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1. Efficient light upconversion via resonant exciton-exciton annihilation of dark excitons in few-layer transition metal dichalcogenides

Author

Chen, Yi-Hsun, Lo, Ping-Yuan, Boschen, Kyle W., Peng, Guan-Hao, Huang, Chun-Jui, Holtzman, Luke N., Hsu, Chih-En, Hsu, Yung-Ning, Holbrook, Madisen, Wang, Wei-Hua, Barmak, Katayun, Hone, James, Hawrylak, Pawel, Hsueh, Hung-Chung, Davis, Jeffrey A., Cheng, Shun-Jen, Fuhrer, Michael S., and Chen, Shao-Yu

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

In this work, we report a pronounced light upconversion in few-layer transition metal dichalcogenides. Our joint theory-experiment study attributes the upconversion photoluminescence to a resonant exciton-exciton annihilation involving a pair of dark excitons with opposite momenta, followed by the spontaneous emission of upconverted bright excitons, which can have a high upconversion efficiency. Additionally, the upconversion photoluminescence is generic in MoS2, MoSe2, WS2, and WSe2, showing a high tuneability from green to ultraviolet light.

Published
2024

2. Superconductivity in twisted bilayer WSe$_2$

Author

Guo, Yinjie, Pack, Jordan, Swann, Joshua, Holtzman, Luke, Cothrine, Matthew, Watanabe, Kenji, Taniguchi, Takashi, Mandrus, David, Barmak, Katayun, Hone, James, Millis, Andrew J., Pasupathy, Abhay N., and Dean, Cory R.

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

The discovery of superconductivity in twisted bilayer and twisted trilayer graphene has generated tremendous interest. The key feature of these systems is an interplay between interlayer coupling and a moir\'e superlattice that gives rise to low-energy flat bands with strong correlations. Flat bands can also be induced by moir\'e patterns in lattice-mismatched and or twisted heterostructures of other two-dimensional materials such as transition metal dichalcogenides (TMDs). Although a wide range of correlated phenomenon have indeed been observed in the moir\'e TMDs, robust demonstration of superconductivity has remained absent. Here we report superconductivity in 5 degree twisted bilayer WSe$_2$ (tWSe$_2$) with a maximum critical temperature of 426 mK. The superconducting state appears in a limited region of displacement field and density that is adjacent to a metallic state with Fermi surface reconstruction believed to arise from antiferromagnetic order. A sharp boundary is observed between the superconducting and magnetic phases at low temperature, reminiscent of spin-fluctuation mediated superconductivity. Our results establish that moir\'e flat-band superconductivity extends beyond graphene structures. Material properties that are absent in graphene but intrinsic among the TMDs such as a native band gap, large spin-orbit coupling, spin-valley locking, and magnetism offer the possibility to access a broader superconducting parameter space than graphene-only structures.

Published
2024

3. Automated Grain Boundary Detection for Bright-Field Transmission Electron Microscopy Images via U-Net

Author

Patrick, Matthew J., Eckstein, James K., Lopez, Javier R., Toderas, Silvia, Asher, Sarah A., Whang, Sylvia I., Levine, Stacey, Rickman, Jeffrey M., and Barmak, Katayun

Subjects
Condensed Matter - Materials Science
Abstract

Quantification of microstructures is crucial for understanding processing-structure and structure-property relationships in polycrystalline materials. Delineating grain boundaries in bright-field transmission electron micrographs, however, is challenging due to complex diffraction contrast in images. Conventional edge detection algorithms are inadequate; instead, manual tracing is usually required. This study demonstrates the first successful machine-learning approach for grain-boundary detection in bright-field transmission electron micrographs. The proposed methodology uses a U-Net convolutional neural network trained on carefully constructed data from bright-field images and hand-tracings available from prior studies, combined with targeted post-processing algorithms to preserve fine features of interest. The image processing pipeline accurately estimates grain-boundary positions, avoiding segmentation in regions with intragrain contrast and identifying low-contrast boundaries. Our approach is validated by directly comparing microstructural markers (i.e., grain centroids) identified in U-Net predictions with those identified in hand tracings; furthermore, the grain size distributions obtained from the two techniques show notable overlap when compared using t-, Kolmogorov-Smirnov, and Cramer-von Mises tests. The technique is then successfully applied to interpret new aluminum film microstructures having different image characteristics from the training data, and preliminary results from Pt and Pd microstructures are presented, highlighting the versatility of our approach for grain-boundary identification in bright-field micrographs.

Published
2023
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4. Detecting Atomic Scale Surface Defects in STM of TMDs with Ensemble Deep Learning

Author

Smalley, Darian, Lough, Stephanie D., Holtzman, Luke, Xu, Kaikui, Holbrook, Madisen, Rosenberger, Matthew R., Hone, J. C., Barmak, Katayun, and Ishigami, Masahiro

Subjects
Condensed Matter - Materials Science, Computer Science - Machine Learning
Abstract

Atomic-scale defect detection is shown in scanning tunneling microscopy images of single crystal WSe2 using an ensemble of U-Net-like convolutional neural networks. Standard deep learning test metrics indicated good detection performance with an average F1 score of 0.66 and demonstrated ensemble generalization to C-AFM images of WSe2 and STM images of MoSe2. Defect coordinates were automatically extracted from defect detections maps showing that STM image analysis enhanced by machine learning can be used to dramatically increase sample characterization throughput., Comment: 9 pages, 4 figures, submitted to MRS Advances as a conference preceding for the 2023 MRS Fall Meeting & Exhibit

Published
2023

8. Reproducible graphene synthesis by oxygen-free chemical vapour deposition

Author

Amontree, Jacob, Yan, Xingzhou, DiMarco, Christopher S., Levesque, Pierre L., Adel, Tehseen, Pack, Jordan, Holbrook, Madisen, Cupo, Christian, Wang, Zhiying, Sun, Dihao, Biacchi, Adam J., Wilson-Stokes, Charlezetta E., Watanabe, Kenji, Taniguchi, Takashi, Dean, Cory R., Hight Walker, Angela R., Barmak, Katayun, Martel, Richard, and Hone, James

