quantum mechanics and for metrological applications in high precision measurement of small physical parameters. Here, we experimentally demonstrate a fundamental relationship between the weak value of an observable and complex zero of the response function of a system by employing weak value amplification of spin Hall shift of a Gaussian light beam. Using this relationship, we show that arbitrarily large weak value amplification far beyond the conventional weak measurement limit can be experimentally obtained from the position of the minima of the pointer intensity profile corresponding to the real part of the complex zero of the response function. The imaginary part of the complex zero, on the other hand, is related to the spatial gradient of geometric phase of light, which in this particular scenario evolves due to the weak interaction and the pre and post selections of the polarization states. These universal relationships between the weak values and the complex zeros of the response function may provide new insights on weak measurements in a wide class of physical systems. Extremely large weak value amplification and extraction of system parameters outside the region of validity of conventional weak measurements may open up a new paradigm of weak measurement enhancing its metrological applications.