REVIEW 5 minor 56 references
Slowly modulated aperiodic crystals admit localized approximate eigenfunctions whose energies are set by effective Landau or oscillator operators (with an extra energy shift).
Reviewed by Pith at T0; open to challenge. T0 means a machine referee read the full paper against a public rubric. the ladder, T0–T4 →
T0 review · grok-4.5
2026-07-10 09:26 UTC pith:BIBPRKXU
load-bearing objection Solid, self-contained construction of L^{2} approximate eigenfunctions for two-scale aperiodic Hamiltonians that recovers Simon, Landau levels (with Zeeman shift), honeycomb Dirac, and almost-flat bands under explicit spectral assumptions.
Approximate eigenfunctions for some aperiodic crystals
The pith
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
Under a local spectral-gap and homogeneous-degree-m expansion assumption on the Bloch family h(k,X) about a point (k0,X0), the aperiodic Hamiltonian H_ε admits localized approximate eigenfunctions Φ_ε whose energies are e0 plus ε^{m/2} times an eigenvalue of an effective matrix operator built from the leading homogeneous symbol (plus an explicit constant matrix correction when m=2). The residual is O(ε^{m/2+1/4}) and the L2-norm of Φ_ε equals the reciprocal square-root of the cell volume plus O(√ε).
What carries the argument
The reduction identity that replaces H_ε acting on a Bloch wave packet by an effective two-scale operator heff_ε (split into a band-edge part heff_1,ε and a non-uniform-density correction heff_2,ε), followed by a WKB construction of approximate eigenpairs of heff_ε that are then lifted back to the original space.
Load-bearing premise
The Bloch eigenvalues and eigenfunctions must admit a homogeneous polynomial expansion of exact degree one or two (with a spectral gap) in a shrinking neighborhood of the special point; any higher-order or non-homogeneous remainder would destroy the claimed residual size.
What would settle it
Take a concrete one-dimensional Schrödinger operator whose band edge is quadratic, compute the exact density of states or the lowest eigenvalues of a large supercell for several small ε, and check whether the predicted oscillator eigenvalues (including the constant energy shift) reproduce the observed peaks within the stated O(ε^{5/4}) tolerance.
If this is right
- Near van-Hove points or Dirac cones the spectrum of H_ε contains discrete approximate eigenvalues given by Landau or harmonic-oscillator levels (plus an explicit constant shift when m=2).
- For rational ε=p/q the same construction produces an almost-flat band of width O(ε^{m/2+1/4}) in the Bloch decomposition over the supercell Brillouin zone.
- Two-particle systems with weak interaction inherit approximate eigenfunctions whose energies are those of the corresponding two-particle Landau/Dirac operator plus the interaction potential.
- The same wave-packet recipe applies verbatim to any dimension and to both Schrödinger and Dirac kinetic terms once the local band geometry is known.
Where Pith is reading between the lines
- The constant matrix correction that appears for m=2 is the continuum analogue of a Zeeman term; its presence suggests that any higher-order effective Hamiltonian will systematically generate magnetic-moment corrections from the same commutator structure.
- Because the construction only needs local information about the Bloch family, it can be turned into a practical numerical scheme that extracts approximate eigenfunctions of large aperiodic systems from a single small-cell band-structure calculation.
- If the homogeneous expansion can be pushed to higher order, the residual can be improved beyond O(ε^{m/2+1/4}), opening a route to sharper almost-flat-band estimates for incommensurate moiré materials.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The paper constructs localized approximate eigenfunctions for two-scale aperiodic Hamiltonians H_ε = T(-i∇_x + A(x,εx)) + V(x,εx) (Schrödinger or Dirac) when the Bloch family h(k,X) admits a multiplicity-J spectral gap and a homogeneous degree-m (m=1 or 2) expansion of eigenvalues and eigenfunctions about a point (k0,X0) (Assumption 3.1). Theorems 3.3 and 3.5 produce wave-packet states Φ_ε built from the Bloch modes and the eigenfunctions of an effective operator (Landau–Dirac, Landau–Schrödinger, or quantum harmonic oscillator, possibly with a constant energy shift ĂM) such that ||(H_ε - e0 - ε^{m/2} μ) Φ_ε|| = O(ε^{m/2 + 1/4}) with ||Φ_ε|| = |Ω|^{-1/2} + O(√ε). The proofs proceed by a reduction of H_ε to an effective Hamiltonian h_eff_ε (Theorem 9.2) followed by a WKB construction; applications recover quantum-oscillator approximations, integer and fractional quantum Hall effects (including honeycomb Dirac cones), and almost-flat bands for rational supercells.
