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1. A theory of time based on wavefunction collapse

Author

Lee, Sung-Sik

Subjects
General Relativity and Quantum Cosmology, High Energy Physics - Theory, Quantum Physics
Abstract

We propose that moments of time arise through the failed emergence of the temporal diffeomorphism as gauge symmetry, and that the passage of time is a continual process of an instantaneous state collapsing toward a gauge-invariant state. Unitarity and directedness of the resulting time evolution are demonstrated for a minisuperspace model of cosmology., Comment: 9 pages; v3) Sec. II and Appendix A expanded

Published
2024

2. Dynamical kinetic energy quenching in the antiferromagnetic quantum critical metals

Author

Borissov, Anton, Calvera, Vladimir, and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We study the dynamics of critical spin fluctuations and hot electrons at the metallic antiferromagnetic quantum critical points with $Z_2$ and $O(2)$ spin symmetries, building upon earlier works on the $O(3)$ symmetric theory. The interacting theories in $2+1$ dimensions are approached from $3+1$-dimensional theories in the $\epsilon$-expansion that tunes the co-dimension of Fermi surface as a control parameter. The low-energy physics of the $Z_2$ and $O(2)$ theories qualitatively differ from each other and also from that of the $O(3)$ theory. The difference is caused by higher-order quantum corrections beyond the one-loop order that are important even to the leading order in $\epsilon$. The naive loop-expansion breaks down due to dynamical quenching of kinetic energy: the speed of the collective mode ($c$) and the Fermi velocity perpendicular to the magnetic ordering vector ($v$) become vanishingly small at low energies. What sets the three theories apart is the hierarchy that emerges between the quenched kinetic terms. At the infrared fixed point, $c/v$ becomes $0$, $1$ and $\infty$ in the $Z_2$, $O(2)$ and $O(3)$ theories, respectively. At intermediate energy scales, the slow renormalization group (RG) flows of $c$ and $v$ toward their fixed point values create approximate scale invariance controlled by approximate marginal parameters. The manifold of those quasi-fixed points and the RG flow therein determines crossovers from scaling behaviours with transient critical exponents at intermediate energy scales to the universal scaling in the low-energy limit. If the symmetry group is viewed as a tuning parameter, the $O(2)$ theory corresponds to a multi-critical point which has one additional quasi-marginal parameter than the other two theories., Comment: 55 pages

Published
2024

3. Space of non-Fermi liquids

Author

Kukreja, Shubham, Besharat, Afshin, and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity
Abstract

In metals, low-energy effective theories are characterized by a set of coupling functions. Among them, the angle-dependent Fermi momentum specifies the size and shape of Fermi surface. Since the Fermi momentum grows incessantly under the renormalization group flow, a metallic fixed point is defined only modulo a rescaling of Fermi momentum. In this paper, we discuss the physical consequences of this projective nature of fixed points for non-Fermi liquids with hot Fermi surfaces. The first is the absence of a unique dynamical critical exponent that dictates the relative scaling between energy and momentum. The second is mismatches between the scaling dimensions of couplings and their relevancy. Nonetheless, each projective fixed point is characterized by a few marginal and relevant coupling functions, and the notion of universality survives. We illustrate our findings by charting the space of projective fixed points and extracting their universal properties for the Ising-nematic quantum critical metal beyond the patch theory. To control the theory, we use the dimensional regularization scheme that tunes the co-dimension of Fermi surface. Near the upper critical dimension, two exactly marginal coupling functions span the space of stable projective fixed points: functions that specify the shape of the Fermi surface and the angle-dependent Fermi velocity. All other coupling functions, including the Landau functions and the universal pairing interaction, are fixed by those two marginal functions. With decreasing dimensions, the forward scattering remains irrelevant while the pairing interaction becomes relevant near two dimensions. In two dimensions, it is expected that the universal superconducting fluctuations lower the symmetry of the non-Fermi liquid realized above the superconducting transition temperatures from the loop U(1) group to a proper subgroup., Comment: 71 pages; v3) Fig. 10b replaced

Published
2024
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4. Anomalous quasiparticle lifetime in geometric quantum critical metals

Author

Song, Hao, Ma, Han, Kallin, Catherine, and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Metals can undergo geometric quantum phase transitions where the local curvature of the Fermi surface changes sign without a change in symmetry or topology. At the inflection points on the Fermi surface, the local curvature vanishes, leading to an anomalous dynamics of quasiparticles. In this paper, we study geometric quantum critical metals that support inflection points in two dimensions, and show that the decay rate of quasiparticles goes as $E^{\alpha}$ with $1<\alpha<2$ as a function of quasiparticle energy $E$ at the inflection points., Comment: 7 pages, 4 figures

Published
2023

5. High mobility transport in isotopically-enriched $^{12}$C and $^{13}$C exfoliated graphene

Author

Iwakiri, Shuichi, Miller, Jakob, Lang, Florian, Prettenthaler, Jakob, Taniguchi, Takashi, Watanabe, Kenji, Lee, Sung Sik, Becker, Pascal, Günther, Detlef, Ihn, Thomas, and Ensslin, Klaus

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Graphene quantum dots are promising candidates for qubits due to weak spin-orbit and hyperfine interactions. The hyperfine interaction, controllable via isotopic purification, could be the key to further improving the coherence. Here, we use isotopically enriched graphite crystals of both $^{12}$C and $^{13}$C grown by high-pressure-high-temperature method to exfoliate graphene layers. We fabricated Hall bar devices and performed quantum transport measurements, revealing mobilities exceeding $10^{5}$$\textrm{cm}^{2}/Vs$ and a long mean free path of microns, which are as high as natural graphene. Shubnikov-de Haas oscillations, quantum Hall effect up to the filling factor of one, and Brown-Zak oscillations due to the alignment of hBN and graphene are observed thanks to the high mobility. These results constitute a material platform for physics and engineering of isotopically-enriched graphene qubits., Comment: 6 pages, 2 figures