Published
2024
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9. Highly tunable room-temperature plexcitons in monolayer WSe2 /gap-plasmon nanocavities

Author

Darlington, Thomas P., Rahaman, Mahfujur, Kwock, Kevin W. C., Yanev, Emanuil, Wu, Xuehao, Holtzman, Luke N., Holbrook, Madisen, Kim, Gwangwoo, Ma, Kyung Yeol, Shin, Hyeon Suk, Krayev, Andrey, Strasbourg, Matthew, Borys, Nicholas J., Basov, D. N., Barmak, Katayun, Hone, James C., Pasupathy, Abhay N., Jariwala, Deep, and Schuck, P. James

Subjects
Physics - Optics, Quantum Physics
Abstract

The advancement of quantum photonic technologies relies on the ability to precisely control the degrees of freedom of optically active states. Here, we realize real-time, room-temperature tunable strong plasmon-exciton coupling in 2D semiconductor monolayers enabled by a general approach that combines strain engineering plus force- and voltage-adjustable plasmonic nanocavities. We show that the exciton energy and nanocavity plasmon resonance can be controllably toggled in concert by applying pressure with a plasmonic nanoprobe, allowing in operando control of detuning and coupling strength, with observed Rabi splittings >100 meV. Leveraging correlated force spectroscopy, nano-photoluminescence (nano-PL) and nano-Raman measurements, augmented with electromagnetic simulations, we identify distinct polariton bands and dark polariton states, and map their evolution as a function of nanogap and strain tuning. Uniquely, the system allows for manipulation of coupling strength over a range of cavity parameters without dramatically altering the detuning. Further, we establish that the tunable strong coupling is robust under multiple pressing cycles and repeated experiments over multiple nanobubbles. Finally, we show that the nanogap size can be directly modulated via an applied DC voltage between the substrate and plasmonic tip, highlighting the inherent nature of the concept as a plexcitonic nano-electro-mechanical system (NEMS). Our work demonstrates the potential to precisely control and tailor plexciton states localized in monolayer (1L) transition metal dichalcogenides (TMDs), paving the way for on-chip polariton-based nanophotonic applications spanning quantum information processing to photochemistry., Comment: 17 pages, 4 figures

Published
2023

10. Charge-transfer Contact to a High-Mobility Monolayer Semiconductor

Author

Pack, Jordan, Guo, Yinjie, Liu, Ziyu, Jessen, Bjarke S., Holtzman, Luke, Liu, Song, Cothrine, Matthew, Watanabe, Kenji, Taniguchi, Takashi, Mandrus, David G., Barmak, Katayun, Hone, James, and Dean, Cory R.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Two-dimensional (2D) semiconductors, such as the transition metal dichalcogenides, have demonstrated tremendous promise for the development of highly tunable quantum devices. Realizing this potential requires low-resistance electrical contacts that perform well at low temperatures and low densities where quantum properties are relevant. Here we present a new device architecture for 2D semiconductors that utilizes a charge-transfer layer to achieve large hole doping in the contact region, and implement this technique to measure magneto-transport properties of high-purity monolayer WSe$_2$. We measure a record-high hole mobility of 80,000 cm$^2$/Vs and access channel carrier densities as low as $1.6\times10^{11}$ cm$^{-2}$, an order of magnitude lower than previously achievable. Our ability to realize transparent contact to high-mobility devices at low density enables transport measurement of correlation-driven quantum phases including observation of a low temperature metal-insulator transition in a density and temperature regime where Wigner crystal formation is expected, and observation of the fractional quantum Hall effect under large magnetic fields. The charge transfer contact scheme paves the way for discovery and manipulation of new quantum phenomena in 2D semiconductors and their heterostructures.

Published
2023
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11. Spontaneous Exciton Dissociation in Transition Metal Dichalcogenide Monolayers

Author

Handa, Taketo, Holbrook, Madisen A., Olsen, Nicholas, Holtzman, Luke N., Huber, Lucas, Wang, Hai I., Bonn, Mischa, Barmak, Katayun, Hone, James C., Pasupathy, Abhay N., and Zhu, X. -Y.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Since the seminal work on MoS2 monolayers, photoexcitation in atomically-thin transition metal dichalcogenides (TMDCs) has been assumed to result in excitons with large binding energies (~ 200-600 meV). Because the exciton binding energies are order-of-magnitude larger than thermal energy at room temperature, it is puzzling that photocurrent and photovoltage generation have been observed in TMDC-based devices, even in monolayers with applied electric fields far below the threshold for exciton dissociation. Here, we show that the photoexcitation of TMDC monolayers results in a substantial population of free charges. Performing ultrafast terahertz (THz) spectroscopy on large-area, single crystal WS2, WSe2, and MoSe2 monolayers, we find that ~10% of excitons spontaneously dissociate into charge carriers with lifetimes exceeding 0.2 ns. Scanning tunnelling microscopy reveals that photo-carrier generation is intimately related to mid-gap defect states, likely via trap-mediated Auger scattering. Only in state-of-the-art quality monolayers14, with mid-gap trap densities as low as 10^9 cm^-2, does intrinsic exciton physics start to dominate the THz response. Our findings reveal that excitons or excitonic complexes are only the predominant quasiparticles in photo-excited TMDC monolayers at the limit of sufficiently low defect densities., Comment: 18 pages, 5 figures, SI

Published
2023

12. Two-step flux synthesis of ultrapure transition metal dichalcogenides

Author

Liu, Song, Liu, Yang, Holtzman, Luke Nemetz, Li, Baichang, Holbrook, Madisen, Pack, Jordan, Taniguchi, Takashi, Watanabe, Kenji, Dean, Cory R., Pasupathy, Abhay, Barmak, Katayun, Rhodes, Daniel A., and Hone, James

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

Here, we describe synthesis of TMD crystals using a two-step flux growth method that eliminates a major potential source of contamination. Detailed characterization of TMDs grown by this two-step method reveals charged and isovalent defects with densities an order of magnitude lower than in TMDs grown by a single-step flux technique. Initial temperature-dependent electrical transport measurements of monolayer WSe2 yield room-temperature hole mobility above 840 cm2/Vs and low-temperature disorder-limited mobility above 44,000 cm2/Vs. Electrical transport measurements of graphene-WSe2 heterostructures fabricated from the two-step flux grown WSe2 also show superior performance: higher graphene mobility, lower charged impurity density, and well-resolved integer quantum Hall states.

