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1. Specifics of the Elemental Excitations in 'True One-Dimensional' MoI$_3$ van der Waals Nanowires

Author

Kargar, Fariborz, Barani, Zahra, Sesing, Nicholas R., Mai, Thuc T., Debnath, Topojit, Zhang, Huairuo, Liu, Yuhang, Zhu, Yanbing, Ghosh, Subhajit, Biacchi, Adam J., da Jornada, Felipe H., Bartels, Ludwig, Adel, Tehseen, Walker, Angela R. Hight, Davydov, Albert V., Salguero, Tina T., Lake, Roger K., and Balandin, Alexander A.

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

We report on the temperature evolution of the polarization-dependent Raman spectrum of exfoliated MoI$_3$, a van der Waals material with a "true one-dimensional" crystal structure that can be exfoliated to individual atomic chains. The temperature evolution of several Raman features reveals anomalous behavior suggesting a phase transition of a magnetic origin. Theoretical considerations indicate that MoI$_3$ is an easy-plane antiferromagnet with alternating spins along the dimerized chains and with inter-chain helical spin ordering. The calculated frequencies of the phonons and magnons are consistent with the interpretation of the experimental Raman data. The obtained results shed light on the specifics of the phononic and magnonic states in MoI$_3$ and provide a strong motivation for future study of this unique material with potential for spintronic device applications., Comment: 28 pages

Published
2022
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2. Metallic vs. Semiconducting Properties of Quasi-One-Dimensional Tantalum Selenide van der Waals Nanoribbons

Author

Kargar, Fariborz, Krayev, Andrey, Wurch, Michelle, Ghafouri, Yassamin, Debnath, Topojit, Wickramaratne, Darshana, Salguero, Tina T., Lake, Roger, Bartels, Ludwig, and Balandin, Alexander A.

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

We conducted a tip-enhanced Raman scattering spectroscopy (TERS) and photoluminescence (PL) study of quasi-1D TaSe3 nanoribbons exfoliated onto gold substrates. At a selenium deficiency of ~0.25 (Se/Ta=2.75,), the nanoribbons exhibit a strong, broad PL peak centered around ~920 nm (1.35 eV), suggesting their semiconducting behavior. Such nanoribbons revealed a strong TERS response under 785-nm laser excitation, allowing for their nanoscale spectroscopic imaging. Nanoribbons with a smaller selenium deficiency of ~0.15 (Se/Ta=2.85) did not show any PL or TERS response. The confocal Raman spectra of these samples agree with the previously-reported spectra of metallic TaSe3. The differences in the optical response of the nanoribbons examined in this study suggest that even small variations in Se content can induce changes in electronic structure, causing samples to exhibit either metallic or semiconducting character. The temperature-dependent electrical measurements of devices fabricated with both types of materials corroborate these observations. The density-functional-theory calculations revealed that incorporation of an oxygen atom in a Se vacancy can result in band gap opening and thus enable the transition from a metal to a semiconductor. However, the predicted bandgap is substantially smaller than that derived from PL data. These results indicate that the properties of van der Waals materials can vary significantly depending on stoichiometry, defect types and concentration, and possibly environmental and substrate effects. In view of this finding, local probing of nanoribbon properties with TERS becomes essential to understanding such low-dimensional systems., Comment: 24 pages, 8 figures

Published
2021

3. Valley lifetimes of conduction band electrons in monolayer WSe$_2$

Author

Ersfeld, Manfred, Volmer, Frank, Rathmann, Lars, Kotewitz, Luca, Heithoff, Maximilian, Lohmann, Mark, Yang, Bowen, Watanabe, Kenji, Taniguchi, Takashi, Bartels, Ludwig, Shi, Jing, Stampfer, Christoph, and Beschoten, Bernd

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

One of the main tasks in the investigation of 2-dimensional transition metal dichalcogenides is the determination of valley lifetimes. In this work, we combine time-resolved Kerr rotation with electrical transport measurements to explore the gate-dependent valley lifetimes of free conduction band electrons of monolayer WSe$_2$. When tuning the Fermi energy into the conduction band we observe a strong decrease of the respective valley lifetimes which is consistent with both spin-orbit and electron-phonon scattering. We explain the formation of a valley polarization by the scattering of optically excited valley polarized bright trions into dark states by intervalley scattering. Furthermore, we show that the conventional time-resolved Kerr rotation measurement scheme has to be modified to account for photo-induced gate screening effects. Disregarding this adaptation can lead to erroneous conclusions drawn from gate-dependent optical measurements and can completely mask the true gate-dependent valley dynamics., Comment: 5 pages, 3 figures