Published
2023
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6. Holotomography

Author

Kim, Geon, Hugonnet, Herve, Kim, Kyoohyun, Lee, Jae-Hyuk, Lee, Sung Sik, Ha, Jeongmin, Lee, Chungha, Park, Hoewon, Yoon, Ki-Jun, Shin, Yongdae, Csucs, Gabor, Hitchcock, Ian, Mackinder, Luke, Kim, Ji Hyang, Hwang, Tae Hyun, Lee, Seongsoo, O’Toole, Peter, Koo, Bon-Kyoung, Guck, Jochen, and Park, YongKeun

Published
2024
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8. MicrobioRaman: an open-access web repository for microbiological Raman spectroscopy data

Author

Lee, Kang Soo, Landry, Zachary, Athar, Awais, Alcolombri, Uria, Pramoj Na Ayutthaya, Pratchaya, Berry, David, de Bettignies, Philippe, Cheng, Ji-Xin, Csucs, Gabor, Cui, Li, Deckert, Volker, Dieing, Thomas, Dionne, Jennifer, Doskocil, Ondrej, D’Souza, Glen, García-Timermans, Cristina, Gierlinger, Notburga, Goda, Keisuke, Hatzenpichler, Roland, Henshaw, Richard J., Huang, Wei E., Iermak, Ievgeniia, Ivleva, Natalia P., Kneipp, Janina, Kubryk, Patrick, Küsel, Kirsten, Lee, Tae Kwon, Lee, Sung Sik, Ma, Bo, Martínez-Pérez, Clara, Matousek, Pavel, Meckenstock, Rainer U., Min, Wei, Mojzeš, Peter, Müller, Oliver, Kumar, Naresh, Nielsen, Per Halkjær, Notingher, Ioan, Palatinszky, Márton, Pereira, Fátima C., Pezzotti, Giuseppe, Pilat, Zdenek, Plesinger, Filip, Popp, Jürgen, Probst, Alexander J., Riva, Alessandra, Saleh, Amr. A. E., Samek, Ota, Sapers, Haley M., Schubert, Olga T., Stubbusch, Astrid K. M., Tadesse, Loza F., Taylor, Gordon T., Wagner, Michael, Wang, Jing, Yin, Huabing, Yue, Yang, Zenobi, Renato, Zini, Jacopo, Sarkans, Ugis, and Stocker, Roman

Published
2024
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9. Emergence of curved momentum-spacetime and its effect on the cyclotron motion in the antiferromagnetic quantum critical metal

Author

Borges, Francisco and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We show that anisotropic quantum corrections can dynamically give rise to curved momentum-spacetimes for quasiparticles in metals. In the (2+1)-dimensional antiferromagnetic quantum critical metal, a curved momentum-spacetime arises as the critical spin fluctuations generate red shift that dilates frequency of electron unevenly on the Fermi surface. As the disparity of the momentum-dependent red shift is controlled by the shape of the Fermi surface, the momentum-spacetime geometry that emerges at low energies depends on the bare nesting angle of the Fermi surface. With increasing nesting angle, the region in which electron motion is slowed down by critical spin fluctuations shrinks. On the other hand, the increasing nesting angle makes the red shift stronger near the hot spots due to the weakened screening of the interaction. These competing effects result in a non-monotonic dependence of the cyclotron frequency of electron on the nesting angle of the Fermi surface. The red shift that becomes more singular at the hot spots with increasing nesting angle creates a possibility of realizing a momentum-space black hole horizon beyond a critical nesting angle : the electron motion becomes `perpetually' slowed down as it approaches a hot spot in the same way that the motion of a free falling object freezes near the event horizon of a black hole with respect to an asymptotic observer. However, the analogous horizon in momentum space does not lead to a vanishing cyclotron frequency because the metric singularity at the hot spots is cut off by thermal effects present above the non-zero superconducting transition temperature., Comment: 22 pages

Published
2023
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10. Fermi liquids beyond the forward scattering limit: the role of non-forward scatterings for scale invariance and instabilities

Author

Ma, Han and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Landau Fermi liquid theory is a fixed point theory of metals that includes the forward scattering amplitudes as exact marginal couplings. However, the fixed point theory that only includes the strict forward scatterings is non-local in real space. In this paper, we revisit the Fermi liquid theory using the field-theoretic functional renormalization group formalism and show how the scale invariant fixed point emerges as a local theory, which includes not only the forward scatterings but also non-forward scatterings with small but non-zero momentum transfers. In the low-energy limit, the non-forward scattering amplitude takes a scale invariant form. If the bare coupling is attractive beyond a critical strength, the coupling function exhibits a run-away flow drived by non-forward scattering amplitudes, signifying potential instabilities in particle-hole channels. The pairing interaction also obeys a scaling relation if the center of mass momentum of Cooper pairs is comparable with energy. The coupling functions fully capture the universal low-energy dynamics of the collective modes and instabilities of Fermi liquids. The divergence of the cocupling function in the particle-hole channel beyond a critical interaction suggests an instability toward an ordered phase with a momentum that depends on the interaction strength. At the critical interaction, the instability corresponds to the uniform Pomeranchuk or Stoner instability, but the momentum of the leading instability becomes non-zero for stronger attractive interaction. In the particle-particle channel, the coupling function reveals the dynamics of the unstable mode associated with the BCS instability. When an unstable normal metal evolves into the superconducting state, there exists a period in which a superconducting state with spatially non-uniform phase appears due to the presence of unstable Cooperon modes with non-zero momenta., Comment: 35 pgs. Experimental consequences added