Published
2023

13. Equilibrium densities of intrinsic defects in transition metal diselenides of molybdenum and tungsten.

Author

Holtzman, Luke N., Vargas, Preston Allen, Hennig, Richard G., and Barmak, Katayun

Subjects
THERMAL equilibrium, CHEMICAL vapor deposition, POINT defects, DENSITY functional theory, TRANSITION metals
Abstract

Point defects are thermodynamically stabilized in all crystalline materials, with increased densities negatively impacting the properties and performance of transition metal dichalcogenides (TMDs). While recent point defect reduction methods have led to considerable improvements in the optoelectronic properties of TMDs, there is a clear need for theoretical work to establish the lower limit of defect densities, as represented by thermal equilibrium. To that end, an ab initio and thermodynamic analysis of the equilibrium densities of intrinsic point defects in MoSe2 and WSe2 is presented. The intrinsic defect formation energies at the limits of the selenium and metal-rich regimes are determined by density functional theory (DFT) and then augmented with elemental chemical potential functions to determine temperature- and pressure-dependent formation energies. Equilibrium defect densities are determined for MSe, SeM, vM, and vSe, where M and v, respectively, represent the metal and the vacancy, as a function of synthesis temperature and pressure. The effects of vibrational free energy contributions and treatment of the DFT exchange–correlation potential are found to be non-negligible. Calculated equilibrium densities are several orders of magnitude below reported defect densities in TMDs made by chemical vapor deposition, chemical vapor transport, and flux methods, thereby establishing that current synthesis methods are either kinetically limited or impurity dominated. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Relative Grain Boundary Energies from Triple Junction Geometry: Limitations to Assuming the Herring Condition in Nanocrystalline Thin Films

Author

Patrick, Matthew J., Rohrer, Gregory S., Chirayutthanasak, Ooraphan, Ratanaphan, Sutach, Homer, Eric R., Hart, Gus L. W., Epshteyn, Yekaterina, and Barmak, Katayun

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

Grain boundary character distributions (GBCD) are routinely measured from bulk microcrystalline samples by electron backscatter diffraction (EBSD) and serial sectioning can be used to reconstruct relative grain boundary energy distributions (GBED) based on the 3D geometry of triple lines, assuming that the Herring condition of force balance is satisfied. These GBEDs correlate to those predicted from molecular dynamics (MD); furthermore, the GBCD and GBED are found to be inversely correlated. For nanocrystalline thin films, orientation mapping via precession enhanced electron diffraction (PED) has proven effective in measuring the GBCD, but the GBED has not been extracted. Here, the established relative energy extraction technique is adapted to PED data from four sputter deposited samples: a 40 nm-thick tungsten film and a 100 nm aluminum film as-deposited, after 30 and after 150 minutes annealing at 400{\deg}C. These films have columnar grain structures, so serial sectioning is not required to determine boundary inclination. Excepting the most energetically anisotropic and highest population boundaries, i.e. aluminum {\Sigma}3 boundaries, the relative GBED extracted from these data do not correlate with energies calculated using MD nor do they inversely correlate with the experimentally determined GBCD for either the tungsten or aluminum films. Failure to reproduce predicted energetic trends implies that the conventional Herring equation cannot be applied to determine relative GBEDs and thus geometries at triple junctions in these films are not well described by this condition; additional geometric factors must contribute to determining triple junction geometry and boundary network structure in spatially constrained, polycrystalline materials., Comment: The document contains the manuscript, figure captions, and a short supplemental document with further details

Published
2022
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15. P-type Ohmic contact to monolayer WSe2 field-effect transistors using high electron affinity amorphous MoO3

Author

Chen, Yi-Hsun, Xing, Kaijian, Liu, Song, Holtzman, Luke, Creedon, Daniel L., McCallum, Jeffrey C., Watanabe, Kenji, Taniguchi, Takashi, Barmak, Katayun, Hone, James, Hamilton, Alexander R., Chen, Shao-Yu, and Fuhrer, Michael S.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

1 School of Physics and Astronomy, Monash University, Clayton, Victoria 3800, Australia 2 Australian Research Council Centre of Excellence in Future Low-Energy Electronics Technologies (FLEET), Monash University, Clayton, Victoria 3800, Australia 3 Department of Mechanical Engineering, Columbia University, New York, New York 10027, United States 4 Department of Applied Physics and Applied Mathematics, Columbia University, New York, New York 10027, United States 5 School of Physics, the University of Melbourne, Melbourne, VIC 3010, Australia 6 Research Center for Functional Materials, National Institute for Materials Science, 1-1 Namiki, Tsukuba 305-0044, Japan 7 International Center for Materials Nanoarchitectonics, National Institute for Materials Science, 1-1 Namiki, Tsukuba 305-0044, Japan 8 School of Physics, University of New South Wales, 2052 Sydney, Australia 9 Center of Condensed Matter Sciences and Center of Atomic Initiative for New Material, National Taiwan University, Taipei 106, Taiwan 10 Monash Centre for Atomically Thin Materials, Monash University, Clayton, 3800, VIC, Australia

Published
2022

16. Characterization of quantum dot-like emitters in programmable arrays of nanowrinkles of 1L-WSe2.

Author

Strasbourg, Matthew C., Yanev, Emanuil S., Darlington, Thomas P., Faagau, Kavika, Holtzman, Luke N., Barmak, Katayun, Hone, James C., Schuck, P. James, and Borys, Nicholas J.

