Your search keyword '"Fogler, MM"' showing total 276 results

1. Visualizing moiré ferroelectricity via plasmons and nano-photocurrent in graphene/twisted-WSe2 structures

Author

Zhang, Shuai, Liu, Yang, Sun, Zhiyuan, Chen, Xinzhong, Li, Baichang, Moore, SL, Liu, Song, Wang, Zhiying, Rossi, SE, Jing, Ran, Fonseca, Jordan, Yang, Birui, Shao, Yinming, Huang, Chun-Ying, Handa, Taketo, Xiong, Lin, Fu, Matthew, Pan, Tsai-Chun, Halbertal, Dorri, Xu, Xinyi, Zheng, Wenjun, Schuck, PJ, Pasupathy, AN, Dean, CR, Zhu, Xiaoyang, Cobden, David H, Xu, Xiaodong, Liu, Mengkun, Fogler, MM, Hone, James C, and Basov, DN

Subjects

Physical Sciences, Condensed Matter Physics

Abstract

Ferroelectricity, a spontaneous and reversible electric polarization, is found in certain classes of van der Waals (vdW) materials. The discovery of ferroelectricity in twisted vdW layers provides new opportunities to engineer spatially dependent electric and optical properties associated with the configuration of moiré superlattice domains and the network of domain walls. Here, we employ near-field infrared nano-imaging and nano-photocurrent measurements to study ferroelectricity in minimally twisted WSe2. The ferroelectric domains are visualized through the imaging of the plasmonic response in a graphene monolayer adjacent to the moiré WSe2 bilayers. Specifically, we find that the ferroelectric polarization in moiré domains is imprinted on the plasmonic response of the graphene. Complementary nano-photocurrent measurements demonstrate that the optoelectronic properties of graphene are also modulated by the proximal ferroelectric domains. Our approach represents an alternative strategy for studying moiré ferroelectricity at native length scales and opens promising prospects for (opto)electronic devices.

Published

2023

2. Deep-learning-aided extraction of optical constants in scanning near-field optical microscopy

Author

Zhao, Y, Chen, X, Yao, Z, Liu, MK, and Fogler, MM

Subjects

Quantum Physics, Engineering, Physical Sciences, Clinical Trials and Supportive Activities, Clinical Research, Bioengineering, Mathematical Sciences, Applied Physics, Mathematical sciences, Physical sciences

Abstract

Scanning near-field optical microscopy is one of the most effective techniques for spectroscopy of nanoscale systems. However, inferring optical constants from the measured near-field signal can be challenging because of a complicated and highly nonlinear interaction between the scanned probe and the sample. Conventional fitting methods applied to this problem often suffer from the lack of convergence or require human intervention. Here, we develop an alternative approach where the optical parameter extraction is automated by a deep learning network. The network provides an initial estimate that is subsequently refined by a traditional fitting algorithm. We show that this method demonstrates superior accuracy, stability against noise, and computational speed when applied to simulated near-field spectra.

Published

2023

3. Shape prediction on the basis of spectrum using neural networks

Author

Zhao, Y and Fogler, MM

Subjects

Physical Sciences, Physical sciences

Published

2023

4. Graphene as a source of entangled plasmons

Author

Sun, Zhiyuan, Basov, DN, and Fogler, MM

Subjects

Quantum Physics, Atomic, Molecular and Optical Physics, Physical Sciences, Condensed Matter Physics, Physical sciences

Published

2022

5. Hybrid Machine Learning for Scanning Near-Field Optical Spectroscopy

Author

Chen, X, Yao, Z, Xu, S, McLeod, AS, Gilbert Corder, SN, Zhao, Y, Tsuneto, M, Bechtel, HA, Martin, MC, Carr, GL, Fogler, MM, Stanciu, SG, Basov, DN, and Liu, M

Subjects

s-SNOM, nano-FTIR, near-field optics, supervised learning, hybrid neural network, Bioengineering, Optical Physics, Quantum Physics, Electrical and Electronic Engineering

Abstract

The underlying physics behind an experimental observation often lacks a simple analytical description. This is especially the case for scanning probe microscopy techniques, where the interaction between the probe and the sample is nontrivial. Realistic modeling to include the exact details of the probe is widely acknowledged as a challenge. Due to various complexity constraints, the probe is often only approximated in a simplified geometry, leading to a source for modeling inconsistencies. On the other hand, a well-trained artificial neural network based on real data can grasp the hidden correlation between the signal and the sample properties, circumventing the explicit probe modeling process. In this work we show that, via a combination of model calculation and experimental data acquisition, a physics-infused hybrid neural network can predict the probe-sample interaction in the widely used scattering-type scanning near-field optical microscope. This hybrid network provides a long-sought solution for accurate extraction of material properties from tip-specific raw data. The methodology can be extended to other scanning probe microscopy techniques as well as other data-oriented physical problems in general.

Published

2021

6. Hybrid Machine Learning for Scanning Near-field Optical Spectroscopy

Author

Chen, Xinzhong, Yao, Ziheng, Xu, Suheng, McLeod, AS, Corder, Stephanie N Gilbert, Zhao, Yueqi, Tsuneto, Makoto, Bechtel, Hans A, Martin, Michael C, Carr, GL, Fogler, MM, Stanciu, Stefan G, Basov, DN, and Liu, Mengkun

Subjects

physics.optics, physics.data-an, physics.ins-det

Abstract

The underlying physics behind an experimental observation often lacks asimple analytical description. This is especially the case for scanning probemicroscopy techniques, where the interaction between the probe and the sampleis nontrivial. Realistic modeling to include the details of the probe is alwaysexponentially more difficult than its "spherical cow" counterparts. On theother hand, a well-trained artificial neural network based on real data cangrasp the hidden correlation between the signal and sample properties. In thiswork, we show that, via a combination of model calculation and experimentaldata acquisition, a physics-infused hybrid neural network can predict thetip-sample interaction in the widely used scattering-type scanning near-fieldoptical microscope. This hybrid network provides a long-sought solution foraccurate extraction of material properties from tip-specific raw data. Themethodology can be extended to other scanning probe microscopy techniques aswell as other data-oriented physical problems in general.