Published
2020
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4. Unveiling valley lifetimes of free charge carriers in monolayer WSe$_2$

Author

Ersfeld, Manfred, Volmer, Frank, Rathmann, Lars, Kotewitz, Luca, Heithoff, Maximilian, Lohmann, Mark, Yang, Bowen, Watanabe, Kenji, Taniguchi, Takashi, Bartels, Ludwig, Shi, Jing, Stampfer, Christoph, and Beschoten, Bernd

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

We report on nanosecond long, gate-dependent valley lifetimes of free charge carriers in monolayer WSe$_2$, unambiguously identified by the combination of time-resolved Kerr rotation and electrical transport measurements. While the valley polarization increases when tuning the Fermi level into the conduction or valence band, there is a strong decrease of the respective valley lifetime consistent with both electron-phonon and spin-orbit scattering. The longest lifetimes are seen for spin-polarized bound excitons in the band gap region. We explain our findings via two distinct, Fermi level-dependent scattering channels of optically excited, valley polarized bright trions either via dark or bound states. By electrostatic gating we demonstrate that the transition metal dichalcogenide WSe$_2$ can be tuned to be either an ideal host for long-lived localized spin states or allow for nanosecond valley lifetimes of free charge carriers (> 10 ns)., Comment: 22 pages, 13 figures

Published
2019
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5. Low Resistivity and High Breakdown Current Density of 10-nm Diameter van der Waals TaSe3 Nanowires by Chemical Vapor Deposition

Author

Empante, Thomas A., Martinez, Aimee, Wurch, Michelle, Zhu, Yanbing, Geremew, Adane K., Yamaguchi, Koichi, Isarraraz, Miguel, Rumyantsev, Sergey, Reed, Evan J., Balandin, Alexander A., and Bartels, Ludwig

Subjects
Condensed Matter - Materials Science
Abstract

Micron-scale single-crystal nanowires of metallic TaSe3, a material that forms -Ta-Se3-Ta-Se3- stacks separated from one another by a tubular van der Waals (vdW) gap, have been synthesized using chemical vapor deposition (CVD) on a SiO2/Si substrate, in a process compatible with semiconductor industry requirements. Their electrical resistivity was found unaffected by downscaling from the bulk to as little as 7 nm in width and height, in striking contrast to the resistivity of copper for the same dimensions. While the bulk resistivity of TaSe3 is substantially higher than that of bulk copper, at the nanometer scale the TaSe3 wires become competitive to similar-sized copper ones. Moreover, we find that the vdW TaSe3 nanowires sustain current densities in excess of 108 A/cm2 and feature an electromigration energy barrier twice that of copper. The results highlight the promise of quasi-one-dimensional transition metal trichalcogenides for electronic interconnect applications and the potential of van der Waals materials for downscaled electronics.

Published
2019
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6. How Photoinduced Gate Screening and Leakage Currents Dynamically Change the Fermi Level in 2D Materials

Author

Volmer, Frank, Ersfeld, Manfred, Rathmann, Lars, Heithoff, Maximilian, Kotewitz, Luca, Lohmann, Mark, Yang, Bowen, Watanabe, Kenji, Taniguchi, Takashi, Bartels, Ludwig, Shi, Jing, Stampfer, Christoph, and Beschoten, Bernd

Subjects
electrical transport, gate screening, monolayers, photoluminescence, transition metal dichalcogenides, Condensed Matter Physics, Materials Engineering, Nanotechnology, Applied Physics
Published
2020

8. A semi-empirical integrated microring cavity approach for 2D material optical index identification at 1.55 {\mu}m

Author

Maiti, Rishi, Hemnani, Rohit A., Amin, Rubab, Ma, Zhizhen, Tahersima, Mohammad H., Empante, Tom A., Dalir, Hamed, Agarwal, Ritesh, Bartels, Ludwig, and Sorger, Volker J.

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

Atomically thin two-dimensional (2D) materials provide a wide range of basic building blocks with unique properties, making them ideal for heterogeneous integration with a mature chip platform for advances in optical communication technology. Control and understanding of the precise value of the optical index of these materials, however, is challenging, due to the small lateral flake dimension. Here we demonstrate a semi-empirical method to determine the index of a 2D material (nMoTe2 of 4.36+0.011i) near telecommunication-relevant wavelength by integrating few layers of MoTe2 onto a micro-ring resonator. The placement, control, and optical-property understanding of 2D materials with integrated photonics paves a way for further studies of active 2D material-based optoelectronics and circuits., Comment: arXiv admin note: substantial text overlap with arXiv:1807.03945

Published
2018

9. Loss and Coupling Tuning via Heterogeneous Integration of MoS2 Layers in Silicon Photonics

Author

Maiti, Rishi, Patil, Chandraman, Hemnani, Rohit, Miscuglio, Mario, Amin, Rubab, Ma, Zhizhen, Chaudhary, Rimjhim, Johnson, Charlie, Bartels, Ludwig, Agarwal, Ritesh, and Sorger, Volker J.