Significance. The work supplies a unified, rigorous semiclassical framework that produces quantum (rather than purely classical) effective Hamiltonians for aperiodic crystals and recovers several physically important models as special cases. The energy-shift term ĂM for m=2 is new and is shown to arise from a Zeeman-type contribution; it improves the density-of-states approximation of Cancès–Massatt–Meng–Polack–Quan. The reduction Theorem 9.2 and the explicit residual O(ε^{m/2+1/4}) are clean and track all cut-off and Taylor remainders. The almost-flat-band statement for rational ε and the two-particle fractional-Hall constructions further enlarge the range of applications. The paper therefore constitutes a solid contribution to mathematical physics of aperiodic media.
minor comments (5)
- The cut-off exponents s1, s2 defined in Assumption 3.1 appear repeatedly; a short remark explaining why the particular combination 1/(2nd(m+1)) is chosen would help the reader follow the error bookkeeping in Section 10.
- In the abstract and Introduction the residual is written O(ε^{m/2 + 1/4}); the same exponent appears in Theorems 3.3 and 3.5. A parenthetical note that the 1/4 is an artifact of the L2-norm of the cut-off remainder (and could be improved under stronger decay) would clarify optimality.
- Figure 1 is referenced as improving the DoS approximation of [9], but the caption does not state the precise value of the shift ĂM used for the green curve; adding that number would make the figure self-contained.
- A few typographical inconsistencies remain (e.g., “Trepresents”, “xÞÑ”, missing spaces around operators). A careful copy-edit pass would remove them.
- Assumption 11.1 for the two-particle problem is left unverified; while the Laughlin wave-functions are known to satisfy the required decay, a one-sentence reference or remark would close the logical gap.
Circularity Check
No circularity: approximate eigenfunctions and residuals are derived from Assumption 3.1 via explicit Bloch/Weyl reduction and WKB, with no fitted parameters or self-referential definitions.
full rationale
The central claims (Theorems 3.3 and 3.5) take as input the local spectral gap and homogeneous degree-m expansions of eigenvalues/eigenfunctions of the family h(k,X) stated in Assumption 3.1. From these the paper constructs the effective operators h_eff_ε (eqs. 8.1–8.3, 8.10–8.11) by Taylor expansion of the projected symbol (3.12), reduces H_ε Φ_ε to Φ_ε h_eff_ε by Bloch transform + Weyl quantization + cut-off estimates (Theorem 9.2 and Lemmas 10.2–10.7), and obtains the residual O(ε^{m/2+1/4}) by a finite-order WKB ansatz on the effective problem (Corollary 9.4). All steps are self-contained calculations; the energy-shift matrix ĂM (3.23) arises algebraically from the same expansion and is not presupposed. Applications (Sections 4–7, 11) simply verify Assumption 3.1 by standard perturbation theory for concrete models and recover known special cases (Simon, Landau levels, Dirac cones) as corollaries. Self-citations appear only for technical lemmas or numerical illustrations and are not load-bearing for the residual bounds. No parameter is fitted to data and then re-used as a prediction, and no uniqueness or ansatz is imported by self-citation. The derivation is therefore non-circular.
Axiom & Free-Parameter Ledger
axioms (3)
- domain assumption Potentials A(x,X), V(x,X) are C^∞ and L-periodic in x (and, for the flat-band section, also in X).
- domain assumption Assumption 3.1: local multiplicity-J gap and homogeneous degree-m expansion of Bloch eigenvalues/eigenfunctions about (k0,X0).
- standard math Standard functional-analytic facts (self-adjointness of magnetic Schrödinger/Dirac operators, Weyl quantization calculus, Poisson summation for Bloch transform).