Published

2021

7. Hyperbolic enhancement of photocurrent patterns in minimally twisted bilayer graphene

Author

Sunku, SS, Halbertal, D, Stauber, T, Chen, S, McLeod, AS, Rikhter, A, Berkowitz, ME, Lo, CFB, Gonzalez-Acevedo, DE, Hone, JC, Dean, CR, Fogler, MM, and Basov, DN

Subjects

Physical Sciences, Condensed Matter Physics, cond-mat.mes-hall

Abstract

Quasi-periodic moiré patterns and their effect on electronic properties of twisted bilayer graphene have been intensely studied. At small twist angle θ, due to atomic reconstruction, the moiré superlattice morphs into a network of narrow domain walls separating micron-scale AB and BA stacking regions. We use scanning probe photocurrent imaging to resolve nanoscale variations of the Seebeck coefficient occurring at these domain walls. The observed features become enhanced in a range of mid-infrared frequencies where the hexagonal boron nitride substrate is optically hyperbolic. Our results illustrate the capabilities of the nano-photocurrent technique for probing nanoscale electronic inhomogeneities in two-dimensional materials.

Published

2021

8. Inductor coil of the highest possible Q

Author

Rikhter, A and Fogler, MM

Subjects

Communications Engineering, Engineering, physics.class-ph

Abstract

The geometry of an inductor made of a long thin wire and having the highest possible Q-factor is found by numerical optimization. As frequency increases, the Q-factor first grows linearly and then according to a square-root law, while the cross-section of the optimal coil evolves from near-circular to sickle-shaped.

Published

2020

9. Photonic crystal for graphene plasmons.

Author

Xiong, L, Forsythe, C, Jung, M, McLeod, AS, Sunku, SS, Shao, YM, Ni, GX, Sternbach, AJ, Liu, S, Edgar, JH, Mele, EJ, Fogler, MM, Shvets, G, Dean, CR, and Basov, DN

Abstract

Photonic crystals are commonly implemented in media with periodically varying optical properties. Photonic crystals enable exquisite control of light propagation in integrated optical circuits, and also emulate advanced physical concepts. However, common photonic crystals are unfit for in-operando on/off controls. We overcome this limitation and demonstrate a broadly tunable two-dimensional photonic crystal for surface plasmon polaritons. Our platform consists of a continuous graphene monolayer integrated in a back-gated platform with nano-structured gate insulators. Infrared nano-imaging reveals the formation of a photonic bandgap and strong modulation of the local plasmonic density of states that can be turned on/off or gradually tuned by the applied gate voltage. We also implement an artificial domain wall which supports highly confined one-dimensional plasmonic modes. Our electrostatically-tunable photonic crystals are derived from standard metal oxide semiconductor field effect transistor technology and pave a way for practical on-chip light manipulation.

Published

2019

10. Soliton superlattices in twisted hexagonal boron nitride.

Author

Ni, GX, Wang, H, Jiang, B-Y, Chen, LX, Du, Y, Sun, ZY, Goldflam, MD, Frenzel, AJ, Xie, XM, Fogler, MM, and Basov, DN

Subjects

MD Multidisciplinary

Abstract

Properties of atomic van der Waals heterostructures are profoundly influenced by interlayer coupling, which critically depends on stacking of the proximal layers. Rotational misalignment or lattice mismatch of the layers gives rise to a periodic modulation of the stacking, the moiré superlattice. Provided the superlattice period extends over many unit cells, the coupled layers undergo lattice relaxation, leading to the concentration of strain at line defects - solitons - separating large area commensurate domains. We visualize such long-range periodic superstructures in thin crystals of hexagonal boron nitride using atomic-force microscopy and nano-infrared spectroscopy. The solitons form sub-surface hexagonal networks with periods of a few hundred nanometers. We analyze the topography and infrared contrast of these networks to obtain spatial distribution of local strain and its effect on the infrared-active phonons of hBN.

Published

2019

11. Photonic crystals for nano-light in moiré graphene superlattices

Author

Sunku, SS, Ni, GX, Jiang, BY, Yoo, H, Sternbach, A, McLeod, AS, Stauber, T, Xiong, L, Taniguchi, T, Watanabe, K, Kim, P, Fogler, MM, and Basov, DN

Subjects

cond-mat.mes-hall, General Science & Technology

Abstract

Graphene is an atomically thin plasmonic medium that supports highly confined plasmon polaritons, or nano-light, with very low loss. Electronic properties of graphene can be drastically altered when it is laid upon another graphene layer, resulting in a moiré superlattice. The relative twist angle between the two layers is a key tuning parameter of the interlayer coupling in thus-obtained twisted bilayer graphene (TBG). We studied the propagation of plasmon polaritons in TBG by infrared nano-imaging. We discovered that the atomic reconstruction occurring at small twist angles transforms the TBG into a natural plasmon photonic crystal for propagating nano-light. This discovery points to a pathway for controlling nano-light by exploiting quantum properties of graphene and other atomically layered van der Waals materials, eliminating the need for arduous top-down nanofabrication.

Published

2018

12. Pancharatnam-Berry phase in condensate of indirect excitons.

Author

Leonard, JR, High, AA, Hammack, AT, Fogler, MM, Butov, LV, Campman, KL, and Gossard, AC

Subjects

cond-mat.mes-hall, quant-ph, MD Multidisciplinary

Abstract

The Pancharatnam-Berry phase is a geometric phase acquired over a cycle of parameters in the Hamiltonian governing the evolution of the system. Here, we report on the observation of the Pancharatnam-Berry phase in a condensate of indirect excitons (IXs) in a GaAs-coupled quantum well structure. The Pancharatnam-Berry phase is directly measured by detecting phase shifts of interference fringes in IX interference patterns. Correlations are found between the phase shifts, polarization pattern of IX emission, and onset of IX spontaneous coherence. The evolving Pancharatnam-Berry phase is acquired due to coherent spin precession in IX condensate and is observed with no decay over lengths exceeding 10 μm indicating long-range coherent spin transport.