Published
2023
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11. Massless graviton in a model of quantum gravity with emergent spacetime

Author

Lee, Sung-Sik

Subjects
High Energy Physics - Theory, General Relativity and Quantum Cosmology
Abstract

In the model of quantum gravity proposed in JHEP 2020, 70 (2020), dynamical spacetime arises as a collective phenomenon of underlying quantum matter. Without a preferred decomposition of the Hilbert space, the signature, topology and geometry of an emergent spacetime depend upon how the total Hilbert space is partitioned into local Hilbert spaces. In this paper, it is shown that the massless graviton emerges in the spacetime realized from a Hilbert space decomposition that supports a collection of largely unentangled local clocks.

Published
2022
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12. Field-theoretic functional renormalization group formalism for non-Fermi liquids and its application to the antiferromagnetic quantum critical metal in two dimensions

Author

Borges, Francisco, Borissov, Anton, Singh, Ashutosh, Schlief, Andres, and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

To capture the universal low-energy physics of metals within effective field theories, one has to generalize the usual notion of scale invariance and renormalizable field theory due to the presence of intrinsic scales (Fermi momenta). In this paper, we develop a field-theoretic functional renormalization group formalism for full low-energy effective field theories of non-Fermi liquids that include all gapless modes around the Fermi surface. The formalism is applied to the non-Fermi liquid that arises at the antiferromagnetic quantum critical point in two space dimensions. In the space of coupling functions, an interacting fixed point arises at a point with momentum-independent couplings and vanishing nesting angle. In theories deformed with non-zero nesting angles, coupling functions acquire universal momentum profiles controlled by the bare nesting angles at low energies before flowing to superconducting states in the low-energy limit. The superconducting instability is unavoidable because lukewarm electrons that are coherent enough to be susceptible to pairing end up being subject to a renormalized attractive interaction with its minimum strength set by the nesting angle. Despite the inevitable superconducting instability, theories with small bare nesting angles and bare four-fermion couplings that are repulsive or weakly attractive must pass through the region with slow RG flow due to the proximity to the non-Fermi liquid fixed point. The bottleneck region controls the scaling behaviours of the normal state and the quasi-universal pathway from the non-Fermi liquid to superconductivity. In the limit that the nesting angle is small, the non-Fermi liquid scaling dictates the physics over a large window of energy scale above the superconducting transition temperature., Comment: 109 pages

Published
2022
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14. Ultraviolet-Infrared Mixing in Marginal Fermi Liquids

Author

Ye, Weicheng, Lee, Sung-Sik, and Zou, Liujun

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, High Energy Physics - Theory
Abstract

When Fermi surfaces (FSs) are subject to long-range interactions that are marginal in the renormalization-group sense, Landau Fermi liquids are destroyed, but only barely. With the interaction further screened by particle-hole excitations through one-loop quantum corrections, it has been believed that these marginal Fermi liquids (MFLs) are described by weakly coupled field theories at low energies. In this Letter, we point out a possibility in which higher-loop processes qualitatively change the picture through UV-IR mixing, in which the size of the FS enters as a relevant scale. The UV-IR mixing effect enhances the coupling at low energies, such that the basin of attraction for the weakly coupled fixed point of a $(2+1)$-dimensional MFL shrinks to a measure-zero set in the low-energy limit. This UV-IR mixing is caused by gapless virtual Cooper pairs that spread over the entire FS through marginal long-range interactions. Our finding signals a possible breakdown of the patch description for the MFL and questions the validity of using the MFL as the base theory in a controlled scheme for non-Fermi liquids that arise from relevant long-range interactions., Comment: 4.5 pages + references + supplemental material

Published
2021
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15. Exact effective action for the O(N) vector model in the large N limit

Author

Ma, Han and Lee, Sung-Sik

Subjects
High Energy Physics - Theory, Condensed Matter - Strongly Correlated Electrons
Abstract

We present the Wilsonian effective action as a solution of the exact RG equation for the critical $O(N)$ vector model in the large $N$ limit. Below four dimensions, the exact effective action can be expressed in a closed form as a transcendental function of two leading scaling operators with infinitely many derivatives. From the exact solution that describes the RG flow from a UV theory to the fixed point theory in the IR, we obtain the mapping between UV operators and IR scaling operators. It is shown that IR scaling operators are given by sums of infinitely many UV operators with infinitely many derivatives., Comment: 19+16 pages, 1/N correction added

Published
2021
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16. Clock-dependent spacetime

Author

Lee, Sung-Sik

Subjects
General Relativity and Quantum Cosmology, High Energy Physics - Theory
Abstract

Einstein's theory of general relativity is based on the premise that the physical laws take the same form in all coordinate systems. However, it still presumes a preferred decomposition of the total kinematic Hilbert space into local kinematic Hilbert spaces. In this paper, we consider a theory of quantum gravity that does not come with a preferred partitioning of the kinematic Hilbert space. It is pointed out that, in such a theory, dimension, signature, topology and geometry of spacetime depend on how a collection of local clocks is chosen within the kinematic Hilbert space., Comment: 30 pages, 7 figures

Published
2020
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17. Constraints on beta functions in field theories

Author

Ma, Han and Lee, Sung-Sik

Subjects
High Energy Physics - Theory, Condensed Matter - Strongly Correlated Electrons
Abstract

