Classical and quantum machine learning applications in spintronics
Classical and quantum machine learning applications in spintronics
In this article we demonstrate the applications of classical and quantum machine learning in quantum transport and spintronics. With the help of a two-terminal device with magnetic impurities we show how machine learning algorithms can predict the highly non-linear nature of conductance as well as t...
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Personal Name(s): | Ghosh, Kumar J. B. (Corresponding author) |
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Ghosh, Sumit (Corresponding author) | |
Contributing Institute: |
Quanten-Theorie der Materialien; PGI-1 |
Published in: | Digital discovery, 2 (2023) 2, S. 512 - 519 |
Imprint: |
Washington DC
Royal Society of Chemistry
2023
|
DOI: |
10.34734/FZJ-2024-03092 |
DOI: |
10.1039/D2DD00094F |
Document Type: |
Journal Article |
Research Program: |
Topological Matter |
Link: |
OpenAccess |
Publikationsportal JuSER |
Please use the identifier: http://dx.doi.org/10.1039/D2DD00094F in citations.
In this article we demonstrate the applications of classical and quantum machine learning in quantum transport and spintronics. With the help of a two-terminal device with magnetic impurities we show how machine learning algorithms can predict the highly non-linear nature of conductance as well as the non-equilibrium spin response function for any random magnetic configuration. By mapping this quantum mechanical problem onto a classification problem, we are able to obtain much higher accuracy beyond the linear response regime compared to the prediction obtained with conventional regression methods. We finally describe the applicability of quantum machine learning which has the capability to handle a significantly large configuration space. Our approach is applicable for solid state devices as well as for molecular systems. These outcomes are crucial in predicting the behavior of large-scale systems where a quantum mechanical calculation is computationally challenging and therefore would play a crucial role in designing nanodevices. |