Published

2018

13. Fundamental limits to graphene plasmonics.

Author

Ni, GX, McLeod, AS, Sun, Z, Wang, L, Xiong, L, Post, KW, Sunku, SS, Jiang, B-Y, Hone, J, Dean, CR, Fogler, MM, and Basov, DN

Subjects

MD Multidisciplinary, General Science & Technology

Abstract

Plasmon polaritons are hybrid excitations of light and mobile electrons that can confine the energy of long-wavelength radiation at the nanoscale. Plasmon polaritons may enable many enigmatic quantum effects, including lasing 1 , topological protection2,3 and dipole-forbidden absorption 4 . A necessary condition for realizing such phenomena is a long plasmonic lifetime, which is notoriously difficult to achieve for highly confined modes 5 . Plasmon polaritons in graphene-hybrids of Dirac quasiparticles and infrared photons-provide a platform for exploring light-matter interaction at the nanoscale6,7. However, plasmonic dissipation in graphene is substantial 8 and its fundamental limits remain undetermined. Here we use nanometre-scale infrared imaging to investigate propagating plasmon polaritons in high-mobility encapsulated graphene at cryogenic temperatures. In this regime, the propagation of plasmon polaritons is primarily restricted by the dielectric losses of the encapsulated layers, with a minor contribution from electron-phonon interactions. At liquid-nitrogen temperatures, the intrinsic plasmonic propagation length can exceed 10 micrometres, or 50 plasmonic wavelengths, thus setting a record for highly confined and tunable polariton modes. Our nanoscale imaging results reveal the physics of plasmonic dissipation and will be instrumental in mitigating such losses in heterostructure engineering applications.

Published

2018

14. Indirect excitons in van der Waals heterostructures at room temperature.

Author

Calman, EV, Fogler, MM, Butov, LV, Hu, S, Mishchenko, A, and Geim, AK

Subjects

cond-mat.mes-hall, MD Multidisciplinary

Abstract

Indirect excitons (IXs) are explored both for studying quantum Bose gases in semiconductor materials and for the development of excitonic devices. IXs were extensively studied in III-V and II-VI semiconductor heterostructures where IX range of existence has been limited to low temperatures. Here, we present the observation of IXs at room temperature in van der Waals transition metal dichalcogenide (TMD) heterostructures. This is achieved in TMD heterostructures based on monolayers of MoS2 separated by atomically thin hexagonal boron nitride. The IXs we realize in the TMD heterostructure have lifetimes orders of magnitude longer than lifetimes of direct excitons in single-layer TMD and their energy is gate controlled. The realization of IXs at room temperature establishes the TMD heterostructures as a material platform both for a field of high-temperature quantum Bose gases of IXs and for a field of high-temperature excitonic devices.

Published

2018

15. Split-gate device for indirect excitons

Author

Dorow, CJ, Leonard, JR, Fogler, MM, Butov, LV, West, KW, and Pfeiffer, LN

Subjects

cond-mat.mes-hall, Physical Sciences, Engineering, Technology, Applied Physics

Abstract

We present a concept and experimental proof of principle for split-gate devices for indirect excitons (IXs). The split-gate forms a narrow channel, a point contact, for IX current. Control of IX flow through the split-gate with both gate voltage and excitation power is demonstrated.

Published

2018

16. Third-order optical conductivity of an electron fluid

Author

Sun, Zhiyuan, Basov, DN, and Fogler, MM

Subjects

cond-mat.mes-hall, cond-mat.mtrl-sci, cond-mat.str-el

Abstract

We derive the nonlinear optical conductivity of an isotropic electron fluidat frequencies below the interparticle collision rate. In this regime, governedby hydrodynamics, the conductivity acquires a universal form at anytemperature, chemical potential, and spatial dimension. We show that thenonlinear response of the fluid to a uniform field is dominated by thethird-order conductivity tensor $\sigma^{(3)}$ whose magnitude and temperaturedependence differ qualitatively from those in the conventional kinetic regimeof higher frequencies. We obtain explicit formulas for $\sigma^{(3)}$ for Diracmaterials such as graphene and Weyl semimetals. We make predictions for thethird-harmonic generation, renormalization of the collective-mode spectrum, andthe third-order circular magnetic birefringence experiments.

Published

2018

17. Imaging the Localized Plasmon Resonance Modes in Graphene Nanoribbons

Author

Hu, F, Luan, Y, Fei, Z, Palubski, IZ, Goldflam, MD, Dai, S, Wu, J-S, Post, KW, Janssen, GCAM, Fogler, MM, and Basov, DN

Subjects

s-SNOM, graphene nanoribbons, surface plasmon polariton, surface plasmon resonance, asymmetric fringes, Nanoscience & Nanotechnology

Abstract

We report a nanoinfrared (IR) imaging study of the localized plasmon resonance modes of graphene nanoribbons (GNRs) using a scattering-type scanning near-field optical microscope (s-SNOM). By comparing the imaging data of GNRs that are aligned parallel and perpendicular to the in-plane component of the excitation laser field, we observed symmetric and asymmetric plasmonic interference fringes, respectively. Theoretical analysis indicates that the asymmetric fringes are formed due to the interplay between the localized surface plasmon resonance (SPR) mode excited by the GNRs and the propagative surface plasmon polariton (SPP) mode launched by the s-SNOM tip. With rigorous simulations, we reproduce the observed fringe patterns and address quantitatively the role of the s-SNOM tip on both the SPR and SPP modes. Furthermore, we have seen real-space signatures of both the dipole and higher-order SPR modes by varying the ribbon width.

Published

2017

18. Efficiency of Launching Highly Confined Polaritons by Infrared Light Incident on a Hyperbolic Material

Author

Dai, S, Ma, Q, Yang, Y, Rosenfeld, J, Goldflam, MD, McLeod, A, Sun, Z, Andersen, TI, Fei, Z, Liu, M, Shao, Y, Watanabe, K, Taniguchi, T, Thiemens, M, Keilmann, F, Jarillo-Herrero, P, Fogler, MM, and Basov, DN

Subjects

Polariton launching hyperbolic materials, hexagonal boron nitride, nano-optics, van der. Waals materials, cond-mat.mes-hall, MD Multidisciplinary, Nanoscience & Nanotechnology

Abstract

We investigated phonon-polaritons in hexagonal boron nitride - a naturally hyperbolic van der Waals material - by means of the scattering-type scanning near-field optical microscopy. Real-space nanoimages we have obtained detail how the polaritons are launched when the light incident on a thin hexagonal boron nitride slab is scattered by various intrinsic and extrinsic inhomogeneities, including sample edges, metallic nanodisks deposited on its top surface, random defects, and surface impurities. The scanned tip of the near-field microscope is itself a polariton launcher whose efficiency proves to be superior to all the other types of polariton launchers we studied. Our work may inform future development of polaritonic nanodevices as well as fundamental studies of collective modes in van der Waals materials.