The $\beta$-functions describe how couplings run under the renormalization group flow in field theories. In general, all couplings that respect the symmetry and locality are generated under the renormalization group flow, and the exact renormalization group flow is characterized by the $\beta$-functions defined in the infinite dimensional space of couplings. In this paper, we show that the renormalization group flow is highly constrained so that the $\beta$-functions defined in a measure zero subspace of couplings completely determine the $\beta$-functions in the entire space of couplings. We provide a quantum renormalization group-based algorithm for reconstructing the full $\beta$-functions from the $\beta$-functions defined in the subspace. As examples, we derive the full $\beta$-functions for the $O(N)$ vector model and the $O_L(N) \times O_R(N)$ matrix model entirely from the $\beta$-functions defined in the subspace of single-trace couplings., Comment: 75 pages, 12 figures, minor changes

Published
2020
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18. A model of quantum gravity with emergent spacetime

Author

Lee, Sung-Sik

Subjects
High Energy Physics - Theory, General Relativity and Quantum Cosmology
Abstract

We construct a model of quantum gravity in which dimension, topology and geometry of spacetime are dynamical. The microscopic degree of freedom is a real rectangular matrix whose rows label internal flavours, and columns label spatial sites. In the limit that the size of the matrix is large, the sites can collectively form a spatial manifold. The manifold is determined from the pattern of entanglement present across local Hilbert spaces associated with column vectors of the matrix. With no structure of manifold fixed in the background, the spacetime gauge symmetry is generalized to a group that includes diffeomorphism in arbitrary dimensions. The momentum and Hamiltonian that generate the generalized diffeomorphism obey a first-class constraint algebra at the quantum level. In the classical limit, the constraint algebra of the general relativity is reproduced as a special case. The first-class nature of the algebra allows one to express the projection of a quantum state of the matrix to a gauge-invariant state as a path integration of dynamical variables that describe collective fluctuations of the matrix. The collective variables describe dynamics of emergent spacetime, where multi-fingered times arise as Lagrangian multipliers that enforce the gauge constraints. If the quantum state has a local structure of entanglement, a smooth spacetime with well-defined dimension, topology, signature and geometry emerges at the saddle-point, and the spin two mode that determines the geometry can be identified. We find a saddle-point solution that describes a series of (3+1)-dimensional de Sitter-like spacetimes with the Lorentzian signature bridged by Euclidean spaces in between. Fluctuations of the collective variables are described by bi-local fields that propagate in the spacetime set up by the saddle-point solution., Comment: 80 pages, 12 figures, ver4 : minor corrections

Published
2019
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20. Stable Flatbands, Topology, and Superconductivity of Magic Honeycomb Networks

Author

Lee, Jongjun M., Geng, Chenhua, Park, Jae Whan, Oshikawa, Masaki, Lee, Sung-Sik, Yeom, Han Woong, and Cho, Gil Young

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Superconductivity
Abstract

We propose a new principle to realize flatbands which are robust in real materials, based on a network superstructure of one-dimensional segments. This mechanism is naturally realized in the nearly commensurate charge-density wave of 1T-TaS${}_2$ with the honeycomb network of conducting domain walls, and the resulting flatband can naturally explain the enhanced superconductivity. We also show that corner states, which are a hallmark of the higher-order topological insulators, appear in the network superstructure., Comment: 7+16 pages, 2+14 figures, Accepted version to PRL

Published
2019
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23. State dependent spread of entanglement in relatively local Hamiltonians

Author

Lee, Sung-Sik

Subjects
High Energy Physics - Theory, Condensed Matter - Strongly Correlated Electrons
Abstract

Relatively local Hamiltonians are a class of background independent non-local Hamiltonians from which local theories emerge within a set of short-range entangled states. The dimension, topology and geometry of the emergent local theory is determined by the initial state to which the Hamiltonian is applied. In this paper, we study dynamical properties of a simple relatively local Hamiltonian for N scalar fields in the large N limit. It is shown that the coordinate speeds at which entanglement spreads and local disturbance propagates in space strongly depend on state in the relatively local Hamiltonian., Comment: 30 pages, 12 figures; v4) a new section on roadmap to quantum gravity + minor corrections

Published
2018
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24. Noncommutativity between the low-energy limit and integer dimension limits in the $\boldsymbol{\epsilon}$-expansion: a case study of the antiferromagnetic quantum critical metal

Author

Schlief, Andres, Lunts, Peter, and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory
Abstract

We study the field theory for the SU($N_c$) symmetric antiferromagnetic quantum critical metal with a one-dimensional Fermi surface embedded in general space dimensions between two and three. The asymptotically exact solution valid in this dimensional range provides an interpolation between the perturbative solution obtained from the $\epsilon$-expansion near three dimensions and the nonperturbative solution in two dimensions. We show that critical exponents are smooth functions of the space dimension. However, physical observables exhibit subtle crossovers that make it hard to access subleading scaling behaviors in two dimensions from the low-energy solution obtained above two dimensions. These crossovers give rise to noncommutativities, where the low-energy limit does not commute with the limits in which the physical dimensions are approached., Comment: 34 pages: 12 pages for the main text, the remaining are supplementary materials. 25 figures and 2 tables. v2: minor revision and references updated. To appear in PRB

Published
2018
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25. Emergent gravity from relatively local Hamiltonians and a possible resolution of the black hole information puzzle

Author

Lee, Sung-Sik

Subjects
High Energy Physics - Theory, General Relativity and Quantum Cosmology
Abstract