Subjects
PHOTONS, LIGHT emitting diodes, ATOMIC force microscopy, THERMOCYCLING, QUANTUM states
Abstract

When combined with nanostructured substrates, two-dimensional semiconductors can be engineered with strain to tailor light–matter interactions on the nanoscale. Recently, room-temperature nanoscale exciton localization with controllable wrinkling in 1L-WSe2 was achieved using arrays of gold nanocones. Here, the characterization of quantum dot-like states and single-photon emitters in the 1L-WSe2/nanocone system is reported. The nanocones induce a wide range of strains, and as a result, a diverse ensemble of narrowband, potential single-photon emitters is observed. The distribution of emitter energies reveals that most reside in two spectrally isolated bands, leaving a less populated intermediate band that is spectrally isolated from the ensembles. The spectral isolation is advantageous for high-purity quantum light emitters, and anti-bunched emission from one of these states is confirmed up to 25 K. Although the spatial distribution of strain is expected to influence the orientation of the transition dipoles of the emitters, multimodal emission polarization anisotropy and atomic force microscopy reveal that the macroscopic orientation of the wrinkles is not a good predictor of dipole orientation. Finally, the emission is found to change with thermal cycling from 4 to 290 K and back to 4 K, highlighting the need to control factors such as temperature-induced strain to enhance the robustness of this quantum emitter platform. The initial characterization here shows that controlled nanowrinkles of 1L-WSe2 generate quantum light in addition to uncovering potential challenges that need to be addressed for their adoption into quantum photonic technologies. [ABSTRACT FROM AUTHOR]

Published
2024
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18. Bilayer WSe$_2$ as a natural platform for interlayer exciton condensates in the strong coupling limit

Author

Shi, Qianhui, Shih, En-Min, Rhodes, Daniel, Kim, Bumho, Barmak, Katayun, Watanabe, Kenji, Taniguchi, Takashi, Papić, Zlatko, Abanin, Dmitry A., Hone, James, and Dean, Cory R.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Exciton condensates (EC) are macroscopic coherent states arising from condensation of electron-hole pairs. Bilayer heterostructures, consisting of two-dimensional electron and hole layers separated by a tunnel barrier, provide a versatile platform to realize and study EC. The tunnel barrier suppresses recombination yielding long-lived excitons. However, this separation also reduces interlayer Coulomb interactions, limiting the exciton binding strength. Here, we report the observation of EC in naturally occurring 2H-stacked bilayer WSe$_2$. In this system, the intrinsic spin-valley structure suppresses interlayer tunneling even when the separation is reduced to the atomic limit, providing access to a previously unattainable regime of strong interlayer coupling. Using capacitance spectroscopy, we investigate magneto-EC, formed when partially filled Landau levels (LL) couple between the layers. We find that the strong-coupling EC show dramatically different behaviour compared with previous reports, including an unanticipated variation of the EC robustness with the orbital number, and find evidence for a transition between two types of low-energy charged excitations. Our results provide a demonstration of tuning EC properties by varying the constituent single-particle wavefunctions.

Published
2021
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19. Moir\'e-localized interlayer exciton wavefunctions captured by imaging its electron and hole constituents

Author

Karni, Ouri, Barré, Elyse, Pareek, Vivek, Georgaras, Johnathan D., Man, Michael K. L., Sahoo, Chakradhar, Bacon, David R., Zhu, Xing, Ribeiro, Henrique B., O'Beirne, Aidan L., Hu, Jenny, Al-Mahboob, Abdullah, Abdelrasoul, Mohamed M. M., Chan, Nicholas S., Karmakar, Arka, Winchester, Andrew J., Kim, Bumho, Watanabe, Kenji, Taniguchi, Takashi, Barmak, Katayun, Madéo, Julien, da Jornada, Felipe H., Heinz, Tony F., and Dani, Keshav M.

Subjects
Physics - Optics, Condensed Matter - Materials Science, Physics - Applied Physics, Physics - Chemical Physics
Abstract

Interlayer excitons (ILXs) - electron-hole pairs bound across two atomically thin layered semiconductors - have emerged as attractive platforms to study exciton condensation, single-photon emission and other quantum-information applications. Yet, despite extensive optical spectroscopic investigations, critical information about their size, valley configuration and the influence of the moir\'e potential remains unknown. Here, we captured images of the time- and momentum-resolved distribution of both the electron and the hole that bind to form the ILX in a WSe2/MoS2 heterostructure. We thereby obtain a direct measurement of the interlayer exciton diameter of ~5.4 nm, comparable to the moir\'e unit-cell length of 6.1 nm. Surprisingly, this large ILX is well localized within the moir\'e cell to a region of only 1.8 nm - smaller than the size of the exciton itself. This high degree of localization of the interlayer exciton is backed by Bethe-Salpeter equation calculations and demonstrates that the ILX can be localized within small moir\'e unit cells. Unlike large moir\'e cells, these are uniform over large regions, thus allowing the formation of extended arrays of localized excitations for quantum technology., Comment: 4 figures

Published
2021

20. Grain Growth and the Effect of Different Time Scales

Author

Barmak, Katayun, Dunca, Anastasia, Epshteyn, Yekaterina, Liu, Chun, and Mizuno, Masashi

Subjects
Condensed Matter - Materials Science, Mathematics - Analysis of PDEs, Mathematics - Numerical Analysis
Abstract

Many technologically useful materials are polycrystals composed of a myriad of small monocrystalline grains separated by grain boundaries. Dynamics of grain boundaries play a crucial role in determining the grain structure and defining the materials properties across multiple scales. In this work, we consider two models for the motion of grain boundaries with the dynamic lattice misorientations and the triple junctions drag, and we conduct extensive numerical study of the models, as well as present relevant experimental results of grain growth in thin films.