Published

2017

19. Plasmonic imaging is gaining momentum

Author

Basov, DN and Fogler, MM

Subjects

Humans, Motion, Scattering, Radiation, Surface Plasmon Resonance, General Science & Technology

Abstract

Terahertz nanospectroscopy reveals many-body interactions in graphene

Published

2017

20. Ultraconfined Plasmonic Hotspots Inside Graphene Nanobubbles.

Author

Fei, Z, Foley, JJ, Gannett, W, Liu, MK, Dai, S, Ni, GX, Zettl, A, Fogler, MM, Wiederrecht, GP, Gray, SK, and Basov, DN

Subjects

FDTD simulation, Graphene nanobubbles, heterostructures, nanoinfrared imaging, plasmon hotspots, Nanoscience & Nanotechnology

Abstract

We report on a nanoinfrared (IR) imaging study of ultraconfined plasmonic hotspots inside graphene nanobubbles formed in graphene/hexagonal boron nitride (hBN) heterostructures. The volume of these plasmonic hotspots is more than one-million-times smaller than what could be achieved by free-space IR photons, and their real-space distributions are controlled by the sizes and shapes of the nanobubbles. Theoretical analysis indicates that the observed plasmonic hotspots are formed due to a significant increase of the local plasmon wavelength in the nanobubble regions. Such an increase is attributed to the high sensitivity of graphene plasmons to its dielectric environment. Our work presents a novel scheme for plasmonic hotspot formation and sheds light on future applications of graphene nanobubbles for plasmon-enhanced IR spectroscopy.

Published

2016

21. Polaritons in van der Waals materials

Author

Basov, DN, Fogler, MM, and de Abajo, FJ García

Subjects

General Science & Technology

Published

2016

22. Tunable Plasmonic Reflection by Bound 1D Electron States in a 2D Dirac Metal

Author

Jiang, B-Y, Ni, GX, Pan, C, Fei, Z, Cheng, B, Lau, CN, Bockrath, M, Basov, DN, and Fogler, MM

Subjects

Physical Sciences, Condensed Matter Physics, cond-mat.mes-hall, Mathematical Sciences, Engineering, General Physics, Mathematical sciences, Physical sciences

Abstract

We show that the surface plasmons of a two-dimensional Dirac metal such as graphene can be reflected by linelike perturbations hosting one-dimensional electron states. The reflection originates from a strong enhancement of the local optical conductivity caused by optical transitions involving these bound states. We propose that the bound states can be systematically created, controlled, and liquidated by an ultranarrow electrostatic gate. Using infrared nanoimaging, we obtain experimental evidence for the locally enhanced conductivity of graphene induced by a carbon nanotube gate, which supports this theoretical concept.

Published

2016

23. Adiabatic Amplification of Plasmons and Demons in 2D Systems

Author

Sun, Zhiyuan, Basov, DN, and Fogler, MM

Subjects

cond-mat.mes-hall, cond-mat.mtrl-sci, cond-mat.str-el, Mathematical Sciences, Physical Sciences, Engineering, General Physics

Abstract

We theoretically investigate charged collective modes in a two-dimensional conductor with hot electrons where the instantaneous mode frequencies gradually increase or decrease with time. We show that the loss compensation or even amplification of the modes may occur. We apply our theory to two types of collective modes in graphene, the plasmons and the energy waves, which can be probed in optical pump-probe experiments.

Published

2016

24. Ultrafast optical switching of infrared plasmon polaritons in high-mobility graphene

Author

Ni, GX, Wang, L, Goldflam, MD, Wagner, M, Fei, Z, McLeod, AS, Liu, MK, Keilmann, F, Özyilmaz, B, Castro Neto, AH, Hone, J, Fogler, MM, and Basov, DN

Subjects

Mathematical Sciences, Physical Sciences, Optoelectronics & Photonics

Published

2016

25. Control of excitons in multi-layer van der Waals heterostructures

Author

Calman, EV, Dorow, CJ, Fogler, MM, Butov, LV, Hu, S, Mishchenko, A, and Geim, AK

Subjects

cond-mat.mes-hall, Physical Sciences, Engineering, Technology, Applied Physics

Abstract

We report an experimental study of excitons in a double quantum well van der Waals heterostructure made of atomically thin layers of MoS2 and hexagonal boron nitride. The emission of neutral and charged excitons is controlled by gate voltage, temperature, and both the helicity and the power of optical excitation.

Published

2016

26. Generalized spectral method for near-field optical microscopy

Author

Jiang, B-Y, Zhang, LM, Neto, AH Castro, Basov, DN, and Fogler, MM

Subjects

cond-mat.mes-hall, Mathematical Sciences, Physical Sciences, Engineering, Applied Physics

Abstract

Electromagnetic interaction between a sub-wavelength particle (the “probe”) and a material surface (the “sample”) is studied theoretically. The interaction is shown to be governed by a series of resonances corresponding to surface polariton modes localized near the probe. The resonance parameters depend on the dielectric function and geometry of the probe as well as on the surface reflectivity of the material. Calculation of such resonances is carried out for several types of axisymmetric probes: spherical, spheroidal, and pear-shaped. For spheroids, an efficient numerical method is developed, capable of handling cases of large or strongly momentum-dependent surface reflectivity. Application of the method to highly resonant materials, such as aluminum oxide (by itself or covered with graphene), reveals a rich structure of multi-peak spectra and nonmonotonic approach curves, i.e., the probe-sample distance dependence. These features also strongly depend on the probe shape and optical constants of the model. For less resonant materials such as silicon oxide, the dependence is weak, so that the spheroidal model is reliable. The calculations are done within the quasistatic approximation with radiative damping included perturbatively.