In this paper, we study a possibility where gravity and time emerge from quantum matter. Within the Hilbert space of matter fields defined on a spatial manifold, we consider a sub-Hilbert space spanned by states which are parameterized by spatial metric. In those states, metric is introduced as a collective variable that controls local structures of entanglement. The underlying matter fields endow the states labeled by metric with an unambiguous inner product. Then we construct a Hamiltonian for the matter fields that is an endomorphism of the sub-Hilbert space, thereby inducing a quantum Hamiltonian of the metric. It is shown that there exists a matter Hamiltonian that induces the general relativity in the semi-classical field theory limit. Although the Hamiltonian is not local in the absolute sense, it has a weaker notion of locality, called relative locality : the range of interactions is set by the entanglement present in target states on which the Hamiltonian acts. In general, normalizable states are not invariant under the transformations generated by the Hamiltonian. As a result, a physical state spontaneously breaks the Hamiltonian constraint, and picks a moment of time. The subsequent flow of time can be understood as a Goldstone mode associated with the broken symmetry. The construction allows one to study dynamics of gravity from the perspective of matter fields. The Hawking radiation corresponds to a unitary evolution where entanglement across horizon is gradually transferred from color degrees of freedom to singlet degrees of freedom. The underlying quantum states remain pure as evaporating black holes keep entanglement with early Hawking radiations in the singlet sector which is not captured by the Bekenstein-Hawking entropy., Comment: 66 pages, 19 figures; v4) minor typos corrected

Published
2018
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28. Recent Developments in Non-Fermi Liquid Theory

Author

Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Non-Fermi liquids arise when metals are subject to singular interactions mediated by soft collective modes. In the absence of well-defined quasiparticle, universal physics of non-Fermi liquids is captured by interacting field theories which replace Landau Fermi liquid theory. In this review, we discuss two approaches that have been recently developed for non-Fermi liquid theory with emphasis on two space dimensions. The first is a perturbative scheme based on a dimensional regularization, which achieves a controlled access to the low-energy physics by tuning the number of co-dimensions of Fermi surface. The second is a non-perturbative approach which treats the interaction ahead of the kinetic term through a non-Gaussian scaling called interaction-driven scaling. Examples of strongly coupled non-Fermi liquids amenable to exact treatments through the interaction-driven scaling are discussed., Comment: 23 pages; comments are welcome

Published
2017
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29. Non-local Geometry inside Lifshitz Horizon

Author

Hu, Qi and Lee, Sung-Sik

Subjects
High Energy Physics - Theory, Condensed Matter - Strongly Correlated Electrons
Abstract

Based on the quantum renormalization group, we derive the bulk geometry that emerges in the holographic dual of the fermionic U(N) vector model at a nonzero charge density. The obstruction that prohibits the metallic state from being smoothly deformable to the direct product state under the renormalization group flow gives rise to a horizon at a finite radial coordinate in the bulk. The region outside the horizon is described by the Lifshitz geometry with a higher-spin hair determined by microscopic details of the boundary theory. On the other hand, the interior of the horizon is not described by any Riemannian manifold, as it exhibits an algebraic non-locality. The non-local structure inside the horizon carries the information on the shape of the filled Fermi sea., Comment: 20 pages

Published
2017
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30. Emergence of a control parameter for the antiferromagnetic quantum critical metal

Author

Lunts, Peter, Schlief, Andres, and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We study the antiferromagnetic quantum critical metal in $3-\epsilon$ space dimensions by extending the earlier one-loop analysis [Sur and Lee, Phys. Rev. B 91, 125136 (2015)] to higher-loop orders. We show that the $\epsilon$-expansion is not organized by the standard loop expansion, and a two-loop graph becomes as important as one-loop graphs due to an infrared singularity caused by an emergent quasilocality. This qualitatively changes the nature of the infrared (IR) fixed point, and the $\epsilon$-expansion is controlled only after the two-loop effect is taken into account. Furthermore, we show that a ratio between velocities emerges as a small parameter, which suppresses a large class of diagrams. We show that the critical exponents do not receive corrections beyond the linear order in $\epsilon$ in the limit that the ratio of velocities vanishes. The $\epsilon$-expansion gives critical exponents which are consistent with the exact solution obtained in $0 < \epsilon \leq 1$., Comment: 20 pages, 8 figures; ver2: minor corrections, comparison to ferromagnetic quantum criticality added, typos fixed, references added

Published
2017
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31. Exact critical exponents for the antiferromagnetic quantum critical metal in two dimensions

Author

Schlief, Andres, Lunts, Peter, and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Unconventional metallic states which do not support well defined single-particle excitations can arise near quantum phase transitions as strong quantum fluctuations of incipient order parameters prevent electrons from forming coherent quasiparticles. Although antiferromagnetic phase transitions occur commonly in correlated metals, understanding the nature of the strange metal realized at the critical point in layered systems has been hampered by a lack of reliable theoretical methods that take into account strong quantum fluctuations. We present a non-perturbative solution to the low-energy theory for the antiferromagnetic quantum critical metal in two spatial dimensions. Being a strongly coupled theory, it can still be solved reliably in the low-energy limit as quantum fluctuations are organized by a new control parameter that emerges dynamically. We predict the exact critical exponents that govern the universal scaling of physical observables at low temperatures., Comment: 19 pages + supplementary materials; v4) discussion on superconductivity expanded; comparison with experiments added

Published
2016
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32. Anisotropic Non-Fermi Liquids

