TY - JOUR
T1 - Deep neural network detects quantum phase transition
AU - Arai, Shunta
AU - Ohzeki, Masayuki
AU - Tanaka, Kazuyuki
N1 - Funding Information:
Acknowledgments We acknowledge the help of Shun Kataoka and Yuya Seki for many fruitful discussions about our numerical simulations. M.O. was supported by KAKENHI Nos. 15H0369, 16H04382, and 16K13849 and JST-START. This work was partly supported by JST-CREST (No. JPMJCR1402).
Publisher Copyright:
© 2018 The Physical Society of Japan.
PY - 2018
Y1 - 2018
N2 - We detect the quantum phase transition of a quantum many-body system by mapping the observed results of the quantum state onto a neural network. In the present study, we utilized the simplest case of a quantum many-body system, namely a one-dimensional chain of Ising spins with the transverse Ising model. We prepared several spin configurations, which were obtained using repeated observations of the model for a particular strength of the transverse field, as input data for the neural network. Although the proposed method can be employed using experimental observations of quantum many-body systems, we tested our technique with spin configurations generated by a quantum Monte Carlo simulation without initial relaxation. The neural network successfully identified the strength of transverse field only from the spin configurations, leading to consistent estimations of the critical point of our model Gc = J.
AB - We detect the quantum phase transition of a quantum many-body system by mapping the observed results of the quantum state onto a neural network. In the present study, we utilized the simplest case of a quantum many-body system, namely a one-dimensional chain of Ising spins with the transverse Ising model. We prepared several spin configurations, which were obtained using repeated observations of the model for a particular strength of the transverse field, as input data for the neural network. Although the proposed method can be employed using experimental observations of quantum many-body systems, we tested our technique with spin configurations generated by a quantum Monte Carlo simulation without initial relaxation. The neural network successfully identified the strength of transverse field only from the spin configurations, leading to consistent estimations of the critical point of our model Gc = J.
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U2 - 10.7566/JPSJ.87.033001
DO - 10.7566/JPSJ.87.033001
M3 - Article
AN - SCOPUS:85042593269
SN - 0031-9015
VL - 87
JO - Journal of the Physical Society of Japan
JF - Journal of the Physical Society of Japan
IS - 3
M1 - 033001
ER -