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Layered two-dimensional (2D) materials provide a wide range of unique properties as compared to their bulk counterpart, making them ideal for heterogeneous integration for on-chip interconnects. Hence, a detailed understanding of the loss and index change on Si integrated platform is a prerequisite for advances in opto-electronic devices impacting optical communication technology, signal processing, and possibly photonic-based computing. Here, we present an experimental guide to characterize transition metal dichalcogenides (TMDs), once monolithically integrated into the Silicon photonic platform at 1.55 um wavelength. We describe the passive tunable coupling effect of the resonator in terms of loss induced as a function of 2D material layer coverage length and thickness. Further, we demonstrate a TMD-ring based hybrid platform as a refractive index sensor where resonance shift has been mapped out as a function of flakes thickness which correlates well with our simulated data. These experimental findings on passive TMD-Si hybrid platform open up a new dimension by controlling the effective change in loss and index, which may lead to the potential application of 2D material based active on chip photonics.

Published
2018

10. Microring Resonators Coupling Tunability by Heterogeneous 2D Material Integration

Author

Maiti, Rishi, Hemnani, Rohit, Amin, Rubab, Ma, Zhizhen, Tahersima, Mohammad, Empante, Thomas A., Dalir, Hamed, Agarwal, Ritesh, Bartels, Ludwig, and Sorger, Volker J.

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Atomically thin 2D materials provide a wide range of basic building blocks with unique properties, making them ideal for heterogeneous integration with a mature chip platform. An understanding the role of excitons in transition metal dichalcogenides in Silicon photonic platform is a prerequisite for advances in optical communication technology, signal processing, and possibly computing. Here we demonstrate passive tunable coupling by integrating few layers of MoTe2 on a micro-ring resonator. We find a TMD-to-rings circumference coverage length ratio to place the ring into critical coupling to be about 10% as determined from the variation of spectral resonance visibility and loss as a function of TMD coverage. Using this TMD ring heterostructure, we further demonstrate a semi-empirical method to determine the index of an unknown TMD material (nMoTe2 of 4.36+.011i) near for telecommunication-relevant wavelength.

Published
2018

11. Effect of distance on photoluminescence quenching and proximity-induced spin-orbit coupling in graphene-WSe2 heterostructures

Author

Yang, Bowen, Molina, Everardo, Kim, Jeongwoo, Barroso, David, Lohmann, Mark, Liu, Yawen, Xu, Yadong, Wu, Ruqian, Bartels, Ludwig, Watanabe, Kenji, Taniguchi, Takashi, and Shi, Jing

Subjects
Condensed Matter - Materials Science
Abstract

Spin-orbit coupling (SOC) in graphene can be greatly enhanced by proximity coupling it to transition metal dichalcogenides (TMDs) such as WSe2. We find that the strength of the acquired SOC in graphene depends on the stacking order of the heterostructures when using hexagonal boron nitride (h-BN) as the capping layer, i.e., SiO2/graphene/WSe2/h-BN exhibiting stronger SOC than SiO2/WSe2/graphene/h-BN. We utilize photoluminescence (PL) as an indicator to characterize the interaction between graphene and monolayer WSe2 grown by chemical vapor deposition. We observe much stronger PL quenching in the SiO2/graphene/WSe2/h-BN stack than in the SiO2/WSe2/graphene/h-BN stack, and correspondingly a much larger weak antilocalization (WAL) effect or stronger induced SOC in the former than in the latter. We attribute these two effects to the interlayer distance between graphene and WSe2, which depends on whether graphene is in immediate contact with h-BN. Our observations and hypothesis are further supported by first-principles calculations which reveal a clear difference in the interlayer distance between graphene and WSe2 in these two stacks.

Published
2018
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12. Towards a 2D Printer: A Deterministic Cross Contamination-free Transfer Method for Atomically Layered Materials

Author

Hemnani, Rohit A., Carfano, Caitlin, Tischler, Jason P., Tahersima, Mohammad H., Maiti, Rishi, Bartels, Ludwig, Agarwal, Ritesh, and Sorger, Volker J.