Published

2016

27. Edge and Surface Plasmons in Graphene Nanoribbons

Author

Fei, Z, Goldflam, MD, Wu, J-S, Dai, S, Wagner, M, McLeod, AS, Liu, MK, Post, KW, Zhu, S, Janssen, GCAM, Fogler, MM, and Basov, DN

Subjects

Graphene nanoribbons, CVD graphene, nano-infrared imaging, plasmon-phonon coupling, edge plasmons, plasmon−phonon coupling, cond-mat.mes-hall, Nanoscience & Nanotechnology

Abstract

We report on nano-infrared (IR) imaging studies of confined plasmon modes inside patterned graphene nanoribbons (GNRs) fabricated with high-quality chemical-vapor-deposited (CVD) graphene on Al2O3 substrates. The confined geometry of these ribbons leads to distinct mode patterns and strong field enhancement, both of which evolve systematically with the ribbon width. In addition, spectroscopic nanoimaging in the mid-infrared range 850-1450 cm(-1) allowed us to evaluate the effect of the substrate phonons on the plasmon damping. Furthermore, we observed edge plasmons: peculiar one-dimensional modes propagating strictly along the edges of our patterned graphene nanostructures.

Published

2015

28. Plasmons in graphene moiré superlattices

Author

Ni, GX, Wang, H, Wu, JS, Fei, Z, Goldflam, MD, Keilmann, F, Özyilmaz, B, Castro Neto, AH, Xie, XM, Fogler, MM, and Basov, DN

Subjects

Physical Sciences, Condensed Matter Physics, Nanoscience & Nanotechnology

Abstract

Moiré patterns are periodic superlattice structures that appear when two crystals with a minor lattice mismatch are superimposed. A prominent recent example is that of monolayer graphene placed on a crystal of hexagonal boron nitride. As a result of the moiré pattern superlattice created by this stacking, the electronic band structure of graphene is radically altered, acquiring satellite sub-Dirac cones at the superlattice zone boundaries. To probe the dynamical response of the moiré graphene, we use infrared (IR) nano-imaging to explore propagation of surface plasmons, collective oscillations of electrons coupled to IR light. We show that interband transitions associated with the superlattice mini-bands in concert with free electrons in the Dirac bands produce two additive contributions to composite IR plasmons in graphene moiré superstructures. This novel form of collective modes is likely to be generic to other forms of moiré-forming superlattices, including van der Waals heterostructures.

Published

2015

29. Topological insulators are tunable waveguides for hyperbolic polaritons

Author

Wu, JS, Basov, DN, and Fogler, MM

Subjects

cond-mat.mes-hall, physics.optics, Fluids & Plasmas, Physical Sciences, Chemical Sciences, Engineering

Abstract

We present a theoretical analysis showing that layered topological insulators, for example, Bi2Se3 are optically hyperbolic materials in the range of terahertz (THz) frequencies. As such, these topological insulators possess deeply subdiffractional, highly directional collective modes: hyperbolic phonon polaritons. We predict that in thin crystals the dispersion of these modes is split into discrete subbands and is strongly influenced by electron surface states. If the surface states are doped, then hybrid collective modes result from coupling of the phonon polaritons with surface plasmons. The strength of the hybridization can be controlled by an external gate that varies the chemical potential of the surface states. We also show that the momentum dependence of the plasmon-phonon coupling leads to a polaritonic analog of the Goos-Hänchen effect. The directionality of the polaritonic rays and their tunable Goos-Hänchen shift is observable via THz nanoimaging.

Published

2015

30. Measurement of exciton correlations using electrostatic lattices

Author

Remeika, M, Leonard, JR, Dorow, CJ, Fogler, MM, Butov, LV, Hanson, M, and Gossard, AC

Subjects

cond-mat.mes-hall, Fluids & Plasmas, Physical Sciences, Chemical Sciences, Engineering

Abstract

We present a method for determining correlations in a gas of indirect excitons in a semiconductor quantum well structure. The method involves subjecting the excitons to a periodic electrostatic potential that causes modulations of the exciton density and photoluminescence (PL). Experimentally measured amplitudes of energy and intensity modulations of exciton PL serve as an input to a theoretical estimate of the exciton correlation parameter and temperature. We also present a proof-of-principle demonstration of the method for determining the correlation parameter and discuss how its accuracy can be improved.

Published

2015

31. Sum-Rule Constraints on the Surface State Conductance of Topological Insulators

Author

Post, KW, Chapler, BC, Liu, MK, Wu, JS, Stinson, HT, Goldflam, MD, Richardella, AR, Lee, JS, Reijnders, AA, Burch, KS, Fogler, MM, Samarth, N, and Basov, DN

Subjects

Mathematical Sciences, Physical Sciences, Engineering, General Physics

Abstract

We report the Drude oscillator strength D and the magnitude of the bulk band gap E_{g} of the epitaxially grown, topological insulator (Bi,Sb)_{2}Te_{3}. The magnitude of E_{g}, in conjunction with the model independent f-sum rule, allows us to establish an upper bound for the magnitude of D expected in a typical Dirac-like system composed of linear bands. The experimentally observed D is found to be at or below this theoretical upper bound, demonstrating the effectiveness of alloying in eliminating bulk charge carriers. Moreover, direct comparison of the measured D to magnetoresistance measurements of the same sample supports assignment of the observed low-energy conduction to topological surface states.

Published

2015

32. Tunneling Plasmonics in Bilayer Graphene

Author

Fei, Z, Iwinski, EG, Ni, GX, Zhang, LM, Bao, W, Rodin, AS, Lee, Y, Wagner, M, Liu, MK, Dai, S, Goldflam, MD, Thiemens, M, Keilmann, F, Lau, CN, Castro-Neto, AH, Fogler, MM, and Basov, DN

Subjects

Infrared nanoimaging, bilayer graphene, plasmons, tunneling, plasmon-off region, cond-mat.mes-hall, Nanoscience & Nanotechnology

Abstract

We report experimental signatures of plasmonic effects due to electron tunneling between adjacent graphene layers. At subnanometer separation, such layers can form either a strongly coupled bilayer graphene with a Bernal stacking or a weakly coupled double-layer graphene with a random stacking order. Effects due to interlayer tunneling dominate in the former case but are negligible in the latter. We found through infrared nanoimaging that bilayer graphene supports plasmons with a higher degree of confinement compared to single- and double-layer graphene, a direct consequence of interlayer tunneling. Moreover, we were able to shut off plasmons in bilayer graphene through gating within a wide voltage range. Theoretical modeling indicates that such a plasmon-off region is directly linked to a gapped insulating state of bilayer graphene, yet another implication of interlayer tunneling. Our work uncovers essential plasmonic properties in bilayer graphene and suggests a possibility to achieve novel plasmonic functionalities in graphene few-layers.

