20 research outputs found
Candidate quantum disordered intermediate phase in the Heisenberg antiferromagnet on the maple-leaf lattice
Quantum antiferromagnets on geometrically frustrated lattices have long
attracted interest for the formation of quantum disordered states and the
possible emergence of quantum spin liquid (QSL) ground states. Here we turn to
the nearest-neighbor spin- Heisenberg antiferromagnet on the maple-leaf
lattice, which is known to relieve frustration by the formation of canted
magnetic order or valence bond crystal order when varying the
bond anisotropy. Employing a pseudo-fermion functional renormalization group
approach to assess its ground state phase diagram in detail, we present
evidence for a QSL regime sandwiched between these two limiting phases. The
formation of such a QSL might signal proximity to a possible deconfined quantum
critical point from which it emerges, and that is potentially accessible by
tuning the exchange couplings. Our conclusions are based on large-scale
simulations involving a careful finite-size scaling analysis of the behavior of
magnetic susceptibility and spin-spin correlation functions under
renormalization group flow.Comment: 7 pages, 6 figure
Generic Field-Driven Phenomena in Kitaev Spin Liquids: Canted Magnetism and Proximate Spin Liquid Physics
Topological spin liquids in two spatial dimensions are stable phases in the
presence of a small magnetic field, but may give way to field-induced phenomena
at intermediate field strengths. Sandwiched between the low-field spin liquid
physics and the high-field spin-polarized phase, the exploration of magnetic
phenomena in this intermediate regime however often remains elusive to
controlled analytical approaches. Here we numerically study such
intermediate-field magnetic phenomena for two representative Kitaev models (on
the square-octagon and decorated honeycomb lattice) that exhibit either Abelian
or non-Abelian topological order in the low-field limit. Using a combination of
exact diagonalization and density matrix renormalization group techniques, as
well as linear spin-wave theory, we establish the generic features of Kitaev
spin liquids in an external magnetic field. While ferromagnetic models
typically exhibit a direct transition to the polarized state at a relatively
low field strength, antiferromagnetic couplings not only substantially
stabilizes the topological spin liquid phase, but generically lead to the
emergence of a distinct field-induced intermediate regime, separated by a
crossover from the high-field polarized regime. Our results suggest that, for
most lattice geometries, this regime generically exhibits significant spin
canting, antiferromagnetic spin-spin correlations, and an extended proximate
spin liquid regime at finite temperatures. Notably, we identify a symmetry
obstruction in the original honeycomb Kitaev model that prevents, at least for
certain field directions, the formation of such canted magnetism without
breaking symmetries -- consistent with the recent numerical observation of an
extended gapless spin liquid in this case.Comment: 13 pages, 16 figures (Appendix: 7 pages, 7 figures
Quantum skyrmions in frustrated ferromagnets
We develop a quantum theory of magnetic skyrmions and antiskyrmions in a
spin-1/2 Heisenberg magnet with frustrating next-nearest neighbor interactions.
Using exact diagonalization we show numerically that a quantum skyrmion exists
as a stable many-magnon bound state and investigate its quantum numbers. We
then derive a phenomenological Schr\"odinger equation for the quantum skyrmion
and its internal degrees of freedom. We find that quantum skyrmions have highly
unusual properties. Their bandwidth is exponentially small and arises from
tunneling processes between skyrmion and antiskyrmion. The bandstructure
changes both qualitatively and quantitatively when a single spin is added or
removed from the quantum skyrmion, reflecting a locking of angular momentum and
spin quantum numbers characteristic for skyrmions. Additionally, while for weak
forces the quantum skyrmion is accelerated parallel to the force, it moves in a
perpendicular direction for stronger fields.Comment: 14 pages, 10 figures, added force-magnetization coupling and periodic
potential to skyrmion Hamiltonia
Partial flux ordering and thermal Majorana metals in (higher-order) spin liquids
In frustrated quantum magnetism, chiral spin liquids are a particularly
intriguing subset of quantum spin liquids in which the fractionalized parton
degrees of freedom form a Chern insulator. Here we study an exactly solvable
spin-3/2 model which harbors not only chiral spin liquids but also spin liquids
with higher-order parton band topology -- a trivial band insulator, a Chern
insulator with gapless chiral edge modes, and a second-order topological
insulator with gapless corner modes. With a focus on the thermodynamic
precursors and thermal phase transitions associated with these distinct states,
we employ numerically exact quantum Monte Carlo simulations to reveal a number
of unconventional phenomena. This includes a heightened thermal stability of
the ground state phases, the emergence of a partial flux ordering of the
associated lattice gauge field, and the formation of a thermal
Majorana metal regime extending over a broad temperature range.Comment: 18 page
TMDs as a platform for spin liquid physics: A strong coupling study of twisted bilayer WSe
The advent of twisted moir\'e heterostructures as a playground for strongly
correlated electron physics has led to a plethora of experimental and
theoretical efforts seeking to unravel the nature of the emergent
superconducting and insulating states. Amongst these layered compositions of
two dimensional materials, transition metal dichalcogenides (TMDs) are by now
appreciated as highly-tunable platforms to simulate reinforced electronic
interactions in the presence of low-energy bands with almost negligible
bandwidth. Here, we focus on the twisted homobilayer WSe and the insulating