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

Precision and chip contamination-free placement of two-dimensional (2D) materials is expected to accelerate both the study of fundamental properties and novel device functionality. Current transfer methods of 2D materials onto an arbitrary substrate deploy wet chemistry and viscoelastic stamping. However, these methods produce a) significant cross contamination of the substrate due to the lack of spatial selectivity b) may not be compatible with chemically sensitive device structures, and c) are challenged with respect to spatial alignment. Here, we demonstrate a novel method of transferring 2D materials resembling the functionality known from printing; utilizing a combination of a sharp micro-stamper and viscoelastic polymer, we show precise placement of individual 2D materials resulting in vanishing cross contamination to the substrate. Our 2D printer-method results show an aerial cross contamination improvement of two to three orders of magnitude relative to state-of-the-art dry and direct transfer methods. Moreover, we find that the 2D material quality is preserved in this transfer method. Testing this 2D material printer on taped-out integrated Silicon photonic chips, we find that the micro-stamper stamping transfer does not physically harm the underneath Silicon nanophotonic structures such as waveguides or micro-ring resonators receiving the 2D material. Such accurate and substrate-benign transfer method for 2D materials could be industrialized for rapid device prototyping due to its high time-reduction, accuracy, and contamination-free process.

Published
2018

13. 2D Materials in Electro-optic Modulation: energy efficiency, electrostatics, mode overlap, material transfer and integration

Author

Ma, Zhizhen, Hemnani, Rohit, Bartels, Ludwig, Agarwal, Ritesh, and Sorger, Volker J.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Here we discuss the physics of electro-optic modulators deploying 2D materials. We include a scaling laws analysis showing how energy-efficiency and speed change for three underlying cavity systems as a function of critical device length scaling. A key result is that the energy-per-bit of the modulator is proportional to the volume of the device, thus making the case for submicron-scale modulators possible deploying a plasmonic optical mode. We then show how Graphenes Pauli-blocking modulation mechanism is sensitive to the device operation temperature, whereby a reduction of the temperature enables a 10x reduction in modulator energy efficiency. Furthermore, we show how the high index tunability of Graphene is able to compensate for the small optical overlap factor of 2D-based material modulators, which is unlike classical Silicon-based dispersion devices. Lastly we demonstrate a novel method towards a 2D material printer suitable for cross-contamination free and on-demand printing. The latter paves the way to integrate 2D materials seamlessly into taped-out photonic chips.

Published
2017
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14. Strong electron-hole symmetric Rashba spin-orbit coupling in graphene/monolayer transition metal dichalcogenide heterostructures

Author

Yang, Bowen, Lohmann, Mark, Barroso, David, Liao, Ingrid, Lin, Zhisheng, Liu, Yawen, Bartels, Ludwig, Watanabe, Kenji, Taniguchi, Takashi, and Shi, Jing

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

Despite its extremely weak intrinsic spin-orbit coupling (SOC), graphene has been shown to acquire considerable SOC by proximity coupling with exfoliated transition metal dichalcogenides (TMDs). Here we demonstrate strong induced Rashba SOC in graphene that is proximity coupled to a monolayer TMD film, MoS2 or WSe2, grown by chemical vapor deposition with drastically different Fermi level positions. Graphene/TMD heterostructures are fabricated with a pickup-transfer technique utilizing hexagonal boron nitride, which serves as a flat template to promote intimate contact and therefore a strong interfacial interaction between TMD and graphene as evidenced by quenching of the TMD photoluminescence. We observe strong induced graphene SOC that manifests itself in a pronounced weak anti-localization (WAL) effect in the graphene magnetoconductance. The spin relaxation rate extracted from the WAL analysis varies linearly with the momentum scattering time and is independent of the carrier type. This indicates a dominantly Dyakonov-Perel spin relaxation mechanism caused by the induced Rashba SOC. Our analysis yields a Rashba SOC energy of ~1.5 meV in graphene/WSe2 and ~0.9 meV in graphene/MoS2, respectively. The nearly electron-hole symmetric nature of the induced Rashba SOC provides a clue to possible underlying SOC mechanisms.

Published
2017
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15. Scalable Transfer-Free Fabrication of MoS$_2$/SiO$_2$ Hybrid Nanophotonic Cavity Arrays with Quality Factors Exceeding 4000

Author

Hammer, Sebastian, Mangold, Hans-Moritz, Nguyen, Ariana E., Martinez-Ta, Dominic, Alvillar, Sahar Naghibi, Bartels, Ludwig, and Krenner, Hubert J.

