NV microscopy of thermally controlled stresses caused by thin Cr2O3 films

Author:

Berzins Andris12ORCID,Smits Janis12,Petruhins Andrejs3,Rimsa Roberts1,Mozolevskis Gatis1,Zubkins Martins1,Fescenko Ilja1

Affiliation:

1. University of Latvia

2. The University of New Mexico

3. Linkoping University

Abstract

Many modern applications, including quantum computing and quantum sensing, use substrate-film interfaces. Particularly, thin films of chromium or titanium and their oxides are commonly used to bind various structures, such as resonators, masks, or microwave antennas, to a diamond surface. Due to different thermal expansions of involved materials, such films and structures could produce significant stresses, which need to be measured or predicted. In this paper, we demonstrate imaging of stresses in the top layer of diamond with deposited structures of Cr2O3 at temperatures 19°C and 37°C by using stress-sensitive optically detected magnetic resonances (ODMR) in NV centers. We also calculated stresses in the diamond-film interface by using finite-element analysis and correlated them to measured ODMR frequency shifts. As predicted by the simulation, the measured high-contrast frequency-shift patterns are only due to thermal stresses, whose spin-stress coupling constant along the NV axis is 21±1 MHz/GPa, that is in agreement with constants previously obtained from single NV centers in diamond cantilever. We demonstrate that NV microscopy is a convenient platform for optically detecting and quantifying spatial distributions of stresses in diamond-based photonic devices with micrometer precision and propose thin films as a means for local application of temperature-controlled stresses. Our results also show that thin-film structures produce significant stresses in diamond substrates, which should be accounted for in NV-based applications.

Funder

Centrālā finanšu un līgumu aģentūra

European Regional Development Fund

Horizon 2020 Framework Programme

Latvijas Universitātes fonds

Latvijas Zinātnes Padome

State Education Development Agency Republic of Latvia

Publisher

Optica Publishing Group

Subject

Atomic and Molecular Physics, and Optics

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