# Direct Comparison of Fractional and Integer Quantized Hall Resistance

**Authors:** Franz J. Ahlers, Martin G\"otz, and Klaus Pierz

arXiv: 1703.05213 · 2017-06-30

## TL;DR

This study performs a highly precise comparison between fractional and integer quantum Hall resistances, providing critical insights into fundamental physics and the SI redefinition, using advanced cryogenic measurement techniques.

## Contribution

It presents the most precise direct comparison of fractional and integer quantum Hall resistances, validating fundamental physics with a novel cryogenic current comparator bridge.

## Key findings

- Achieved a ratio measurement with a 95% confidence level uncertainty of 6.3×10^{-8}.
- Demonstrated the capability of cryogenic current comparator bridges for ultra-precise resistance comparisons.
- Confirmed the consistency of fractional and integer quantum Hall effects within experimental uncertainty.

## Abstract

We present precision measurements of the fractional quantized Hall effect where the quantized resistance $R^{[1/3]}$ in the fractional quantum Hall state at filling factor 1/3 was compared with a quantized resistance $R^{[2]}$, represented by an integer quantum Hall state at filling factor 2. A cryogenic current comparator bridge capable of currents down to the nanoampere range was used to directly compare two resistance values of two GaAs-based devices located in two cryostats. A value of $1 - (5.3 \pm 6.3) 10^{-8}$ (95% confidence level) was obtained for the ratio $(R^{[1/3]}/6R^{[2]})$. This constitutes the most precise comparison of integer resistance quantization (in terms of $h/e^2$) in single-particle systems and of fractional quantization in fractionally charged quasi-particle systems. While not relevant for practical metrology, such a test of the validity of the underlying physics is of significance in the context of the up-coming revision of the SI.

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Source: https://tomesphere.com/paper/1703.05213