Published

2015

33. Graphene on hexagonal boron nitride as a tunable hyperbolic metamaterial

Author

Dai, S, Ma, Q, Liu, MK, Andersen, T, Fei, Z, Goldflam, MD, Wagner, M, Watanabe, K, Taniguchi, T, Thiemens, M, Keilmann, F, Janssen, GCAM, Zhu, S-E, Jarillo-Herrero, P, Fogler, MM, and Basov, DN

Subjects

cond-mat.mes-hall, Nanoscience & Nanotechnology

Abstract

Hexagonal boron nitride (h-BN) is a natural hyperbolic material, in which the dielectric constants are the same in the basal plane (ε(t) ≡ ε(x) = ε(y)) but have opposite signs (ε(t)ε(z)

Published

2015

34. Hamiltonian Optics of Hyperbolic Polaritons in Nanogranules

Author

Sun, Zhiyuan, Gutiérrez-Rubio, Á, Basov, DN, and Fogler, MM

Subjects

Hyperbolic materials, boron nitride, polariton, nanoresonator, Purcell's factor, semiclassical quantization, Purcell’s factor, cond-mat.mes-hall, Nanoscience & Nanotechnology

Abstract

Semiclassical quantization rules and numerical calculations are applied to study polariton modes of materials whose permittivity tensor has principal values of opposite sign (so-called hyperbolic materials). The spectra of volume- and surface-confined polaritons are computed for spheroidal nanogranules of hexagonal boron nitride, a natural hyperbolic crystal. The field distribution created by polaritons excited by an external dipole source is predicted to exhibit raylike patterns due to classical periodic orbits. Near-field infrared imaging and Purcell-factor measurements are suggested to test these predictions.

Published

2015

35. Electronic response of graphene to linelike charge perturbations

Author

Jiang, BY and Fogler, MM

Subjects

cond-mat.mes-hall, Fluids & Plasmas, Physical Sciences, Chemical Sciences, Engineering

Abstract

The problem of electrostatic screening of a charged line by undoped or weakly doped graphene is treated beyond the linear-response theory. The induced electron density is found to be approximately doping independent, n(x)∼x-2log2x, at intermediate distances x from the charged line. At larger x, twin p-n junctions may form if the external perturbation is repulsive for graphene charge carriers. The effect of such inhomogeneities on conductance and quantum capacitance of graphene is calculated. The results are relevant for transport properties of graphene grain boundaries and for local electrostatic control of graphene with ultrathin gates.

Published

2015

36. Subdiffractional focusing and guiding of polaritonic rays in a natural hyperbolic material.

Author

Dai, S, Ma, Q, Andersen, T, Mcleod, AS, Fei, Z, Liu, MK, Wagner, M, Watanabe, K, Taniguchi, T, Thiemens, M, Keilmann, F, Jarillo-Herrero, P, Fogler, MM, and Basov, DN

Subjects

cond-mat.mes-hall, physics.optics

Abstract

Uniaxial materials whose axial and tangential permittivities have opposite signs are referred to as indefinite or hyperbolic media. In such materials, light propagation is unusual leading to novel and often non-intuitive optical phenomena. Here we report infrared nano-imaging experiments demonstrating that crystals of hexagonal boron nitride, a natural mid-infrared hyperbolic material, can act as a 'hyper-focusing lens' and as a multi-mode waveguide. The lensing is manifested by subdiffractional focusing of phonon-polaritons launched by metallic disks underneath the hexagonal boron nitride crystal. The waveguiding is revealed through the modal analysis of the periodic patterns observed around such launchers and near the sample edges. Our work opens new opportunities for anisotropic layered insulators in infrared nanophotonics complementing and potentially surpassing concurrent artificial hyperbolic materials with lower losses and higher optical localization.

Published

2015

37. Scattering of two-dimensional massless Dirac electrons by a circular potential barrier

Author

Wu, JS and Fogler, MM

Subjects

cond-mat.mes-hall, Fluids & Plasmas, Physical Sciences, Chemical Sciences, Engineering

Abstract

We calculate the differential, total, and transport cross-sections for scattering of two-dimensional massless Dirac electrons by a circular barrier. For scatterer of a small radius, the cross-sections are dominated by quantum effects such as resonant scattering that can be computed using the partial-wave series. Scattering by larger size barriers is better described within the classical picture of reflection and refraction of rays, which leads to phenomena of caustics, rainbow, and critical scattering. Refraction can be negative if the potential of the scatterer is repulsive, so that a p-n junction forms at its boundary. Qualitative differences of this case from the n-N doping case are examined. Quantum interference effects beyond the classical ray picture are also considered, such as normal and anomalous diffraction, and also whispering-gallery resonances. Implications of these results for transport and scanned-probe experiments in graphene and topological insulators are discussed.

Published

2014

38. Model for quantitative tip-enhanced spectroscopy and the extraction of nanoscale-resolved optical constants

Author

McLeod, AS, Kelly, P, Goldflam, MD, Gainsforth, Z, Westphal, AJ, Dominguez, G, Thiemens, MH, Fogler, MM, and Basov, DN

Subjects

cond-mat.mtrl-sci, physics.optics, Fluids & Plasmas, Physical Sciences, Chemical Sciences

Abstract

Near-field infrared spectroscopy by elastic scattering of light from a probe tip resolves optical contrasts in materials at dramatically subwavelength scales across a broad energy range, with the demonstrated capacity for chemical identification at the nanoscale. However, current models of probe-sample near-field interactions still cannot provide a sufficiently quantitatively interpretation of measured near-field contrasts, especially in the case of materials supporting strong surface phonons. We present a model of near-field spectroscopy derived from basic principles and verified by finite-element simulations, demonstrating superb predictive agreement both with tunable quantum cascade laser near-field spectroscopy of SiO2 thin films and with newly presented nanoscale Fourier transform infrared (nanoFTIR) spectroscopy of crystalline SiC. We discuss the role of probe geometry, field retardation, and surface mode dispersion in shaping the measured near-field response. This treatment enables a route to quantitatively determine nanoresolved optical constants, as we demonstrate by inverting newly presented nanoFTIR spectra of an SiO2 thin film into the frequency dependent dielectric function of its mid-infrared optical phonon. Our formalism further enables tip-enhanced spectroscopy as a potent diagnostic tool for quantitative nanoscale spectroscopy. © 2014 American Physical Society.