phase at half-filling of the flat bands reported therein. More specifically, we
explore the possibility of realizing quantum spin liquid (QSL) physics on the
basis of a strong coupling description, including up to second nearest neighbor
Heisenberg couplings and , as well as Dzyaloshinskii-Moriya (DM)
interactions. Mapping out the global phase diagram as a function of an
out-of-plane displacement field, we indeed find evidence for putative QSL
states, albeit only close to SU symmetric points. In the presence of
finite DM couplings and XXZ anisotropy, long-range order is predominantly
present, with a mix of both commensurate and incommensurate magnetic phases.Comment: 12 pages, 5 figures, supplemental material (3 pages, 1 figure
Non-Coplanar Magnetic Orders in Classical Square-Kagome Antiferromagnets
Motivated by the recent synthesis of a number of Mott insulating
square-kagome materials, we explore the rich phenomenology of frustrated
magnetism induced by this lattice geometry, also referred to as the squagome or
shuriken lattice. On the classical level, square-kagome antiferromagnets are
found to exhibit extensive degeneracies, order-by-disorder, and non-coplanar
ordering tendencies, which we discuss for an elementary, classical Heisenberg
model with nearest-neighbor and cross-plaquette interactions. Having in mind
that upon introducing quantum fluctuations non-coplanar order can melt into
chiral quantum spin liquids, we provide detailed information on the multitude
of non-coplanar orders, including some which break rotational symmetry
(possibly leading to nematic quantum orders), as well as a number of
(incommensurate) spin spiral phases. Using extensive numerical simulations, we
also discuss the thermodynamic signatures of these phases, which often show
multi-step thermal ordering. Our comprehensive discussion of the classical
square-kagome Heisenberg model, often drawing comparisons to the conventional
kagome antiferromagnet, sets the stage for future explorations of quantum
analogs of the various phases, either conceptually such as in quantum spin-1/2
generalizations of our model or experimentally such as in the Cu-based
candidate materials.Comment: 24 pages, 27 figure
Haldane-Hubbard Mott Insulator: From Tetrahedral Spin Crystal to Chiral Spin Liquid
Motivated by cold atom experiments on Chern insulators, we study the honeycomb lattice Haldane-Hubbard Mott insulator of spin-1/2 fermions using exact diagonalization and density matrix renormalization group methods. We show that this model exhibits various chiral magnetic orders including a wide regime of triple-Q tetrahedral order. Incorporating third-neighbor hopping frustrates and ultimately melts this tetrahedral spin crystal. From analyzing the low energy spectrum, many-body Chern numbers, entanglement spectra, and modular matrices, we identify the molten state as a chiral spin liquid (CSL) with gapped semion excitations. We formulate and study the Chern-Simons-Higgs field theory of the exotic CSL-to-tetrahedral spin crystallization transition
Emergence of a field-driven U(1) spin liquid in the Kitaev honeycomb model
In the field of quantum magnetism, the exactly solvable Kitaev honeycomb
model serves as a paradigm for the fractionalization of spin degrees of freedom
and the formation of quantum spin liquids. An intense
experimental search has led to the discovery of a number of spin-orbit
entangled Mott insulators that realize its characteristic bond-directional
interactions and, in the presence of magnetic fields, exhibit no indications of
long-range order. Here, we map out the complete phase diagram of the Kitaev
model in tilted magnetic fields and report the emergence of a distinct gapless
quantum spin liquid at intermediate field strengths. Analyzing a number of
static, dynamical, and finite temperature quantities using numerical exact
diagonalization techniques, we find strong evidence that this phase exhibits
gapless fermions coupled to a massless gauge field. We discuss its
stability in the presence of perturbations that naturally arise in spin-orbit
entangled candidate materials.Comment: 9 pages, 9 figures, Supplemental Material (4 pages, 4 figures). Final
published versio
Elementary Building Blocks for Cluster Mott Insulators
<p>Mott insulators, in which strong Coulomb interactions fully localize electrons on single atomic sites, play host to an incredibly rich and exciting array of strongly correlated physics. One can naturally extend this concept to cluster Mott insulators, wherein electrons localize not on single atoms but across clusters of atoms, forming "molecules in solids''. The resulting localized degrees of freedom incorporate the full spectrum of electronic degrees of freedom, spin, orbital, and charge. These serve as the building blocks for cluster Mott insulators, and understanding them is an important first step toward understanding the many-body physics that emerges in candidate cluster Mott insulators. Here, we focus on elementary building blocks, neglecting some of the complexity present in real materials which can often obfuscate the underlying principles at play. Through an extensive set of exact theoretical calculations on clusters of varying geometry, number of orbitals, and number of electrons, we uncover some of the basic organizing principles of cluster Mott phases, particularly when interactions dominate and negate a simple single-particle picture.</p><p>In the accompanying paper (see link), we presented illustrative phase diagrams for different cluster geometries and select electron fillings. Here, we present the raw data and phase diagrams for all the remaining electron fillings on all cluster geometries obtained from exact diagonalization. The data is presented in Arrow files, with each Arrow file containing data such as eigenvalues, eigenvectors, ground state degeneracies, and various quantum numbers for a 21x21 U-J grid for all electron fillings, with the specific hopping values specified in the file name. The plots in the dataset have been derived from the respective raw data files.</p>