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

We report the fully-scalable fabrication of a large array of hybrid molybdenum disulfide (MoS$_2$) - silicon dioxide (SiO$_2$) one-dimensional, free-standing photonic-crystal cavities capable of enhancement of the MoS$_2$ photoluminescence at the narrow cavity resonance. We demonstrate continuous tunability of the cavity resonance wavelength across the entire emission band of MoS$_2$ simply by variation of the photonic crystal periodicity. Device fabrication started by substrate-scale growth of MoS$_2$ using chemical vapor deposition (CVD) on non-birefringent thermal oxide on a silicon wafer; it was followed by lithographic fabrication of a photon crystal nanocavity array on the same substrate at more than 50% yield of functional devices. Our cavities exhibit three dominant modes with measured linewidths less than 0.2 nm, corresponding to quality factors exceeding 4000. All experimental findings are found to be in excellent agreement with finite difference time domain simulations., Comment: accepted for Scientific Reports (2017)

Published
2017
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16. Effect of Distance on Photoluminescence Quenching and Proximity-Induced Spin–Orbit Coupling in Graphene/WSe2 Heterostructures

Author

Yang, Bowen, Molina, Everardo, Kim, Jeongwoo, Barroso, David, Lohmann, Mark, Liu, Yawen, Xu, Yadong, Wu, Ruqian, Bartels, Ludwig, Watanabe, Kenji, Taniguchi, Takashi, and Shi, Jing

Subjects
Graphene, transition metal dichalcogenides, proximity effect, photoluminescence, spin-orbit coupling, interlayer distance, spin−orbit coupling, cond-mat.mtrl-sci, Nanoscience & Nanotechnology
Abstract

Spin-orbit coupling (SOC) in graphene can be greatly enhanced by proximity coupling it to transition metal dichalcogenides (TMDs) such as WSe2. We find that the strength of the acquired SOC in graphene depends on the stacking order of the heterostructures when using hexagonal boron nitride ( h-BN) as the capping layer, i.e., SiO2/graphene/WSe2/ h-BN exhibiting stronger SOC than SiO2/WSe2/graphene/ h-BN. We utilize photoluminescence (PL) as an indicator to characterize the interaction between graphene and monolayer WSe2 grown by chemical vapor deposition. We observe much stronger PL quenching in the SiO2/graphene/WSe2/ h-BN stack than in the SiO2/WSe2/graphene/ h-BN stack and, correspondingly, a much larger weak antilocalization (WAL) effect or stronger induced SOC in the former than in the latter. We attribute these two effects to the interlayer distance between graphene and WSe2, which depends on whether graphene is in immediate contact with h-BN. Our observations and hypothesis are further supported by first-principles calculations, which reveal a clear difference in the interlayer distance between graphene and WSe2 in these two stacks.

Published
2018

17. Testbeds for Transition Metal Dichalcogenide Photonics: Efficacy of Light Emission Enhancement in Monomer vs. Dimer Nanoscale Antennae

Author

Tahersima, Mohammad H., Birowosuto, M. Danang, Ma, Zhizhen, Sarpkaya, Ibrahim, Coley, William C., Valentin, Michael D., Lu, I-Hsi, Liu, Ke, Zhou, Yao, Martinez, Aimee, Liao, Ingrid, Davis, Brandon N., Martinez, Joseph, Alvillar, Sahar Naghibi, Martinez-Ta, Dominic, Guan, Alison, Nguyen, Ariana E., Soci, Cesare, Reed, Evan, Bartels, Ludwig, and Sorger, Volker J.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Monolayer transition metal dichalcogenides are uniquely-qualified materials for photonics because they combine well defined tunable direct band gaps and selfpassivated surfaces without dangling bonds. However, the atomic thickness of these 2D materials results in low photo absorption limiting the achievable photo luminescence intensity. Such emission can, in principle, be enhanced via nanoscale antennae resulting in; a. an increased absorption cross-section enhancing pump efficiency, b. an acceleration of the internal emission rate via the Purcell factor mainly by reducing the antennas optical mode volume beyond the diffraction limit, and c. improved impedance matching of the emitter dipole to the freespace wavelength. Plasmonic dimer antennae show orders of magnitude hot-spot field enhancements when an emitter is positioned exactly at the midgap. However, a 2D material cannot be grown, or easily transferred, to reside in mid-gap of the metallic dimer cavity. In addition, a spacer layer between the cavity and the emissive material is required to avoid non-radiative recombination channels. Using both computational and experimental methods, in this work we show that the emission enhancement from a 2D emitter- monomer antenna cavity system rivals that of dimers at much reduced lithographic effort. We rationalize this finding by showing that the emission enhancement in dimer antennae does not specifically originate from the gap of the dimer cavity, but is an average effect originating from the effective cavity crosssection taken below each optical cavity where the emitting 2D film is located. In particular, we test an array of different dimer and monomer antenna geometries and observe a representative 3x higher emission for both monomer and dimer cavities as compared to intrinsic emission of Chemical Vapor Deposition synthesized WS2 flakes., Comment: 31 pages, 5 figures