Published
2021

21. Tunable quantum confinement of neutral excitons using electric fields and exciton-charge interactions

Author

Thureja, Deepankur, Imamoglu, Atac, Smolenski, Tomasz, Popert, Alexander, Chervy, Thibault, Lu, Xiaobo, Liu, Song, Barmak, Katayun, Watanabe, Kenji, Taniguchi, Takashi, Norris, David J., Kroner, Martin, and Murthy, Puneet A.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases
Abstract

Quantum confinement is the discretization of energy when motion of particles is restricted to length scales smaller than their de Broglie wavelength. The experimental realization of this effect has had wide ranging impact in diverse fields of physics and facilitated the development of new technologies. In semiconductor physics, quantum confinement of optically excited quasiparticles, such as excitons or trions, is typically achieved by modulation of material properties - an approach crucially limited by the lack of insitu tunability and scalability of confining potentials. Achieving fully tunable quantum confinement of optical excitations has therefore been an outstanding goal in quantum photonics. Here, we demonstrate electrically controlled quantum confinement of neutral excitons in a gate-defined monolayer p-i-n diode. A combination of dc Stark shift induced by large in-plane fields and a previously unknown confining mechanism based on repulsive interaction between excitons and free charges ensures tight exciton confinement in the narrow neutral region. Quantization of exciton motion manifests in multiple discrete, spectrally narrow, voltage-dependent optical resonances that emerge below the free exciton resonance. Our measurements reveal several unique physical features of these quantum confined excitons, including an in-plane dipolar character, one-dimensional center-of-mass confinement, and strikingly enhanced exciton size in the presence of magnetic fields. Our method provides an experimental route towards creating scalable arrays of identical single photon sources, which will constitute building blocks of strongly correlated photonic systems.

Published
2021

22. Wafer-scale development, characterization, and high temperature stabilization of epitaxial Cr2O3 films grown on Ru(0001).

Author

Cumston, Quintin, Patrick, Matthew, Hegazy, Ahmed R., Zangiabadi, Amirali, Daughtry, Maximillian, Coffey, Kevin R., Barmak, Katayun, and Kaden, William E.

Subjects
CHROMIUM oxide, HIGH temperatures, SPUTTER deposition, TRANSMISSION electron microscopy, LATTICE constants
Abstract

This work outlines conditions suitable for the heteroepitaxial growth of Cr2O3(0001) films (1.5–20 nm thick) on a Ru(0001)-terminated substrate. Optimized growth is achieved by sputter deposition of Cr within a 4 mTorr Ar/O2 20% ambient at Ru temperatures ranging from 450 to 600 °C. The Cr2O3 film adopts a 30° rotated honeycomb configuration with respect to the underlying Ru(0001) substrate and exhibits a hexagonal lattice parameter consistent with that for bulk Cr2O3(0001). Heating to 700 °C within the same environment during film preparation leads to Ru oxidation. Exposure to temperatures at or above 400 °C in a vacuum, Ar, or Ar/H2 3% leads to chromia film degradation characterized by increased Ru 3d XPS intensity coupled with concomitant Cr 2p and O 1s peak attenuations when compared to data collected from unannealed films. An ill-defined but hexagonally well-ordered RuxCryOz surface structure is noted after heating the film in this manner. Heating within a wet Ar/H2 3% environment preserves the Cr2O3(0001)/Ru(0001) heterolayer structure to temperatures of at least 950 °C. Heating an Ru–Cr2O3–Ru heterostacked film to 950 °C within this environment is shown by cross-sectional scanning/transmission electron microscopy (S/TEM) to provide clear evidence of retained epitaxial bicrystalline oxide interlayer structure, interlayer immiscibility, and epitaxial registry between the top and bottom Ru layers. Subtle effects marked by O enrichment and O 1s and Cr 2p shifts to increased binding energies are noted by XPS in the near-Ru regions of Cr2O3(0001)/Ru(0001) and Ru(0001)/Cr2O3(0001)/Ru(0001) films after annealing to different temperatures in different sets of environmental conditions. [ABSTRACT FROM AUTHOR]

Published
2024
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23. Optical Measurement of Pseudo-Spin Texture of the Exciton Fine-Structure in Monolayer WSe2 within the Light Cone

Author

Schneider, Lorenz Maximilian, Esdaille, Shanece, Rhodes, Daniel, Barmak, Katayun, Hone, James, and Rahimi-Iman, Arash

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

Several theoretical predictions have claimed that the neutral exciton of TMDCs splits into a transversal and longitudinal exciton branch, with the longitudinal one, which is the upper branch, exhibiting an extraordinary strong dispersion in the meV range within the light cone. Historically, this was linked for semiconductor quantum wells to strong far-field optical dipole coupling, or strong electronic long-range exchange interactions, describing two sides of the same coin. Recently, experiments utilizing Fourier-space spectroscopy have shown that the exciton (exciton-polariton) dispersion can indeed be measured for high-quality hexagonal-BN-encapsulated WSe2 monolayer samples and can confirm the energy scale. Here, the exciton fine-structure's pseudo-spin and the valley polarization are investigated as a function of the centre-of-mass-momentum and excitation-laser detuning. For quasi-resonant excitation, a strong dispersion featuring a pronounced momentum-dependent helicity is observed. By increasing the excitation energy step-wise towards and then above the electronic band gap, the dispersion and the helicity systematically decrease due to contributions of incoherent excitons and emission from plasma. The decline of the helicity with centre-of-mass momentum can be phenomenologically modelled by the Maialle-Silva-Sham mechanism using the exciton splitting as the source of an effective magnetic field.