Author

Sur, Shouvik and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We study non-Fermi liquid states that arise at the quantum critical points associated with the spin density wave (SDW) and charge density wave (CDW) transitions in metals with twofold rotational symmetry. We use the dimensional regularization scheme, where a one-dimensional Fermi surface is embedded in $3-\epsilon$ dimensional momentum space. In three dimensions, quasilocal marginal Fermi liquids arise both at the SDW and CDW critical points : the speed of the collective mode along the ordering wavevector is logarithmically renormalized to zero compared to that of Fermi velocity. Below three dimensions, however, the SDW and CDW critical points exhibit drastically different behaviors. At the SDW critical point, a stable anisotropic non-Fermi liquid state is realized for small $\epsilon$, where not only time but also different spatial coordinates develop distinct anomalous dimensions. The non-Fermi liquid exhibits an emergent algebraic nesting as the patches of Fermi surface are deformed into a universal power-law shape near the hot spots. Due to the anisotropic scaling, the energy of incoherent spin fluctuations disperse with different power laws in different momentum directions. At the CDW critical point, on the other hand, the perturbative expansion breaks down immediately below three dimensions as the interaction renormalizes the speed of charge fluctuations to zero within a finite renormalization group scale through a two-loop effect. The difference originates from the fact that the vertex correction anti-screens the coupling at the SDW critical point whereas it screens at the CDW critical point., Comment: 27 pages, 15 figures; v2) References & clarification added

Published
2016
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33. Horizon as Critical Phenomenon

Author

Lee, Sung-Sik

Subjects
High Energy Physics - Theory, Condensed Matter - Strongly Correlated Electrons
Abstract

We show that renormalization group(RG) flow can be viewed as a gradual wave function collapse, where a quantum state associated with the action of field theory evolves toward a final state that describes an IR fixed point. The process of collapse is described by the radial evolution in the dual holographic theory. If the theory is in the same phase as the assumed IR fixed point, the initial state is smoothly projected to the final state. If in a different phase, the initial state undergoes a phase transition which in turn gives rise to a horizon in the bulk geometry. We demonstrate the connection between critical behavior and horizon in an example, by deriving the bulk metrics that emerge in various phases of the U(N) vector model in the large N limit based on the holographic dual constructed from quantum RG. The gapped phase exhibits a geometry that smoothly ends at a finite proper distance in the radial direction. The geometric distance in the radial direction measures a complexity : the depth of RG transformation that is needed to project the generally entangled UV state to a direct product state in the IR. For gapless states, entanglement persistently spreads out to larger length scales, and the initial state can not be projected to the direct product state. The obstruction to smooth projection at charge neutral point manifests itself as the long throat in the anti-de Sitter space. The Poincare horizon at infinity marks the critical point which exhibits a divergent length scale in the spread of entanglement. For the gapless states with non-zero chemical potential, the bulk space becomes the Lifshitz geometry with the dynamical critical exponent two. The identification of horizon as critical point may provide an explanation for the universality of horizon. We also discuss the structure of the bulk tensor network that emerges from the quantum RG., Comment: 37 pages, 8 figures; v2) introduction expanded

Published
2016
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34. A novel method for automated crystal visualization and quantification in murine folic acid-induced acute kidney injury

Author

Hamid, Ahmad Kamal; https://orcid.org/0000-0003-4835-5807, Pastor Arroyo, Eva Maria, Lee, Sung Sik, Wagner, Carsten Alexander; https://orcid.org/0000-0002-9874-8898, Egli-Spichtig, Daniela; https://orcid.org/0000-0002-0778-2696, Hamid, Ahmad Kamal; https://orcid.org/0000-0003-4835-5807, Pastor Arroyo, Eva Maria, Lee, Sung Sik, Wagner, Carsten Alexander; https://orcid.org/0000-0002-9874-8898, and Egli-Spichtig, Daniela; https://orcid.org/0000-0002-0778-2696

Abstract

Here, we describe a novel method for the visualization and quantification of renal folic acid (FA) crystals in the rodent FA-induced acute kidney injury (FA-AKI) model. The protocol involves a straightforward histological approach followed by fully automated imaging and quantification steps. Applicability was confirmed by showing that the FA-AKI model is sex-dependent. The method can serve as a tool to aid in characterizing FA-AKI and to control for studies investigating prophylactic therapeutic avenues using FA-AKI.

Published
2024

35. Ab initio holography

Author

Lunts, Peter, Bhattacharjee, Subhro, Miller, Jonah, Schnetter, Erik, Kim, Yong Baek, and Lee, Sung-Sik

Subjects
High Energy Physics - Theory, Condensed Matter - Strongly Correlated Electrons
Abstract

We apply the quantum renormalization group to construct a holographic dual for the U(N) vector model for complex bosons defined on a lattice. The bulk geometry becomes dynamical as the hopping amplitudes which determine connectivity of space are promoted to quantum variables. In the large N limit, the full bulk equations of motion for the dynamical hopping fields are numerically solved for finite systems. From finite size scaling, we show that different phases exhibit distinct geometric features in the bulk. In the insulating phase, the space gets fragmented into isolated islands deep inside the bulk, exhibiting ultra-locality. In the superfluid phase, the bulk exhibits a horizon beyond which the geometry becomes non-local. Right at the horizon, the hopping fields decay with a universal power-law in coordinate distance between sites, while they decay in slower power-laws with continuously varying exponents inside the horizon. At the critical point, the bulk exhibits a local geometry whose characteristic length scale diverges asymptotically in the IR limit., Comment: 44+11 pages, many figures, added how to extract critical exponent from bulk (Fig. 13), other minor changes

Published
2015
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36. Impact of Nanoplastic Particles on Macrophage Inflammation and Intestinal Health in a Mouse Model of Inflammatory Bowel Disease.