Published
2017

18. Large-Scale Arrays of Single- and Few-Layer MoS2 Nanomechanical Resonators

Author

Jia, Hao, Yang, Rui, Nguyen, Ariana E., Alvillar, Sahar N., Empante, Thomas, Bartels, Ludwig, and Feng, Philip X. -L.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report on fabrication of large-scale arrays of suspended molybdenum disulfide (MoS2) atomic layers, as two-dimensional (2D) MoS2 nanomechanical resonators. We employ a water-assisted lift-off process to release chemical vapor deposited (CVD) MoS2 atomic layers from a donor substrate, followed by an all-dry transfer onto microtrench arrays. The resultant large arrays of suspended single- and few-layer MoS2 drumhead resonators (0.5 to 2um in diameter) offer fundamental resonances (f_0) in the very high frequency (VHF) band (up to ~120MHz) and excellent figures-of-merit up to f_0*Q ~ 3*10^10Hz. A stretched circular diaphragm model allows us to estimate low pre-tension levels of typically ~15mN/m in these devices. Compared to previous approaches, our transfer process features high yield and uniformity with minimal liquid and chemical exposure (only involving DI water), resulting in high-quality MoS2 crystals and exceptional device performance and homogeneity; and our process is readily applicable to other 2D materials., Comment: 14 pages, 6 figures

Published
2016
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19. A semi-empirical integrated microring cavity approach for 2D material optical index identification at 1.55 μm

Author

Maiti Rishi, Hemnani Rohit A., Amin Rubab, Ma Zhizhen, Tahersima Mohammad H., Empante Tom A., Dalir Hamed, Agarwal Ritesh, Bartels Ludwig, and Sorger Volker J.

Subjects
heterogeneous integration, 2D materials, TMDCs, microring resonator, 2D printer, coupling coefficients, Physics, QC1-999
Abstract

Atomically thin 2D materials such as transition metal dichalcogenides (TMDs) provide a wide range of basic building blocks with unique properties, making them ideal for heterogeneous integration with a mature chip platform for advances in optical communication technology. The control and understanding of the precise value of the optical index of these materials, however, is challenging, as the standard metrology techniques such as the millimeter-large ellipsometry is often not usable due the small lateral 2D material flake dimension. Here, we demonstrate an approach of passive tunable coupling by integrating few layers of MoTe2 onto a microring resonator connected to a waveguide bus. We find the TMD-to-ring circumference coverage length ratio required to precisely place the ring into a critical coupling condition to be about 10% as determined from the variation of spectral resonance visibility and loss as a function of TMD coverage. Using this TMD-ring heterostructure, we further demonstrate a semiempirical method to determine the index of a 2D material (nMoTe2 of 4.36+0.011i) near telecommunication-relevant wavelength. The placement, control, and optical property understanding of 2D materials with integrated photonics pave the way for further studies of active 2D material-based optoelectronics and circuits.

Published
2019
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22. Machine-Learning-Driven Expansion of the 1D van der Waals Materials Space

Author

Zhu, Yanbing, primary, Antoniuk, Evan R., additional, Wright, Dylan, additional, Kargar, Fariborz, additional, Sesing, Nicholas, additional, Sendek, Austin D., additional, Salguero, Tina T., additional, Bartels, Ludwig, additional, Balandin, Alexander A., additional, Reed, Evan J., additional, and da Jornada, Felipe H., additional

Published
2023
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23. Atoms-First Curriculum: A Comparison of Student Success in General Chemistry

Author

Esterling, Kevin M. and Bartels, Ludwig

Abstract

We present an evaluation of the impact of an atoms-first curriculum on student success in introductory chemistry classes and find that initially a lower fraction of students obtain passing grades in the first and second quarters of the general chemistry series. This effect is more than reversed for first-quarter students after one year of instruction experience with the atoms-first curriculum, yet challenges with the second quarter remain. This study involves more than 8000 students over five years, with two-fifths of them taught using the atoms-first approach. It provides a cautionary example for the adoption of this approach.