read the original abstract
In this paper, we consider Hamiltonians for aperiodic crystals of the form \begin{align*} H_\varepsilon:=T(-i\nabla_x+{\mathbf A}(x,\varepsilon x))+V(x,\varepsilon x),\qquad x\in {\mathbb R}^d \end{align*} where $T$ represents either a Dirac operators or a Schr\"odinger operator, and $x\mapsto {\mathbf A}(x,X)$ and $x\mapsto V(x,X)$ are $\mathbb L$-periodic with respect to some lattice $\mathbb L\subset{\mathbb R}^d$. Let \begin{align*} (k,X)\ni {\mathbb R}^d\times {\mathbb R}^d\mapsto h(k,X):=T(-i\nabla_x+k+{\mathbf A}(x,X))+V(x,X) \end{align*} be a family of operators acting on $L^2_{\rm per}(\mathbb{R}^d/\mathbb{L})$ with periodic boundary conditions. We show that, under some suitable assumptions on the family of operators $ (h(k,X))_{k,X}$ around an energy level $e_0\in {\mathbb R}$ and some points $(k_0,X_0)\in {\mathbb R}^d\times {\mathbb R}^d$, one can construct localized approximate eigenfunctions $\Phi_\varepsilon\in L^2({\mathbb R}^d)$ of the operator $H_\varepsilon$ such that for $\varepsilon$ small enough and for some $m\in \{1,2\}$ and $\mu\in {\mathbb R}$, \begin{align}\label{eq:abstract} \|(H_\varepsilon-e_0-\varepsilon^{\frac{m}{2}}\mu)\Phi_\varepsilon\|_{L^2({\mathbb R}^d)}={\mathcal O}(\varepsilon^{\frac{m}{2}+\frac{1}{4}}). \end{align} with \begin{align*} \|\Phi_\varepsilon\|_{L^2({\mathbb R}^d)}=\frac{1}{|{\mathbb R}^d/\mathbb L|^{1/2}}+{\mathcal O}(\sqrt{\varepsilon}). \end{align*}
Figures
Reference graph
Works this paper leans on
-
[1]
Continuum honeycomb Schr\"odinger operators with incommensurate line defects
Pierre Amenoagbadji and Michael I Weinstein. “Continuum honeycomb Schrödinger operators with incommensurate line defects”. In:arXiv preprint arXiv:2604.16712(2026)
work page internal anchor Pith review Pith/arXiv arXiv 2026
-
[2]
Artur Avila and Svetlana Jitomirskaya. “The Ten Martini Problem”. In:Ann. of Math. (2)170.1 (2009), pp. 303–342
work page 2009
-
[3]
Mathematics of magic angles in a model of twisted bilayer graphene
S. Becker, M. Embree, J. Wittsten, and M. Zworski. “Mathematics of magic angles in a model of twisted bilayer graphene”. In:Probab. Math. Phys.3.1 (2022), pp. 69–103
work page 2022
-
[4]
Semiclassical quantization conditions in strained moiré lat- tices
Simon Becker and Jens Wittsten. “Semiclassical quantization conditions in strained moiré lat- tices”. In:Comm. Math. Phys.405.9 (2024), Paper No. 218, 48
work page 2024
-
[5]
The noncommutative geometry of the quantum Hall effect
Jean Bellissard, Andreas van Elst, and Hermann Schulz-Baldes. “The noncommutative geometry of the quantum Hall effect”. In:Journal of Mathematical Physics35.10 (1994), pp. 5373–5451
work page 1994
-
[6]
Moiré bands in twisted double-layer graphene
Rafi Bistritzer and Allan H. MacDonald. “Moiré bands in twisted double-layer graphene”. In: Proceedings of the National Academy of Sciences108.30 (2011), pp. 12233–12237
work page 2011
-
[7]
Anderson localization for Schrödinger operators onZ 2 with quasi-periodic potential
Jean Bourgain, Michael Goldstein, and Wilhelm Schlag. “Anderson localization for Schrödinger operators onZ 2 with quasi-periodic potential”. In:Acta Math.188.1 (2002), pp. 41–86
work page 2002
-
[8]
Simple derivation of moiré-scale continuous models for twisted bilayer graphene
Eric Cancès, Louis Garrigue, and David Gontier. “Simple derivation of moiré-scale continuous models for twisted bilayer graphene”. In:Phys. Rev. B107 (15 2023), p. 155403
work page 2023
-
[9]
Numerical compu- tation of the density of states of aperiodic multiscale Schrödinger operators
Eric Cancès, Daniel Massatt, Long Meng, Étienne Polack, and Xue Quan. “Numerical compu- tation of the density of states of aperiodic multiscale Schrödinger operators”. In:to appear in SIAM Journal on Scientific Computing(2026)
