Machine learning approach to study quantum phases of a frustrated one dimensional spin-1/2 system

Abstract

Frustration driven quantum fluctuation leads to many exotic phases in the ground state and study of these quantum phase transitions is one of the most challenging areas of research in condensed matter physics. Here, a frustrated Heisenberg J1-J2 model of spin-1/2 chain with nearest exchange interaction J1 and next nearest exchange interaction J2 is studied using the principal component analysis (PCA) which is an unsupervised machine learning technique. In this method most probable spin configurations (MPSC) of ground-state (GS) and first excited state (FES) for different J2/J1 are used as the input in PCA to construct the co-variance matrix. The `quantified principal component' of the largest eigenvalue of co-variance matrix p1(J2/J1) is calculated and it is shown that the nature and variation of p1(J2/J1) can accurately predict the phase transitions and degeneracies in the GS. The p1(J2/J1) calculated from the MPSC of GS can only exhibit the signature of degeneracies in the GS, whereas, p1(J2/J1) calculated from MPSC of FES captures the gapless spin liquid (GSL)-dimer phase transition as well as all the degeneracies of the model system. We show that jump in p1(J2/J1) of FES at J2/J1 ≈ 0.241, indicates the GSL-dimer phase transition, whereas its kinks give the signature of the GS degeneracies. The scatter plot of first two principal components of FES shows distinct band formation for different phases.