Published
2013
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24. Elemental excitations in MoI3 one-dimensional van der Waals nanowires

Author

Kargar, Fariborz, primary, Barani, Zahra, additional, Sesing, Nicholas R., additional, Mai, Thuc T., additional, Debnath, Topojit, additional, Zhang, Huairuo, additional, Liu, Yuhang, additional, Zhu, Yanbing, additional, Ghosh, Subhajit, additional, Biacchi, Adam J., additional, da Jornada, Felipe H., additional, Bartels, Ludwig, additional, Adel, Tehseen, additional, Hight Walker, Angela R., additional, Davydov, Albert V., additional, Salguero, Tina T., additional, Lake, Roger K., additional, and Balandin, Alexander A., additional

Published
2022
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26. Supplementary data for 'Methanol carbonylation to acetaldehyde on Au particles supported by single-layer MoS2 grown on silica'

Author

Almeida, Kortney, Chagoya, Katerina L., Felix, Alan, Jiang, Tao, Le, Duy, Rawal, Takat B., Evans, Prescott E., Wurch, Michelle, Yamaguchi, Koichi, Dowben, Peter A., Bartels, Ludwig, Rahman, Talat S, and Blair, Richard G

Subjects
structure, MoS2, methanol, catalyst
Abstract

This dataset contains the following structures, that are used in: K. Almeida, K.L. Chagoya, A. Felix, T. Jiang, D. Le, T.B. Rawal, P.E. Evans, M. Wurch, K. Yamaguchi, P.A. Dowben, L. Bartels, T.S. Rahman, and R.G. Blair, "Methanol carbonylation to acetaldehyde on Au particles supported by single-layer MoS2 grown on silica," Journal of Physics: Condensed Matter (2021). DOI:10.1088/1361-648X/ac40ad 1. Au13-MoS2.extxyz 2. CO.extxyz 3. H2.extxyz 4. CH3.extxyz 5. CH3CO.extxyz 6. CH3CHO.extxyz 7. CH3+CO_CH3CO_IS.extxyz 8. CH3+CO_CH3CO_TS.extxyz 9. CH3+CO_CH3CO_FS.extxyz 10. CH3CO+H_CH3CHO_IS.extxyz 11. CH3CO+H_CH3CHO_TS.extxyz 12. CH3CO+H_CH3CHO_FS.extxyz #File format All data ara written in extxyz, which includes coordinates of atoms, dimension of supercell, force components acting on each atom, total energy. Instruction on reading the data can be found at https://wiki.fysik.dtu.dk/ase/ase/io/formatoptions.html#extxyz #Other files get_energy.py: reproducing computational data reported in the paper. POTCAR: Potential files used in the calculations. &nbsp

Published
2021
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28. Methanol carbonylation to acetaldehyde on Au particles supported by single-layer MoS2 grown on silica

Author

Almeida, Kortney, primary, Chagoya, Katerina, additional, Felix, Alan, additional, Jiang, Tao, additional, Le, Duy, additional, Rawal, Takat B, additional, Evans, Prescott E, additional, Wurch, Michelle, additional, Yamaguchi, Koichi, additional, Dowben, Peter A, additional, Bartels, Ludwig, additional, Rahman, Talat S, additional, and Blair, Richard G, additional

Published
2021
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29. Facile growth of monolayer MoS2 film areas on SiO2

Author

Mann, John, Sun, Dezheng, Ma, Quan, Chen, Jen-Ru, Preciado, Edwin, Ohta, Taisuke, Diaconescu, Bogdan, Yamaguchi, Koichi, Tran, Tai, Wurch, Michelle, Magnone, KatieMarie, Heinz, Tony F., Kellogg, Gary L., Kawakami, Roland, and Bartels, Ludwig

Published
2013
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32. Elemental excitations in MoI3 one-dimensional van der Waals nanowires.

Author

Kargar, Fariborz, Barani, Zahra, Sesing, Nicholas R., Mai, Thuc T., Debnath, Topojit, Zhang, Huairuo, Liu, Yuhang, Zhu, Yanbing, Ghosh, Subhajit, Biacchi, Adam J., da Jornada, Felipe H., Bartels, Ludwig, Adel, Tehseen, Hight Walker, Angela R., Davydov, Albert V., Salguero, Tina T., Lake, Roger K., and Balandin, Alexander A.