work page 2026
-
[10]
Semiclassical analysis of two-scale electronic Hamiltonians for twisted bilayer graphene
Eric Cancès and Long Meng. “Semiclassical analysis of two-scale electronic Hamiltonians for twisted bilayer graphene”. In:arXiv preprint arXiv:2311.14011(2023)
work page internal anchor Pith review Pith/arXiv arXiv 2023
-
[11]
Duality between atomic configurations and Bloch states in twistronic materials
Stephen Carr, Daniel Massatt, Mitchell Luskin, and Efthimios Kaxiras. “Duality between atomic configurations and Bloch states in twistronic materials”. In:Phys. Rev. Res.2 (3 2020), p. 033162
work page 2020
-
[12]
Effective mass theorems with Bloch modes crossings
Victor Chabu, Clotilde Fermanian Kammerer, and Fabricio Macià. “Effective mass theorems with Bloch modes crossings”. In:Arch. Ration. Mech. Anal.245.3 (2022), pp. 1339–1400
work page 2022
-
[13]
Derivation of Kubo’s formula for disordered systems at zero temperature
Wojciech De Roeck, Alexander Elgart, and Martin Fraas. “Derivation of Kubo’s formula for disordered systems at zero temperature”. In:Invent. Math.235.2 (2024), pp. 489–568
work page 2024
-
[14]
Pseudospectra of semiclassical (pseudo-) differential operators
Nils Dencker, Johannes Sjöstrand, and Maciej Zworski. “Pseudospectra of semiclassical (pseudo-) differential operators”. In:Comm. Pure Appl. Math.57.3 (2004), pp. 384–415
work page 2004
-
[15]
Développementsasymptotiquesdesperturbationslentesdel’opérateurdeSchrödinger périodique
MouezDimassi.“Développementsasymptotiquesdesperturbationslentesdel’opérateurdeSchrödinger périodique”. In:Comm. Partial Differential Equations18.5-6 (1993), pp. 771–803
work page 1993
-
[16]
Adiabatic charge transport and the Kubo formula for Landau-type Hamiltonians
Alexander Elgart and Benjamin Schlein. “Adiabatic charge transport and the Kubo formula for Landau-type Hamiltonians”. In:Comm. Pure Appl. Math.57.5 (2004), pp. 590–615
work page 2004
-
[17]
Zyun Francis Ezawa.Quantum Hall Effects. 3rd. World Ssientific, 2013
work page 2013
-
[18]
Honeycomb Schrödinger operators in the strong binding regime
Charles L. Fefferman, James P. Lee-Thorp, and Michael I. Weinstein. “Honeycomb Schrödinger operators in the strong binding regime”. In:Comm. Pure Appl. Math.71.6 (2018), pp. 1178–1270
work page 2018
-
[19]
Honeycomb lattice potentials and Dirac points
Charles L. Fefferman and Michael I. Weinstein. “Honeycomb lattice potentials and Dirac points”. In:J. Amer. Math. Soc.25.4 (2012), pp. 1169–1220
work page 2012
-
[20]
Wave packets in honeycomb structures and two-dimensional Dirac equations
Charles L. Fefferman and Michael I. Weinstein. “Wave packets in honeycomb structures and two-dimensional Dirac equations”. In:Comm. Math. Phys.326.1 (2014), pp. 251–286
work page 2014
-
[21]
Sharp regularity results for Coulombic many-electron wave functions
Søren Fournais, Maria Hoffmann-Ostenhof, Thomas Hoffmann-Ostenhof, and Thomas Øster- gaard Sørensen. “Sharp regularity results for Coulombic many-electron wave functions”. In: Comm. Math. Phys.255.1 (2005), pp. 183–227
work page 2005
-
[22]
A mathematical approach to the effective Hamiltonian in perturbed periodic problems
C. Gérard, A. Martinez, and J. Sjöstrand. “A mathematical approach to the effective Hamiltonian in perturbed periodic problems”. In:Comm. Math. Phys.142.2 (1991), pp. 217–244
work page 1991
-
[23]
Homogenization limits and Wigner transforms
PatrickGérard,PeterA.Markowich,NorbertJ.Mauser,andFrédéricPoupaud.“Homogenization limits and Wigner transforms”. In:Comm. Pure Appl. Math.50.4 (1997), pp. 323–379. 60
work page 1997
-
[24]
Dynamical delocalization in random Landau Hamiltonians
François Germinet, Abel Klein, and Jeffrey H. Schenker. “Dynamical delocalization in random Landau Hamiltonians”. In:Ann. of Math. (2)166.1 (2007), pp. 215–244
work page 2007
-
[25]
Universality of the Hall conduc- tivity in interacting electron systems
Alessandro Giuliani, Vieri Mastropietro, and Marcello Porta. “Universality of the Hall conduc- tivity in interacting electron systems”. In:Comm. Math. Phys.349.3 (2017), pp. 1107–1161
work page 2017
-
[26]
Michael Goldstein and Wilhelm Schlag. “Hölder continuity of the integrated density of states for quasi-periodic Schrödinger equations and averages of shifts of subharmonic functions”. In:Ann. of Math. (2)154.1 (2001), pp. 155–203
work page 2001
-
[27]
Puits de potentiel généralisés et asymptotique semi-classique
B. Helffer and D. Robert. “Puits de potentiel généralisés et asymptotique semi-classique”. In: vol. 41. 3. 1984, pp. 291–331
work page 1984
-
[28]
B. Helffer and J. Sjöstrand. “Analyse semi-classique pour l’équation de Harper (avec application à l’équation de Schrödinger avec champ magnétique)”. In:Mém. Soc. Math. France (N.S.)34 (1988), p. 113
work page 1988
-
[29]
Semiclassical analysis for Harper’s equation. III. Cantor structure of the spectrum
B. Helffer and J. Sjöstrand. “Semiclassical analysis for Harper’s equation. III. Cantor structure of the spectrum”. In:Mém. Soc. Math. France (N.S.)39 (1989), pp. 1–124
work page 1989
-
[30]
B. Helffer and J. Sjöstrand. “Analyse semi-classique pour l’équation de Harper. II. Comportement semi-classique près d’un rationnel”. In:Mém. Soc. Math. France (N.S.)40 (1990), p. 139
work page 1990
-
[31]
P. D. Hislop and I. M. Sigal.Introduction to spectral theory. Vol. 113. Applied Mathematical Sci- ences. With applications to Schrödinger operators. Springer-Verlag, New York, 1996, pp. x+337. isbn: 0-387-94501-6
work page 1996
-
[32]
Kai Jiang, Meng Li, Juan Zhang, and Lei Zhang. “Projection method for quasiperiodic elliptic equations and application to quasiperiodic homogenization”. In:SIAM J. Numer. Anal.63.5 (2025), pp. 1962–1985
work page 2025
-
[33]
Universal hierarchical structure of quasiperiodic eigen- functions
Svetlana Jitomirskaya and Wencai Liu. “Universal hierarchical structure of quasiperiodic eigen- functions”. In:Ann. of Math. (2)187.3 (2018), pp. 721–776
work page 2018
-
[34]
Metal-insulator transition for the almost Mathieu operator
Svetlana Ya. Jitomirskaya. “Metal-insulator transition for the almost Mathieu operator”. In:Ann. of Math. (2)150.3 (1999), pp. 1159–1175
work page 1999
-
[35]
Flat band in twisted bilayer Bravais lattices
Toshikaze Kariyado and Ashvin Vishwanath. “Flat band in twisted bilayer Bravais lattices”. In: Phys. Rev. Res.1 (3 2019), p. 033076
work page 2019
-
[36]
On Mott’s formula for the ac-conductivity in the Anderson model
Abel Klein, Olivier Lenoble, and Peter Müller. “On Mott’s formula for the ac-conductivity in the Anderson model”. In:Ann. of Math. (2)166.2 (2007), pp. 549–577
work page 2007
-
[37]
R. B. Laughlin. “Anomalous Quantum Hall Effect: An Incompressible Quantum Fluid with Frac- tionally Charged Excitations”. In:Phys. Rev. Lett.50 (18 1983), pp. 1395–1398
work page 1983
-
[38]
On the mixed regularity ofN-body Coulombic wavefunctions
Long Meng. “On the mixed regularity ofN-body Coulombic wavefunctions”. In:ESAIM Math. Model. Numer. Anal.57.4 (2023), pp. 2257–2282
work page 2023
-
[39]
A rigorous justification of the Mittleman’s approach to the Dirac-Fock model
Long Meng. “A rigorous justification of the Mittleman’s approach to the Dirac-Fock model”. In: Calc. Var. Partial Differential Equations63.2 (2024), Paper No. 39, 29
work page 2024
-
[40]
Mit H. Naik and Manish Jain. “Ultraflatbands and Shear Solitons in Moiré Patterns of Twisted Bilayer Transition Metal Dichalcogenides”. In:Phys. Rev. Lett.121 (26 2018), p. 266401
work page 2018
-
[41]
Low energy bands do not contribute to quantum Hall effect
S. Nakamura and J. Bellissard. “Low energy bands do not contribute to quantum Hall effect”. In:Comm. Math. Phys.131.2 (1990), pp. 283–305
work page 1990
-
[42]
Effective dynamics for Bloch electrons: Peierls substitution and beyond
Gianluca Panati, Herbert Spohn, and Stefan Teufel. “Effective dynamics for Bloch electrons: Peierls substitution and beyond”. In:Comm. Math. Phys.242.3 (2003), pp. 547–578
work page 2003
-
[43]
These pictures are calculated by Xue Quan
Xue Quan. These pictures are calculated by Xue Quan
-
[44]
Michael Reed and Barry Simon.Methods of modern mathematical physics. IV. Analysis of operators. Academic Press [Harcourt Brace Jovanovich, Publishers], New York-London, 1978, pp. xv+396.isbn: 0-12-585004-2
work page 1978
-
[45]
Emergent quantum Hall effects below 50 mT in a two-dimensional topo- logical insulator
Saquib Shamim et al. “Emergent quantum Hall effects below 50 mT in a two-dimensional topo- logical insulator”. In:Science Advances6.26 (2020), eaba4625
work page 2020
-
[46]
Tight-binding reduction and topological equivalence in strong magnetic fields
Jacob Shapiro and Michael I. Weinstein. “Tight-binding reduction and topological equivalence in strong magnetic fields”. In:Adv. Math.403 (2022), Paper No. 108343, 70. 61
work page 2022
-
[47]
Almost periodic Schrödinger operators: a review
Barry Simon. “Almost periodic Schrödinger operators: a review”. In:Adv. in Appl. Math.3.4 (1982), pp. 463–490
work page 1982
-
[48]
Semiclassical analysis of low lying eigenvalues. I. Nondegenerate minima: asymp- totic expansions
Barry Simon. “Semiclassical analysis of low lying eigenvalues. I. Nondegenerate minima: asymp- totic expansions”. In:Ann. Inst. H. Poincaré Sect. A (N.S.)38.3 (1983), pp. 295–308
work page 1983
-
[49]
Semiclassical analysis of low lying eigenvalues. II. Tunneling
Barry Simon. “Semiclassical analysis of low lying eigenvalues. II. Tunneling”. In:Ann. of Math. (2)120.1 (1984), pp. 89–118
work page 1984
-
[50]
Strain-induced quasi-1D channels in twisted Moiré lattices
Andreas Sinner, Pierre A. Pantaleón, and Francisco Guinea. “Strain-induced quasi-1D channels in twisted Moiré lattices”. In:Phys. Rev. Lett.131.16 (2023), Paper No. 166402, 7
work page 2023
-
[51]
Semiclassical approximations for Hamiltonians with operator-valued symbols
Hans-Michael Stiepan and Stefan Teufel. “Semiclassical approximations for Hamiltonians with operator-valued symbols”. In:Communications in Mathematical Physics320.3 (2013), pp. 821– 849
work page 2013
-
[52]
Stefan Teufel.Adiabatic perturbation theory in quantum dynamics. Vol. 1821. Lecture Notes in Mathematics. Springer-Verlag, Berlin, 2003, pp. vi+236.isbn: 3-540-40723-5
work page 2003
-
[53]
Texts and Monographs in Physics
Bernd Thaller.The Dirac equation. Texts and Monographs in Physics. Springer-Verlag, Berlin, 1992, pp. xviii+357.isbn: 3-540-54883-1
work page 1992
-
[54]
Time dependent approach to scattering from impurities in a crystal
Lawrence E. Thomas. “Time dependent approach to scattering from impurities in a crystal”. In: Comm. Math. Phys.33 (1973), pp. 335–343
work page 1973
-
[55]
Lectures on the Quantum Hall Effect
David Tong. “Lectures on the quantum Hall effect”. In:arXiv preprint arXiv:1606.06687(2016)
work page internal anchor Pith review Pith/arXiv arXiv 2016
-
[56]
Convergence of the planewave approximations for quantum incommensurate systems
Ting Wang, Huajie Chen, Aihui Zhou, Yuzhi Zhou, and Daniel Massatt. “Convergence of the planewave approximations for quantum incommensurate systems”. In:Multiscale Model. Simul. 23.1 (2025), pp. 545–576. 62
work page 2025
discussion (0)
Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.