Published
2020

24. Epitaxial metals for interconnects beyond Cu

Author

Barmak, Katayun, Ezzat, Sameer, Gusle, Ryan, Jog, Atharv, Kerdsongpanya, Sit, Khanya, Asim, Milosevic, Erik, Richardson, William, Sentosun, Kadir, Zangiabadi, Amirali, Gall, Daniel, Kaden, William E., Mucciolo, Eduardo R., Schelling, Patrick K., West, Alan C., and Coffey, Kevin R.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The experimentally measured resistivity of Co(0001) and Ru(0001) single crystal thin films, grown on c-plane sapphire substrates, as a function of thickness is modeled using the semiclassical model of Fuchs-Sondheimer. The model fits show that the resistivity of Ru would cross below that for Co at a thickness of approximately 20 nm. For Ru films with thicknesses above 20 nm, transmission electron microscopy evidences threading and misfit dislocations, stacking faults and deformation twins. Exposure of Co films to ambient air, and the deposition of oxide layers of SiO2, MgO, Al2O3 and Cr2O3 on Ru degrade the surface specularity of the metallic layer. However, for the Ru films, annealing in a reducing ambient restores the surface specularity. Epitaxial electrochemical deposition of Co on epitaxially-deposited Ru layers is used as an example to demonstrate the feasibility of generating epitaxial interconnects for back-end of line structures. An electron transport model based on a tight-binding approach is described, with Ru interconnects used an example. The model allows conductivity to be computed for structures comprising large ensembles of atoms (10^5-10^6), scales linearly with system size and can also incorporate defects., Comment: 37 pages, 10 figures, to appear in the Journal of Vacuum Science & Technology A

Published
2020
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25. Diffusivity Reveals Three Distinct Phases of Interlayer Excitons in MoSe2/WSe2 Heterobilayers

Author

Wang, Jue, Shi, Qianhui, Shih, En-Min, Zhou, Lin, Wu, Wenjing, Bai, Yusong, Rhodes, Daniel A., Barmak, Katayun, Hone, James, Dean, Cory R., and Zhu, X. -Y.

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

Charge separated interlayer excitons in transition metal dichalcogenide (TMDC) heterobilayers are being explored for moir\'e exciton lattices and exciton condensates. The presence of permanent dipole moments and the poorly screened Coulomb interaction make many body interactions particularly strong for interlayer excitons. Here we reveal two distinct phase transitions for interlayer excitons in the MoSe2/WSe2 heterobilayer using time and spatially resolved photoluminescence imaging: from trapped excitons in the moir\'e-potential to the modestly mobile exciton gas as exciton density increases to ne/h ~ 1011 cm-2 and from the exciton gas to the highly mobile charge separated electron/hole plasma for ne/h > 1012 cm-2. The latter is the Mott transition and is confirmed in photoconductivity measurements. These findings set fundamental limits for achieving quantum states of interlayer excitons., Comment: 11 pages, 4 figures, and SI with 14 figures

Published
2020
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26. Direct Measurement of the Radiative Pattern of Bright and Dark Excitons and Exciton Complexes in Encapsulated Tungsten Diselenide

Author

Schneider, Lorenz Maximilian, Esdaille, Shanece, Rhodes, Daniel, Barmak, Katayun, Hone, James, and Rahimi-Iman, Arash

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

The optical properties of particularly the tungsten-based transition-metal dichalcogenides are strongly influenced by the presence of dark excitons. Recently, theoretical predictions as well as indirect experimental insights have shown that two different dark excitons exist within the light cone. While one is completely dark, the other one is only dipole forbidden out-of-plane, hence referred to as grey exciton. Here, we present angle-resolved spectroscopic data of a high-quality hexagonal-BN-encapsulated WSe2 monolayer with which we directly obtain the radiation pattern of this grey exciton that deviates from that of the bright exciton and other exciton complexes obtained at cryogenic temperatures.

Published
2019

27. WSe2/WS2 moir\'e superlattices: a new Hubbard model simulator

Author

Tang, Yanhao, Li, Lizhong, Li, Tingxin, Xu, Yang, Liu, Song, Barmak, Katayun, Watanabe, Kenji, Taniguchi, Takashi, MacDonald, Allan H, Shan, Jie, and Mak, Kin Fai

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

The Hubbard model, first formulated by physicist John Hubbard in the 1960s, is a simple theoretical model of interacting quantum particles in a lattice. The model is thought to capture the essential physics of high-temperature superconductors, magnetic insulators, and other complex emergent quantum many-body ground states. Although the Hubbard model is greatly simplified as a representation of most real materials, it has nevertheless proved difficult to solve accurately except in the one-dimensional case. Physical realization of the Hubbard model in two or three dimensions, which can act as quantum simulators, therefore have a vital role to play in solving the strong-correlation puzzle. Here we obtain a quantum phase diagram of the two-dimensional triangular lattice Hubbard model by studying angle-aligned WSe2/WS2 bilayers, which form moir\'e superlattices because of the difference in lattice constant between the two two-dimensional materials. We probe both charge and magnetic properties of the system by measuring the dependence of optical response on out-of-plane magnetic field, and on gate-tuned carrier density. At half filling of the first hole moir\'e superlattice band, we observe a Mott insulating state with antiferromagnetic Curie-Weiss behavior as expected for a Hubbard model in the strong interaction regime. Past half filling, our experiment suggests an antiferromagnetic to paramagnetic quantum phase transition near 0.6 filling. Our results establish a new solid-state platform based on moir\'e superlattices which can be used to simulate outstanding problems in strong correlation physics that are manifested by triangular lattice Hubbard models.

Published
2019

28. Enhanced Superconductivity in Monolayer $T_d$-MoTe$_2$ with Tilted Ising Spin Texture

Author

Rhodes, Daniel, Yuan, Noah F., Jung, Younghun, Antony, Abhinandan, Wang, Hua, Kim, Bumho, Chiu, Yu-che, Taniguchi, Takashi, Watanabe, Kenji, Barmak, Katayun, Balicas, Luis, Dean, Cory R., Qian, Xiaofeng, Fu, Liang, Pasupathy, Abhay N., and Hone, James

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Crystalline two-dimensional (2D) superconductors with low carrier density are an exciting new class of materials in which superconductivity coexists with strong interactions, the effects of complex topology are not obscured by disorder, and electronic properties can be strongly tuned by electrostatic gating. Very recently, two such materials, 'magic-angle' twisted bilayer graphene and monolayer $T_d$-WTe$_2$, have been reported to show superconductivity at temperatures near 1 K. Here we report superconductivity in semimetallic monolayer $T_d$-MoTe$_2$. The critical temperature $T_\textrm{c}$ reaches 8 K, a sixty-fold enhancement as compared to the bulk. This anomalous increase in $T_\textrm{c}$ is only observed in monolayers, and may be indicative of electronically mediated pairing. Reflecting the low carrier density, the critical temperature, magnetic field, and current density are all tunable by an applied gate voltage, revealing a superconducting dome that extends across both hole and electron pockets. The temperature dependence of the in-plane upper critical field is distinct from that of $2H$ transition metal dichalcogenides (TMDs), consistent with a tilted spin texture as predicted by \textit{ab initio} theory.

Published
2019

29. Shedding light on the monolayer-WSe2 exciton's nature by optical effective-mass measurements

Author

Schneider, Lorenz Maximilian, Esdaille, Shanece, Rhodes, Daniel, Barmak, Katayun, Hone, James, and Rahimi-Iman, Arash

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

Two-dimensional excitons formed in quantum materials such as monolayer transition-metal dichalcogenides and their strong light-matter interaction have attracted unrivalled attention by the research community due to their extraordinarily large oscillator strength as well as binding energy, and the inherent spin-valley locking. Semiconducting few-layer and monolayer materials with their sharp optical resonances such as WSe2 have been extensively studied and envisioned for applications in the weak as well as strong light-matter coupling regimes, for effective nano-laser operation with various different structures, and particularly for valleytronic nanophotonics motivated by the circular dichroism. Many of these applications, which may benefit heavily from the two-dimensional electronic quasiparticle's properties in such films, require controlling, manipulating and first of all understanding the nature of the optical resonances that are attributed to exciton modes. While theory and previous experiments have provided unique methods to the characterization and classification efforts regarding the band structure and optical modes in 2D materials, here, we directly measure the quasiparticle energy-momentum dispersion for the first time. Our results for single-layer WSe2 clearly indicate an emission regime predominantly governed by free excitons, i.e. Coulomb-bound electron-hole pairs with centre-of-mass momentum and corresponding effective mass. Besides uniquely evidencing the existence of free excitons at cryogenic temperatures optically, the fading of the dispersive character for increased temperatures or excitation densities reveals a transition to a regime with profound role of charge-carrier plasma or localized excitons regarding its emission, debunking the myth of free-exciton emission at elevated temperatures.

Published
2018

34. Statistics of grain growth: experiment versus the Phase-Field-Crystal and Mullins models

Author

La Boissoniere, Gabriel Martine, Choksi, Rustum, Barmak, Katayun, and Esedoglu, Selim

Subjects
Condensed Matter - Materials Science
Abstract

We present a detailed comparison of multiple statistical grain metrics for previously reported experimental thin film samples of aluminum with 2D simulations obtained from the Phase-Field-Crystal (PFC) model and a Mullins grain boundary motion model. For all these results, ``universality'' is observed with respect to the dynamics and initial conditions. This comparison reveals that PFC reproduces geometric metrics such as area and perimeter, but does not capture grain shape and topology as accurately. Similarly, the Mullins model captures the number of sides distribution quite well but not other metrics. Our collective comparison of such measurements underscores the critical importance of the use of multiple metrics for comparison of experiments with all present and future models of grain growth in polycrystalline materials., Comment: 17 pages, 6 figures

Published
2018
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35. Scalable, 'Dip-and-dry' Fabrication of a Wide-Angle Plasmonic Selective Absorber for High-efficiency Solar-Thermal Energy Conversion

Author

Mandal, Jyotirmoy, Wang, Derek, Overvig, Adam C., Shi, Norman N., Paley, Daniel, Zangiabadi, Amirali, Cheng, Qian, Barmak, Katayun, Yu, Nanfang, and Yang, Yuan

Subjects
Physics - Applied Physics
Abstract

A galvanic displacement reaction-based, room-temperature "dip-and-dry" technique is demonstrated for fabricating selectively solar-absorbing plasmonic nanostructure-coated foils (PNFs). The technique, which allows for facile tuning of the PNFs' spectral reflectance to suit different radiative and thermal environments, yields PNFs which exhibit excellent, wide-angle solar absorptance (0.96 at 15{\deg}, to 0.97 at 35{\deg}, to 0.79 at 80{\deg}) and low hemispherical thermal emittance (0.10) without the aid of antireflection coatings. The thermal emittance is on par with those of notable selective solar absorbers (SSAs) in the literature, while the wide-angle solar absorptance surpasses those of previously reported SSAs with comparable optical selectivities. In addition, the PNFs show promising mechanical and thermal stabilities at temperatures of up to 200{\deg}C. Along with the performance of the PNFs, the simplicity, inexpensiveness and environment-friendliness of the "dip-and-dry" technique makes it an appealing alternative to current methods for fabricating selective solar absorbers.

Published
2018
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36. Via Method for Lithography Free Contact and Preservation of 2D Materials

Author

Telford, Evan J., Benyamini, Avishai, Rhodes, Daniel, Wang, Da, Jung, Younghun, Zangiabadi, Amirali, Watanabe, Kenji, Taniguchi, Takashi, Jia, Shuang, Barmak, Katayun, Pasupathy, Abhay N., Dean, Cory R., and Hone, James

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

Atomically thin 2D materials span the common components of electronic circuits as metals, semi-conductors, and insulators, and can manifest correlated phases such as superconductivity, charge density waves, and magnetism. An ongoing challenge in the field is to incorporate these 2D materials into multi-layer hetero-structures with robust electrical contacts while preventing disorder and degradation. In particular, preserving and studying air-sensitive 2D materials has presented a significant challenge since they readily oxidize under atmospheric conditions. We report a new technique for contacting 2D materials, in which metal via contacts are integrated into flakes of insulating hexagonal boron nitride, and then placed onto the desired conducting 2D layer, avoiding direct lithographic patterning onto the 2D conductor. The metal contacts are planar with the bottom surface of the boron nitride and form robust contacts to multiple 2D materials. These structures protect air-sensitive 2D materials for months with no degradation in performance. This via contact technique will provide the capability to produce atomic printed circuit boards that can form the basis of more complex multi-layer heterostructures., Comment: 16 pages, 4 figures

Published
2018
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37. Structure of the moiré exciton captured by imaging its electron and hole

Author

Karni, Ouri, Barré, Elyse, Pareek, Vivek, Georgaras, Johnathan D., Man, Michael K. L., Sahoo, Chakradhar, Bacon, David R., Zhu, Xing, Ribeiro, Henrique B., O’Beirne, Aidan L., Hu, Jenny, Al-Mahboob, Abdullah, Abdelrasoul, Mohamed M. M., Chan, Nicholas S., Karmakar, Arka, Winchester, Andrew J., Kim, Bumho, Watanabe, Kenji, Taniguchi, Takashi, Barmak, Katayun, Madéo, Julien, da Jornada, Felipe H., Heinz, Tony F., and Dani, Keshav M.

