IAP Seminar (Magnetic Chirality)
Date : August 16, 2022 11:00 ~ 12:00
Speaker : Prof. Sang-Wook cheong (Rutgers University)
Professor : Prof. Je-Geun Park)
Location : 56-105
Magnetic Chirality
Chirality with all broken mirror symmetries, combined with any spatial rotations, matters ubiquitously from DNA functionality, vine climbing, to the piezoelectricity of quartz crystals. Magnetic chirality means chirality in spin ordered states or (atomic-scale or mesoscopic) spin textures. Magnetic chirality does not change with time reversal operation, and chirality prime (C¢) means that time reversal symmetry in addition to all mirror symmetries, combined with any spatial rotations, are broken. We can have magnetic chirality or chirality¢ in three different situations: [1] in centrosymmetric magnetic lattices while their crystallographic lattices are chiral, [2] in chiral magnetic lattices while their crystallographic lattices are also chiral, and [3] in centrosymmetric crystallographic lattices. In addition, there exist two kinds of C¢: type-I C¢ with unbroken space inversion Ä time reversal and type-II C¢ with broken space inversion Ä time reversal. Four examples of magnetic chirality will be discussed: helical spin state, magnetic toroidal moment combined with canted moment, magnetic quadruple moment combined with alternating canted moments, and Bloch-type skyrmions. We will also discuss a few examples of type-I C¢ type-II C¢, and the emergent physical phenomena of C and C¢. Some of these exotic phenomena have been recently observed, and many of them need to be experimentally confirmed.
Chirality with all broken mirror symmetries, combined with any spatial rotations, matters ubiquitously from DNA functionality, vine climbing, to the piezoelectricity of quartz crystals. Magnetic chirality means chirality in spin ordered states or (atomic-scale or mesoscopic) spin textures. Magnetic chirality does not change with time reversal operation, and chirality prime (C¢) means that time reversal symmetry in addition to all mirror symmetries, combined with any spatial rotations, are broken. We can have magnetic chirality or chirality¢ in three different situations: [1] in centrosymmetric magnetic lattices while their crystallographic lattices are chiral, [2] in chiral magnetic lattices while their crystallographic lattices are also chiral, and [3] in centrosymmetric crystallographic lattices. In addition, there exist two kinds of C¢: type-I C¢ with unbroken space inversion Ä time reversal and type-II C¢ with broken space inversion Ä time reversal. Four examples of magnetic chirality will be discussed: helical spin state, magnetic toroidal moment combined with canted moment, magnetic quadruple moment combined with alternating canted moments, and Bloch-type skyrmions. We will also discuss a few examples of type-I C¢ type-II C¢, and the emergent physical phenomena of C and C¢. Some of these exotic phenomena have been recently observed, and many of them need to be experimentally confirmed.