Subjects
NANOWIRES, MAGNETIC transitions, RAMAN spectroscopy, MAGNONS, CRYSTAL structure, PHONONS, SKYRMIONS
Abstract

We report the polarization-dependent Raman spectra of exfoliated MoI3, a van der Waals material with a "true one-dimensional" crystal structure that can be exfoliated to individual atomic chains. The temperature evolution of several Raman features reveals an anomalous behavior suggesting a phase transition of magnetic origin. Theoretical considerations indicate that MoI3 is an easy-plane antiferromagnet with alternating spins along the dimerized chains and with inter-chain helical spin ordering. The calculated frequencies of phonons and magnons are consistent with the interpretation of the experimental Raman data. The obtained results shed light on the specifics of the phononic and magnonic states in MoI3 and provide a strong motivation for further study of this unique material with potential for future spintronic applications. [ABSTRACT FROM AUTHOR]

Published
2022
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33. Methanol carbonylation to acetaldehyde on Au particles supported by single-layer MoS2 grown on silica

Author

Almeida, Kortney, Chagoya, Katerina, Felix, Alan, Jiang, Tao, Le, Duy, Rawal, Takat B, Evans, Prescott E, Wurch, Michelle, Yamaguchi, Koichi, Dowben, Peter A., Bartels, Ludwig, Rahman, Talat S, Blair, Richard G, Almeida, Kortney, Chagoya, Katerina, Felix, Alan, Jiang, Tao, Le, Duy, Rawal, Takat B, Evans, Prescott E, Wurch, Michelle, Yamaguchi, Koichi, Dowben, Peter A., Bartels, Ludwig, Rahman, Talat S, and Blair, Richard G

Abstract

Homogenous single-layer MoS2 films coated with sub-single layer amounts of gold are found to isolate the reaction of methanol with carbon monoxide, the fundamental step toward higher alcohols, from an array of possible surface reactions. Active surfaces were prepared from homogenous single-layer MoS2 films coated with sub-single layer amounts of gold. These gold atoms formed clusters on the MoS2 surface. A gas mixture of carbon monoxide (CO) and methanol (CH3OH) was partially converted to acetaldehyde (CH3CHO) under mild process conditions (308 kPa and 393 K). This carbonylation of methanol to a C2 species is a critical step toward the formation of higher alcohols. Density functional theory modeling of critical steps of the catalytic process identify a viable reaction pathway. Imaging and spectroscopic methods revealed that the single layer of MoS2 facilitated formation of nanoscale gold islands, which appear to sinter through Ostwald ripening. The formation of acetaldehyde by the catalytic carbonylation of methanol over supported gold clusters is an important step toward realizing controlled production of useful molecules from low carbon-count precursors.

Published
2021

34. Simplified setup for electro-optic sampling of terahertz pulses

Author

Grebenev, Viatcheslav and Bartels, Ludwig

Subjects
Spectrum analysis -- Methods, Electrooptics -- Research, Astronomy, Physics
Abstract

We present a simplified setup for the generation and electro-optic sampling of terahertz pulses employing a nonamplified pump source and a single ZnTe crystal, which is simultaneously used for generation and detection. The setup is characterized, and first steps of its application for gas-phase spectroscopy are presented. OCIS codes: 300.1030, 260.3090.

Published
2003

36. Valley lifetimes of conduction band electrons in monolayer WSe2

Author

Ersfeld, Manfred, primary, Volmer, Frank, additional, Rathmann, Lars, additional, Kotewitz, Luca, additional, Heithoff, Maximilian, additional, Lohmann, Mark, additional, Yang, Bowen, additional, Watanabe, Kenji, additional, Taniguchi, Takashi, additional, Bartels, Ludwig, additional, Shi, Jing, additional, Stampfer, Christoph, additional, and Beschoten, Bernd, additional

Published
2020
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37. How Photoinduced Gate Screening and Leakage Currents Dynamically Change the Fermi Level in 2D Materials

Author

Volmer, Frank, primary, Ersfeld, Manfred, additional, Rathmann, Lars, additional, Heithoff, Maximilian, additional, Kotewitz, Luca, additional, Lohmann, Mark, additional, Yang, Bowen, additional, Watanabe, Kenji, additional, Taniguchi, Takashi, additional, Bartels, Ludwig, additional, Shi, Jing, additional, Stampfer, Christoph, additional, and Beschoten, Bernd, additional

Published
2020
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38. Unveiling Valley Lifetimes of Free Charge Carriers in Monolayer WSe2

Author

Ersfeld, Manfred, primary, Volmer, Frank, additional, Rathmann, Lars, additional, Kotewitz, Luca, additional, Heithoff, Maximilian, additional, Lohmann, Mark, additional, Yang, