Your search keyword '"Cook, Caleb Q."' showing total 9 results

1. Hydrodynamics with triangular point group

Author

Friedman, Aaron J., Cook, Caleb Q., and Lucas, Andrew

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

When continuous rotational invariance of a two-dimensional fluid is broken to the discrete, dihedral subgroup $D_6$ - the point group of an equilateral triangle - the resulting anisotropic hydrodynamics breaks both spatial-inversion and time-reversal symmetries, while preserving their combination. In this work, we present the hydrodynamics of such $D_6$ fluids, identifying new symmetry-allowed dissipative terms in the hydrodynamic equations of motion. We propose two experiments - both involving high-purity solid-state materials with $D_6$-invariant Fermi surfaces - that are sensitive to these new coefficients in a $D_6$ fluid of electrons. In particular, we propose a local current imaging experiment (which is present-day realizable with nitrogen vacancy center magnetometry) in a hexagonal device, whose $D_6$-exploiting boundary conditions enable the unambiguous detection of these novel transport coefficients., Comment: 25+12 pages, 7+0 figures, 2+0 tables. v2: fixed typos. v3: revised version

Published

2022

2. Viscometry of electron fluids from symmetry

Author

Cook, Caleb Q. and Lucas, Andrew

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Fluid Dynamics

Abstract

When electrons flow as a viscous fluid in anisotropic metals, the reduced symmetry can lead to exotic viscosity tensors with many additional, nonstandard components. We present a viscometry technique that can, in principle, measure the multiple dissipative viscosities allowed in isotropic and anisotropic fluids alike. By applying representation theory to exploit the intrinsic symmetry of the fluid, our viscometry is also exceptionally robust to both boundary complications and ballistic effects. We present the technique via the illustrative example of dihedral symmetry, relevant in this context as the point symmetry of 2D crystals. Finally, we propose a present-day realizable experiment for detecting, in a metal, a novel hydrodynamic phenomenon: the presence of rotational dissipation in an otherwise isotropic fluid.

Published

2021

3. Electron hydrodynamics with a polygonal Fermi surface

Author

Cook, Caleb Q. and Lucas, Andrew

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Recent experiments have observed hints of hydrodynamic electron flow in a number of materials, not all of which have an isotropic Fermi surface. We revisit these experiments in $\mathrm{PdCoO}_2$, a quasi-two-dimensional material whose Fermi surface is a rounded hexagon, and observe that the data appears quantitatively consistent with a non-hydrodynamic interpretation. Nevertheless, motivated by such experiments, we develop a simple model for the low temperature kinetics and hydrodynamics of a two-dimensional Fermi liquid with a polygonal Fermi surface. A geometric effect leads to a finite number of additional long-lived quasihydrodynamic "imbalance" modes and corresponding qualitative changes in transport at the ballistic-to-hydrodynamic crossover. In the hydrodynamic limit, we find incoherent diffusion and a new dissipative component of the viscosity tensor arising from the explicit breaking of rotational invariance by the Fermi surface. Finally, we compute the conductance of narrow channels across the ballistic-to-hydrodynamic crossover and demonstrate a modification of the Gurzhi effect that allows for non-monotonic temperature and width dependence in the channel conductance., Comment: 27 + 11 pages (main text + appendices/references); 8+1 figures; 1+2 tables. v2: published version

Published

2019

4. Theory of chirped photonic crystals in biological broadband reflectors

Author

Cook, Caleb Q. and Amir, Ariel

Subjects

Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Biological Physics

Abstract

One-dimensional photonic crystals with slowly varying, i.e. "chirped", lattice period are responsible for broadband light reflectance in many diverse biological contexts, ranging from the shiny coatings of various beetles to the eyes of certain butterflies. We present a quantum scattering analogy for light reflection from these adiabatically chirped photonic crystals (ACPCs) and apply a WKB-type approximation to obtain a closed-form expression for the reflectance. From this expression we infer several design principles, including a differential equation for the chirp pattern required to elicit a given reflectance spectrum and the minimal number of bilayers required to exceed a desired reflectance threshold. Comparison of the number of bilayers found in ACPCs throughout nature and our predicted minimal required number also gives a quantitative measure of the optimality of chirped biological reflectors. Together these results elucidate the design principles of chirped reflectors in nature and their possible application to future optical technologies.

Published

2016

5. Shape dependence of two-cylinder Renyi entropies for free bosons on a lattice

Author

Chojnacki, Leilee, Cook, Caleb Q., Dalidovich, Denis, Sierens, Lauren E. Hayward, Lantagne-Hurtubise, Étienne, Melko, Roger G., and Vlaar, Tiffany J.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Universal scaling terms occurring in Renyi entanglement entropies have the potential to bring new understanding to quantum critical points in free and interacting systems. Quantitative comparisons between analytical continuum theories and numerical calculations on lattice models play a crucial role in advancing such studies. In this paper, we exactly calculate the universal two-cylinder shape dependence of entanglement entropies for free bosons on finite-size square lattices, and compare to approximate functions derived in the continuum using several different ansatzes. Although none of these ansatzes are exact in the thermodynamic limit, we find that numerical fits are in good agreement with continuum functions derived using the AdS/CFT correspondence, an extensive mutual information model, and a quantum Lifshitz model. We use fits of our lattice data to these functions to calculate universal scalars defined in the thin-cylinder limit, and compare to values previously obtained for the free boson field theory in the continuum., Comment: 7 pages, 5 figures, 1 table

Published

2016

6. Viscometry of Electron Fluids from Symmetry

Author

Cook, Caleb Q., primary and Lucas, Andrew, additional

Published

2021

7. Electron hydrodynamics with a polygonal Fermi surface

Author

Cook, Caleb Q., primary and Lucas, Andrew, additional

Published

2019

8. Theory of chirped photonic crystals in biological broadband reflectors

Author

Cook, Caleb Q., primary and Amir, Ariel, additional

Published

2016

9. Shape dependence of two-cylinder Rényi entropies for free bosons on a lattice

Author

Chojnacki, Leilee, primary, Cook, Caleb Q., additional, Dalidovich, Denis, additional, Hayward Sierens, Lauren E., additional, Lantagne-Hurtubise, Étienne, additional, Melko, Roger G., additional, and Vlaar, Tiffany J., additional

Published

2016