Author

Schwarzfischer, Marlene, Ruoss, Tano S., Niechcial, Anna, Lee, Sung Sik, Wawrzyniak, Marcin, Laimbacher, Andrea, Atrott, Kirstin, Manzini, Roberto, Wilmink, Marijn, Linzmeier, Luise, Morsy, Yasser, Lang, Silvia, Rogler, Gerhard, Kaegi, Ralf, Scharl, Michael, and Spalinger, Marianne R.

Subjects
INFLAMMATORY bowel diseases, DIETARY patterns, PLASTIC scrap, CELL morphology, INTESTINAL diseases
Abstract

Background: The increasing presence of plastics in the human diet is raising public concern about the potential risks posed by nanoplastic (NP) particles, which can emerge from the degradation of plastic debris. NP ingestion poses particular risks to individuals with inflammatory bowel disease (IBD), as compromised epithelial barriers may facilitate NP translocation. Methods: In vitro, bone-marrow-derived macrophages (BMDMs) were exposed to 25 nm polymethacrylate (PMMA) or 50 nm polystyrene (PS) particles to assess morphological changes and alterations in pro- and anti-inflammatory gene expression. In vivo, mice received PMMA NP particles for 6 months before acute dextran sodium sulfate (DSS) colitis was induced to investigate NP impacts on intestinal health and inflammation. Results: PMMA and PS NP exposure in BMDMs induced morphological changes indicative of a proinflammatory phenotype characterized by enlarged amoeboid cell shapes. It also triggered an inflammatory response, indicated by increased expression of proinflammatory cytokines such as Tnfa and Il6. Unexpectedly, long-term PMMA NP administration did not affect the intestinal epithelial barrier or exacerbate acute DSS-induced colitis in mice. Colonoscopy and histological analysis revealed no NP-related changes, suggesting adverse effects on intestinal health or inflammation. Conclusion: Our findings from animal models offer some reassurance to IBD patients regarding the effects of NP ingestion. However, variations in lifestyle and dietary habits may lead to significantly higher plastic intake in certain individuals, raising concerns about potential long-term gastrointestinal effects of lifelong plastic consumption. [ABSTRACT FROM AUTHOR]

Published
2024
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41. Renormalization group analysis on a neck-narrowing Lifshitz transition in the presence of weak short-range interactions in two dimensions

Author

Ghamari, Sedigh, Lee, Sung-Sik, and Kallin, Catherine

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We study a system of weakly interacting electrons described by the energy dispersion $\xi(\mathbf{k}) = k_x^2 - k_y^2 - \mu$ in two dimensions within a renormalization group approach. This energy dispersion exhibits a neck-narrowing Lifshitz transition at the critical chemical potential $\mu_c=0$ where a van Hove singularity develops. Implementing a systematic renormalization group analysis of this system has long been hampered by the appearance of nonlocal terms in the Wilsonian effective action. We demonstrate that non-locality at the critical point is intrinsic, and the locality of the effective action can be maintained only away from the critical point. We also point out that it is crucial to introduce a large momentum cutoff to keep locality even away from the critical point. Based on a local renormalization group scheme employed near the critical point, we show that, as the energy scale $E$ is lowered, an attractive four-fermion interaction grows as $\log^2 E$ for $E > \mu$, whereas it retains the usual BCS growth, $-\log E$, for $E < \mu$. Starting away from the critical point, this fast growth of the pairing interaction suggests that the system becomes unstable toward a superconducting state well before the critical point is reached., Comment: 9 pages, 11 figures; Minor revision

Published
2014
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42. Ultraviolet/infrared mixing in non-Fermi liquids

Author

Mandal, Ipsita and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory
Abstract

We study low-energy effective field theories for non-Fermi liquids with Fermi surfaces of general dimensions and co-dimensions. When the dimension of Fermi surface is greater than one, low-energy particle-hole excitations remain strongly coupled with each other across the entire Fermi surface. In this case, even the observables that are local in the momentum space (such as the Green's functions) become dependent on the size of the Fermi surface in singular ways, resulting in an ultraviolet/infrared (UV/IR) mixing. By tuning the dimension and co-dimension of the Fermi surface independently, we find perturbative non-Fermi liquid fixed points controlled by both UV/IR mixing and interactions., Comment: minor typos corrected

Published
2014
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43. Quasi-Local Strange Metal

Author

Sur, Shouvik and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

One of the key factors that determine the fates of quantum many-body systems in the zero temperature limit is the competition between kinetic energy that delocalizes particles in space and interaction that promotes localization. While one dominates over the other in conventional metals and insulators, exotic states can arise at quantum critical points where none of them clearly wins. Here we present a novel metallic state that is realized at the antiferromagnetic (AF) quantum critical point in space dimensions three and below. At the critical point, interactions between particles are screened to zero in the low energy limit at the same time the kinetic energy is suppressed in certain spatial directions to the leading order in a perturbative expansion that becomes asymptotically exact in three dimensions. The resulting dispersionless and interactionless state exhibits distinct quasi-local strange metallic behaviors due to the subtle dynamical balance between screening and infrared singularity caused by the spontaneous reduction of effective dimensionality., Comment: v2) minor revision; appendix A added

Published
2014
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44. Chiral non-Fermi Liquids

Author

Sur, Shouvik and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory
Abstract