Published
2022
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38. Determining the density and spatial descriptors of atomic scale defects of 2H–WSe2 with ensemble deep learning.

Author

Smalley, Darian, Lough, Stephanie D., Holtzman, Luke N., Holbrook, Madisen, Hone, James C., Barmak, Katayun, and Ishigami, Masahiro

Subjects
TRANSITION metals, DEUTERIUM, CRYSTAL structure, DEEP learning, SCANNING tunneling microscopy, CONVOLUTIONAL neural networks
Abstract

We have demonstrated atomic-scale defect characterization in scanning tunneling microscopy images of single crystal tungsten diselenide using an ensemble of U-Net-like convolutional neural networks. Coordinates, counts, densities, and spatial extents were determined from almost 16 000 defect detections, leading to the rapid identification of defect types and their densities. Our results show that analysis aided by machine learning can be used to rapidly determine the quality of transition metal dichalcogenides and provide much needed quantitative input, which may improve the synthesis process. [ABSTRACT FROM AUTHOR]

Published
2024
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41. Simulation of Hubbard model physics in WSe.sub.2/WS.sub.2 moire superlattices

Author

Tang, Yanhao, Li, Lizhong, Li, Tingxin, Xu, Yang, Liu, Song, Barmak, Katayun, and Watanabe, Kenji

Subjects
Tungsten compounds -- Atomic properties -- Chemical properties, Chemical models -- Usage, Superlattices as materials -- Models, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

The Hubbard model, formulated by physicist John Hubbard in the 1960s.sup.1, is a simple theoretical model of interacting quantum particles in a lattice. The model is thought to capture the essential physics of high-temperature superconductors, magnetic insulators and other complex quantum many-body ground states.sup.2,3. Although the Hubbard model provides a greatly simplified representation of most real materials, it is nevertheless difficult to solve accurately except in the one-dimensional case.sup.2,3. Therefore, the physical realization of the Hubbard model in two or three dimensions, which can act as an analogue quantum simulator (that is, it can mimic the model and simulate its phase diagram and dynamics.sup.4,5), has a vital role in solving the strong-correlation puzzle, namely, revealing the physics of a large number of strongly interacting quantum particles. Here we obtain the phase diagram of the two-dimensional triangular-lattice Hubbard model by studying angle-aligned WSe.sub.2/WS.sub.2 bilayers, which form moiré superlattices.sup.6 because of the difference between the lattice constants of the two materials. We probe the charge and magnetic properties of the system by measuring the dependence of its optical response on an out-of-plane magnetic field and on the gate-tuned carrier density. At half-filling of the first hole moiré superlattice band, we observe a Mott insulating state with antiferromagnetic Curie-Weiss behaviour, as expected for a Hubbard model in the strong-interaction regime.sup.2,3,7-9. Above half-filling, our experiment suggests a possible quantum phase transition from an antiferromagnetic to a weak ferromagnetic state at filling factors near 0.6. Our results establish a new solid-state platform based on moiré superlattices that can be used to simulate problems in strong-correlation physics that are described by triangular-lattice Hubbard models. Study of WSe.sub.2/WS.sub.2 moiré superlattices reveals the phase diagram of the triangular-lattice Hubbard model, including a Mott insulating state at half-filling and a possible magnetic quantum phase transition near 0.6 filling., Author(s): Yanhao Tang [sup.1] , Lizhong Li [sup.1] , Tingxin Li [sup.1] , Yang Xu [sup.1] , Song Liu [sup.2] , Katayun Barmak [sup.3] , Kenji Watanabe [sup.4] , Takashi [...]

Published
2020
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42. Grain growth beyond the Mullins model, capturing the complex physics behind universal grain size distributions

Author

Backofen, Rainer, Barmak, Katayun, Elder, Ken, and Voigt, Axel

Subjects
Condensed Matter - Materials Science
Abstract

Grain growth experiments on thin metallic films have shown the geometric and topological characteristics of the grain structure to be universal and independent of many experimental conditions. The universal size distribution, however, is found to differ both qualitatively and quantitatively from the standard Mullins curvature driven model of grain growth; with the experiments exhibiting an excess of small grains (termed an "ear") and an excess of very large grains (termed a "tail") compared with the model. While a plethora of extensions of the Mullins model have been proposed to explain these characteristics, none have been successful. In this work, large scale simulations of a model that resolves the atomic scale on diffusive time scales, the phase field crystal model, is used to examine the complex phenomena of grain growth. The results are in remarkable agreement with the experimental results, recovering the characteristic "ear" and "tail" features of the experimental grain size distribution. The simulations also indicate that while the geometric and topological characteristics are universal, the dynamic growth exponent is not., Comment: 4 pages, 5 figures

Published
2013
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49. Two-Step Flux Synthesis of Ultrapure Transition-Metal Dichalcogenides

Author

Liu, Song, primary, Liu, Yang, additional, Holtzman, Luke, additional, Li, Baichang, additional, Holbrook, Madisen, additional, Pack, Jordan, additional, Taniguchi, Takashi, additional, Watanabe, Kenji, additional, Dean, Cory R., additional, Pasupathy, Abhay N., additional, Barmak, Katayun, additional, Rhodes, Daniel A., additional, and Hone, James, additional

Published
2023
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