Machine learning phases of matter
TL;DR: It is shown that modern machine learning architectures, such as fully connected and convolutional neural networks, can identify phases and phase transitions in a variety of condensed-matter Hamiltonians.
read more
Abstract: The success of machine learning techniques in handling big data sets proves ideal for classifying condensed-matter phases and phase transitions. The technique is even amenable to detecting non-trivial states lacking in conventional order. Condensed-matter physics is the study of the collective behaviour of infinitely complex assemblies of electrons, nuclei, magnetic moments, atoms or qubits1. This complexity is reflected in the size of the state space, which grows exponentially with the number of particles, reminiscent of the ‘curse of dimensionality’ commonly encountered in machine learning2. Despite this curse, the machine learning community has developed techniques with remarkable abilities to recognize, classify, and characterize complex sets of data. Here, we show that modern machine learning architectures, such as fully connected and convolutional neural networks3, can identify phases and phase transitions in a variety of condensed-matter Hamiltonians. Readily programmable through modern software libraries4,5, neural networks can be trained to detect multiple types of order parameter, as well as highly non-trivial states with no conventional order, directly from raw state configurations sampled with Monte Carlo6,7.
read more
Chat with Paper
AI Agents for this Paper
Find similar papers on Google Scholar, PubMed and Arxiv
Write a critical review of this paper
Analyze citations of this paper to find unaddressed research gaps
Citations
Machine Learning Magnetic Parameters from Spin Configurations
Dingchen Wang,Songrui Wei,Anran Yuan,Fanghua Tian,Kaiyan Cao,Qizhong Zhao,Yin Zhang,Chao Zhou,Xiaoping Song,Dezhen Xue,Sen Yang +10 more
TL;DR: In this paper, a machine learning-based approach for estimating Hamiltonian parameters from high-resolution images based on a small amount of simulated images is proposed. But the approach is limited to a single unexplored experimental image and cannot predict the corresponding materials properties.
38
Toward Electrochemical Studies on the Nanometer and Atomic Scales: Progress, Challenges, and Opportunities.
Sergei V. Kalinin,Ondrej Dyck,Nina Balke,Sabine M. Neumayer,Wan-Yu Tsai,Rama K. Vasudevan,David B. Lingerfelt,Mahshid Ahmadi,Maxim Ziatdinov,Matthew T. McDowell,Evgheni Strelcov +10 more
TL;DR: The challenges and opportunities for extending electrochemical characterization probes to the nanometer and ultimately atomic scales are discussed, including challenges in down-scaling classical methods, the emergence of novel probes enabled by nanotechnology and based on emergent physics and chemistry of nanoscale systems, and the integration of local data into macroscopic models.
38
Self-organizing maps as a method for detecting phase transitions and phase identification
Albert A. Shirinyan,V. K. Kozin,V. K. Kozin,Johan Hellsvik,Manuel Pereiro,Olle Eriksson,Olle Eriksson,Dmitry Yudin +7 more
TL;DR: This research presents a novel approach called “supervised learning” that automates the very labor-intensive and therefore time-heavy and expensive process of manually cataloging and extracting features from multidimensional datasets.
38
Machine-learning quantum mechanics: Solving quantum mechanics problems using radial basis function networks
TL;DR: In this paper, the radial basis function network in a discrete basis is used as the variational wave function for the ground state of a quantum system and the results are in good agreement with theoretical values.
37
Machine Learning in Nano-Scale Biomedical Engineering
Alexandros-Apostolos A. Boulogeorgos,Stylianos E. Trevlakis,Sotiris A. Tegos,Vasilis K. Papanikolaou,George K. Karagiannidis +4 more
TL;DR: This article reviews the existing research regarding the use of ML in nano-scale biomedical engineering and identifies the main challenges that can be formulated as ML problems, and discusses the state of the art ML methodologies used to countermeasure the aforementioned challenges.
37
References
Gradient-based learning applied to document recognition
Yann LeCun,Léon Bottou,Léon Bottou,Yoshua Bengio,Yoshua Bengio,Yoshua Bengio,Patrick Haffner +6 more
- 01 Jan 1998
TL;DR: In this article, a graph transformer network (GTN) is proposed for handwritten character recognition, which can be used to synthesize a complex decision surface that can classify high-dimensional patterns, such as handwritten characters.
53.5K
Crystal statistics. I. A two-dimensional model with an order-disorder transition
TL;DR: In this article, the eigenwert problem involved in the corresponding computation for a long strip crystal of finite width, joined straight to itself around a cylinder, is solved by direct product decomposition; in the special case $n=\ensuremath{\infty}$ an integral replaces a sum.
6.7K
Fault tolerant quantum computation by anyons
TL;DR: A two-dimensional quantum system with anyonic excitations can be considered as a quantum computer Unitary transformations can be performed by moving the excitations around each other Unitary transformation can be done by joining excitations in pairs and observing the result of fusion.
5.5K
Topological entanglement entropy
TL;DR: The von Neumann entropy of rho, a measure of the entanglement of the interior and exterior variables, has the form S(rho) = alphaL - gamma + ..., where the ellipsis represents terms that vanish in the limit L --> infinity.
Detecting Topological Order in a Ground State Wave Function
Michael Levin,Xiao-Gang Wen +1 more
TL;DR: A way to detect a kind of topological order using only the ground state wave function which directly measures the total quantum dimension D= Sum(id2i).
2.5K
Related Papers (5)
[...]