A non-Fermi liquid state without time-reversal and parity symmetries arises when a chiral Fermi surface is coupled with a soft collective mode in two space dimensions. The full Fermi surface is described by a direct sum of chiral patch theories, which are decoupled from each other in the low energy limit. Each patch includes low energy excitations near a set of points on the Fermi surface with a common tangent vector. General patch theories are classified by the local shape of the Fermi surface, the dispersion of the critical boson, and the symmetry group, which form the data for distinct universality classes. We prove that a large class of chiral non-Fermi liquid states exist as stable critical states of matter. For this, we use a renormalization group scheme where low energy excitations of the Fermi surface are interpreted as a collection of (1+1)-dimensional chiral fermions with a continuous flavor labelling the momentum along the Fermi surface. Due to chirality, the Wilsonian effective action is strictly UV finite. This allows one to extract the exact scaling exponents although the theories flow to strongly interacting field theories at low energies. In general, the low energy effective theory of the full Fermi surface includes patch theories of more than one universality classes. As a result, physical responses include multiple universal components at low temperatures. We also point out that, in quantum field theories with extended Fermi surface, a non-commutative structure naturally emerges between a coordinate and a momentum which are orthogonal to each other. We show that the invalidity of patch description for Fermi liquid states is tied with the presence of UV/IR mixing associated with the emergent non-commutativity. On the other hand, UV/IR mixing is suppressed in non-Fermi liquid states due to UV insensitivity, and the patch description is valid., Comment: 37 pages, 25 figures; v3) Typos fixed

Published
2013
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45. Perturbative non-Fermi liquids from dimensional regularization

Author

Dalidovich, Denis and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory
Abstract

We devise a dimensional regularization scheme for quantum field theories with Fermi surface to study scaling behaviour of non-Fermi liquid states in a controlled approximation. Starting from a Fermi surface in two space dimensions, the co-dimension of Fermi surface is extended to a general value while the dimension of Fermi surface is fixed. When Fermi surface is coupled with a critical boson centered at zero momentum, the interaction becomes marginal at a critical space dimension d_c=5/2. A deviation from the critical dimension is used as a small parameter for a systematic expansion. We apply this method to the theory where two patches of Fermi surface is coupled with a critical boson, and show that the Ising-nematic critical point is described by a stable non-Fermi liquid state slightly below the critical dimension. Critical exponents are computed upto the two-loop order., Comment: 46 pages, 10 figures; v3) typos corrected

Published
2013
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46. Quantum Renormalization Group and Holography

Author

Lee, Sung-Sik

Subjects
High Energy Physics - Theory, Condensed Matter - Strongly Correlated Electrons, General Relativity and Quantum Cosmology
Abstract

Quantum renormalization group scheme provides a microscopic understanding of holography through a general mapping between the beta functions of underlying quantum field theories and the holographic actions in the bulk. We show that the Einstein gravity emerges as a long wavelength holographic description for a matrix field theory which has no other operator with finite scaling dimension except for the energy-momentum tensor. We also point out that holographic actions for general large N matrix field theories respect the inversion symmetry along the radial direction in the bulk if the beta functions of single-trace operators are gradient flows with respect to the target space metric set by the beta functions of double-trace operators., Comment: 5 pages; 1 figure; v2) references added

Published
2013
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48. Scaling of entanglement entropy across Lifshitz transitions

Author

Rodney, Marlon, Song, H. Francis, Lee, Sung-Sik, Hur, Karyn Le, and Sorensen, Erik

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We investigate the scaling of the bipartite entanglement entropy across Lifshitz quantum phase transitions, where the topology of the Fermi surface changes without any changes in symmetry. We present both numerical and analytical results which show that Lifshitz transitions are characterized by a well-defined set of critical exponents for the entanglement entropy near the phase transition. In one dimension, we show that the entanglement entropy exhibits a length scale that diverges as the system approaches a Lifshitz critical point. In two dimensions, the leading and sub-leading coefficients of the scaling of entanglement entropy show distinct power-law singularities at critical points. The effect of weak interactions is investigated using the density matrix renormalization group algorithm., Comment: 11 pages, 11 figures; v2) references added

Published
2012
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49. Emergence of supersymmetry on the surface of three dimensional topological insulators

Author

Ponte, Pedro and Lee, Sung-Sik

Subjects
Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory
Abstract

We propose two possible experimental realizations of a 2+1 dimensional spacetime supersymmetry at a quantum critical point on the surface of three dimensional topological insulators. The quantum critical point between the semi-metallic state with one Dirac fermion and the s-wave superconducting state on the surface is described by a supersymmetric conformal field theory within $\epsilon$-expansion. We predict the exact voltage dependence of the differential conductance at the supersymmetric critical point., Comment: 8 pages, 2 figures; published version

Published
2012
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50. Background independent holographic description : From matrix field theory to quantum gravity

Author

Lee, Sung-Sik

Subjects
High Energy Physics - Theory, Condensed Matter - Strongly Correlated Electrons, General Relativity and Quantum Cosmology
Abstract

We propose a local renormalization group procedure where length scale is changed in spacetime dependent way. Combining this scheme with an earlier observation that high energy modes in renormalization group play the role of dynamical sources for low energy modes at each scale, we provide a prescription to derive background independent holographic duals for field theories. From a first principle construction, it is shown that the holographic theory dual to a D-dimensional matrix field theory is a (D+1)-dimensional quantum theory of gravity coupled with matter fields of various spins. The gravitational theory has (D+1) first-class constraints which generate local spacetime transformations in the bulk. The (D+1)-dimensional diffeomorphism invariance is a consequence of the freedom to choose different local RG schemes., Comment: 34 pages, 4 figures; v2) sections VIII and IX added; v3) typos corrected (to appear in JHEP)

Published
2012
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