Published

2014

39. Colloquium: Graphene spectroscopy

Author

Basov, DN, Fogler, MM, Lanzara, A, Wang, F, and Zhang, Y

Subjects

cond-mat.mes-hall, Physical Sciences, Fluids & Plasmas

Abstract

Spectroscopic studies of electronic phenomena in graphene are reviewed. A variety of methods and techniques are surveyed, from quasiparticle spectroscopies (tunneling, photoemission) to methods probing density and current response (infrared optics, Raman) to scanning probe nanoscopy and ultrafast pump-probe experiments. Vast complimentary information derived from these investigations is shown to highlight unusual properties of Dirac quasiparticles and many-body interaction effects in the physics of graphene. © 2014 American Physical Society.

Published

2014

40. Infrared nanospectroscopy and imaging of collective superfluid excitations in anisotropic superconductors

Author

Stinson, HT, Wu, JS, Jiang, BY, Fei, Z, Rodin, AS, Chapler, BC, McLeod, AS, Castro Neto, A, Lee, YS, Fogler, MM, and Basov, DN

Subjects

Bioengineering, cond-mat.supr-con, cond-mat.mes-hall, Fluids & Plasmas, Physical Sciences, Chemical Sciences

Abstract

We investigate near-field infrared spectroscopy and superfluid polariton imaging experiments on conventional and unconventional superconductors. Our modeling shows that near-field spectroscopy can measure the magnitude of the superconducting energy gap in Bardeen-Cooper-Schrieffer-like superconductors with nanoscale spatial resolution. We demonstrate how the same technique can measure the c-axis plasma frequency, and thus the c-axis superfluid density, of layered unconventional superconductors with a similar spatial resolution. Our modeling also shows that near-field techniques can image superfluid surface mode interference patterns near physical and electronic boundaries. We describe how these images can be used to extract the collective mode dispersion of anisotropic superconductors with subdiffractional spatial resolution. © 2014 American Physical Society.

Published

2014

41. Tunable Phonon Polaritons in Atomically Thin van der Waals Crystals of Boron Nitride

Author

Dai, S, Fei, Z, Ma, Q, Rodin, AS, Wagner, M, McLeod, AS, Liu, MK, Gannett, W, Regan, W, Watanabe, K, Taniguchi, T, Thiemens, M, Dominguez, G, Neto, AH Castro, Zettl, A, Keilmann, F, Jarillo-Herrero, P, Fogler, MM, and Basov, DN

Subjects

General Science & Technology

Abstract

van der Waals heterostructures assembled from atomically thin crystalline layers of diverse two-dimensional solids are emerging as a new paradigm in the physics of materials. We used infrared nanoimaging to study the properties of surface phonon polaritons in a representative van der Waals crystal, hexagonal boron nitride. We launched, detected, and imaged the polaritonic waves in real space and altered their wavelength by varying the number of crystal layers in our specimens. The measured dispersion of polaritonic waves was shown to be governed by the crystal thickness according to a scaling law that persists down to a few atomic layers. Our results are likely to hold true in other polar van der Waals crystals and may lead to new functionalities.

Published

2014

42. High-temperature superfluidity with indirect excitons in van der Waals heterostructures

Author

Fogler, MM, Butov, LV, and Novoselov, KS

Subjects

cond-mat.mes-hall, cond-mat.mtrl-sci

Abstract

All known superfluid and superconducting states of condensed matter are enabled by composite bosons (atoms, molecules and Cooper pairs) made of an even number of fermions. Temperatures where such macroscopic quantum phenomena occur are limited by the lesser of the binding energy and the degeneracy temperature of the bosons. High-critical temperature cuprate superconductors set the present record of ~100 K. Here we propose a design for artificially structured materials to rival this record. The main elements of the structure are two monolayers of a transition metal dichalcogenide separated by an atomically thin spacer. Electrons and holes generated in the system would accumulate in the opposite monolayers and form bosonic bound states--the indirect excitons. The resultant degenerate Bose gas of indirect excitons would exhibit macroscopic occupation of a quantum state and vanishing viscosity at high temperatures.

Published

2014

43. Electronic and plasmonic phenomena at graphene grain boundaries

Author

Fei, Z, Rodin, AS, Gannett, W, Dai, S, Regan, W, Wagner, M, Liu, MK, McLeod, AS, Dominguez, G, Thiemens, M, Castro Neto, Antonio H, Keilmann, F, Zettl, A, Hillenbrand, R, Fogler, MM, and Basov, DN

Subjects

Physical Sciences, Engineering, Nanotechnology, Condensed Matter Physics, cond-mat.mes-hall, Nanoscience & Nanotechnology

Abstract

Graphene, a two-dimensional honeycomb lattice of carbon atoms of great interest in (opto)electronics and plasmonics, can be obtained by means of diverse fabrication techniques, among which chemical vapour deposition (CVD) is one of the most promising for technological applications. The electronic and mechanical properties of CVD-grown graphene depend in large part on the characteristics of the grain boundaries. However, the physical properties of these grain boundaries remain challenging to characterize directly and conveniently. Here we show that it is possible to visualize and investigate the grain boundaries in CVD-grown graphene using an infrared nano-imaging technique. We harness surface plasmons that are reflected and scattered by the graphene grain boundaries, thus causing plasmon interference. By recording and analysing the interference patterns, we can map grain boundaries for a large-area CVD graphene film and probe the electronic properties of individual grain boundaries. Quantitative analysis reveals that grain boundaries form electronic barriers that obstruct both electrical transport and plasmon propagation. The effective width of these barriers (∼10-20 nm) depends on the electronic screening and is on the order of the Fermi wavelength of graphene. These results uncover a microscopic mechanism that is responsible for the low electron mobility observed in CVD-grown graphene, and suggest the possibility of using electronic barriers to realize tunable plasmon reflectors and phase retarders in future graphene-based plasmonic circuits.

