Jia Ning Leaw scite author profile

The role of electron-electron interactions in two-dimensional Dirac fermion systems remains enigmatic. Using a combination of nonperturbative numerical and analytical techniques that incorporate both the contact and long-range parts of the Coulomb interaction, we identify the two previously discussed regimes: a Gross-Neveu transition to a strongly correlated Mott insulator and a semimetallic state with a logarithmically diverging Fermi velocity accurately described by the random phase approximation. We predict that experimental realizations of Dirac fermions span this crossover and that this determines whether the Fermi velocity is increased or decreased by interactions. We explain several long-standing mysteries, including why the observed Fermi velocity in graphene is consistently about 20% larger than values obtained from ab initio calculations and why graphene on different substrates shows different behaviors.

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Singlet superconductivity enhanced by charge order in nested twisted bilayer graphene Fermi surfaces

Laksono

Leaw

Reaves

et al. 2018

Solid State Communications

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Using the continuum model for low energy non-interacting electronic structure of moiré van der Waals heterostructures developed by Bistritzer and MacDonald [1] , we study the competition between spin, charge, and superconducting order in twisted bilayer graphene. Surprisingly, we find that for a range of small angles inclusive of the so-called magic angle, this model features robust Fermi pockets that preclude any Mott insulating phase at weak coupling. However, a Fermi surface reconstruction at θ 1.2 • gives emergent van Hove singularities without any Fermi pockets. Using a hot-spot model for Fermi surface patches around these emergent saddle points, we develop a random-phase approximation from which we obtain a phase diagram very similar to that obtained recently by Isobe, Yuan, and Fu using the parquet renormalization group [2] but with additional insights. For example, our model shows strong nesting around time-reversal symmetric points at a moderate doping of ∼ 2 × 10 11 cm −2 away from the van Hove singularity. When this nesting dominates, we predict that charge-order enhances singlet superconductivity, while spin-order suppresses superconductivity. Our theory also provides additional possibilities for the case of unnested Fermi surfaces.

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Antiferromagnetism and chiral d -wave superconductivity from an effective t−J−D model for twisted bilayer graphene

Gu¹,

Chen²,

Leaw³

et al. 2020

Phys. Rev. B

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Universal Fermi-surface anisotropy renormalization for interacting Dirac fermions with long-range interactions

Leaw

Tang

Trushin

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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Recent experimental (1) and numerical (2) evidence suggest an intriguing universal relationship between the Fermi surface anisotropy of the non-interacting parent two-dimensional electron gas and the strongly correlated composite Fermi liquid formed in a strong magnetic field close to half-filling. Inspired by these observations, we explore more generally the question of anisotropy renormalization in interacting 2D Fermi systems. Using a recently developed (3) nonperturbative and numerically-exact projective quantum Monte Carlo simulation as well as other numerical and analytic techniques, only for Dirac fermions with long-range Coulomb interactions do we find a universal square-root decrease of the Fermi-surface anisotropy. For the ν = 1/2 composite Fermi liquid, this result is surprising since a Dirac fermion ground state (4) was only recently proposed as an alternative to the usual HLR state (5). The importance of the long-range interaction, expected for Dirac systems (6), is also consistent with recent transport measurements (7). Our proposed universality can be tested in several anisotropic Dirac materials including graphene, topological insulators (8), organic conductors (9), and magic-angle twisted bilayer graphene (10). Dirac fermions | Fermi surface anisotropy | Composite fermions

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Strategic insights from playing quantum tic-tac-toe

Leaw¹,

Cheong²

2010

J. Phys. A: Math. Theor.

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Abstract. In this paper, we perform a minimalistic quantization of the classical game of tic-tac-toe, by allowing superpositions of classical moves. In order for the quantum game to reduce properly to the classical game, we require legal quantum moves to be orthogonal to all previous moves. We also admit interference effects, by squaring the sum of amplitudes over all moves by a player to compute his or her occupation level of a given site. A player wins when the sums of occupations along any of the eight straight lines we can draw in the 3 × 3 grid is greater than three. We play the quantum tic-tactoe first randomly, and then deterministically, to explore the impact different opening moves, end games, and different combinations of offensive and defensive strategies have on the outcome of the game. In contrast to the classical tic-tac-toe, the deterministic quantum game does not always end in a draw. In contrast also to most classical twoplayer games of no chance, it is possible for Player 2 to win. More interestingly, we find that Player 1 enjoys an overwhelming quantum advantage when he opens with a quantum move, but loses this advantage when he opens with a classical move. We also find the quantum blocking move, which consists of a weighted superposition of moves that the opponent could use to win the game, to be very effective in denying the opponent his or her victory. We then speculate what implications these results might have on quantum information transfer and portfolio optimization.

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Jia Ning Leaw

The role of electron-electron interactions in two-dimensional Dirac fermions

Singlet superconductivity enhanced by charge order in nested twisted bilayer graphene Fermi surfaces

Antiferromagnetism and chiral d -wave superconductivity from an effective t−J−D model for twisted bilayer graphene

Universal Fermi-surface anisotropy renormalization for interacting Dirac fermions with long-range interactions

Strategic insights from playing quantum tic-tac-toe

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