Published

2013

44. Plasmonic Hot Spots in Triangular Tapered Graphene Microcrystals

Author

Rodin, AS, Fei, Z, McLeod, AS, Wagner, M, Neto, AH Castro, Fogler, MM, and Basov, DN

Subjects

cond-mat.mes-hall

Abstract

Recently, plasmons in graphene have been observed experimentally usingscattering scanning near-field optical microscopy. In this paper, we develop asimplified analytical approach to describe the behavior in triangular samples.Replacing Coulomb interaction by a short-range one reduces the problem to aHelmholtz equation, amenable to analytical treatment. We demonstrate that evenwith our simplifications, the system still exhibits the key features seen inthe experiment.

Published

2013

45. Anisotropic Electronic State via Spontaneous Phase Separation in Strained Vanadium Dioxide Films

Author

Liu, MK, Wagner, M, Abreu, E, Kittiwatanakul, S, McLeod, A, Fei, Z, Goldflam, M, Dai, S, Fogler, MM, Lu, J, Wolf, SA, Averitt, RD, and Basov, DN

Subjects

Mathematical Sciences, Physical Sciences, Engineering, General Physics

Abstract

We resolved the enigma of anisotropic electronic transport in strained vanadium dioxide (VO2) films by inquiring into the role that strain plays in the nanoscale phase separation in the vicinity of the insulator-to-metal transition. The root source of the anisotropy was visualized as the formation of a peculiar unidirectional stripe state which accompanies the phase transition. Furthermore, nanoscale infrared spectroscopy unveils distinct facets of electron-lattice interplay at three different stages of the phase transition. These stages include the initial formation of sparse nonpercolating metallic domains without noticeable involvement of the lattice followed by an electron-lattice coupled anisotropic stripe state close to percolation which ultimately evolves into a nearly isotropic rutile metallic phase. Our results provide a unique mesoscopic perspective for the tunable macroscopic phenomena in strained metal oxide films.

Published

2013

46. Stripe and bubble phases in quantum Hall systems

Author

Fogler, MM

Subjects

cond-mat.mes-hall, Nuclear & Particles Physics

Abstract

We present a brief survey of the charge density wave phases of atwo-dimensional electron liquid in moderate to weak magnetic fields whereseveral higher Landau levels are occupied. The review follows the chronologicaldevelopment of this new and emerging field: from the ideas that led to theoriginal theoretical prediction of the novel ground states, to their dramaticexperimental discovery, to the currently pursued directions and open questions.

Published

2001

47. The Absence of the Fractional Quantum Hall Effect at High Landau Levels

Author

Fogler, MM and Koulakov, AA

Subjects

cond-mat

Abstract

We compare the energies of the Laughlin liquid and a charge density wave in aweak magnetic field for the upper Landau level filling factors $\nu_N = 1/3$and $1/5$. The charge density wave period has been optimized and was found tobe $\simeq 3R_c$, where $R_c$ is the cyclotron radius. We conclude that theoptimal charge density wave is more energetically preferable than the Laughlinliquid for the Landau level numbers $N \ge 2$ at $\nu_N = 1/3$ and for $N \ge3$ at $\nu_N = 1/5$. This implies that the $1/3$ fractional quantum Hall effectcannot be observed for $N \ge 2$, in agreement with the experiment.

Published

1996

48. Fizeau drag in graphene plasmonics

Author

Massachusetts Institute of Technology. Department of Physics, Dong, Y, Xiong, L, Phinney, IY, Sun, Z, Jing, R, McLeod, AS, Zhang, S, Liu, S, Ruta, FL, Gao, H, Dong, Z, Pan, R, Edgar, JH, Jarillo-Herrero, P, Levitov, LS, Millis, AJ, Fogler, MM, Bandurin, DA, Basov, DN, Massachusetts Institute of Technology. Department of Physics, Dong, Y, Xiong, L, Phinney, IY, Sun, Z, Jing, R, McLeod, AS, Zhang, S, Liu, S, Ruta, FL, Gao, H, Dong, Z, Pan, R, Edgar, JH, Jarillo-Herrero, P, Levitov, LS, Millis, AJ, Fogler, MM, Bandurin, DA, and Basov, DN

Abstract

Dragging of light by moving dielectrics was predicted by Fresnel and verified by Fizeau's celebrated experiments with flowing water. This momentous discovery is among the experimental cornerstones of Einstein's special relativity and is well understood in the context of relativistic kinematics. In contrast, experiments on dragging photons by an electron flow in solids are riddled with inconsistencies and so far eluded agreement with the theory. Here we report on the electron flow dragging surface plasmon polaritons (SPPs): hybrid quasiparticles of infrared photons and electrons in graphene. The drag is visualized directly through infrared nano-imaging of propagating plasmonic waves in the presence of a high-density current. The polaritons in graphene shorten their wavelength when launched against the drifting carriers. Unlike the Fizeau effect for light, the SPP drag by electrical currents defies the simple kinematics interpretation and is linked to the nonlinear electrodynamics of the Dirac electrons in graphene. The observed plasmonic Fizeau drag enables breaking of time-reversal symmetry and reciprocity at infrared frequencies without resorting to magnetic fields or chiral optical pumping.

Published

2022

49. Inductor coil of the highest possible [Formula: see text]

Author

Rikhter, A and Fogler, MM

Subjects

physics.class-ph

Abstract

The geometry of an inductor made of a long thin wire and having the highest possible Q-factor is found by numerical optimization. As frequency increases, the Q-factor first grows linearly and then according to a square-root law, while the cross-section of the optimal coil evolves from near-circular to sickle-shaped.

Published

2020

50. Plasmonic Hot Spots in Triangular Tapered Graphene Microcrystals

Author

Rodin, AS, Fei, Z, McLeod, AS, Wagner, M, Neto, AH Castro, Fogler, MM, and Basov, DN

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), cond-mat.mes-hall, FOS: Physical sciences

Abstract

Recently, plasmons in graphene have been observed experimentally using scattering scanning near-field optical microscopy. In this paper, we develop a simplified analytical approach to describe the behavior in triangular samples. Replacing Coulomb interaction by a short-range one reduces the problem to a Helmholtz equation, amenable to analytical treatment. We demonstrate that even with our simplifications, the system still exhibits the key features seen in the experiment., 4 pages, 3 figures

Published

2016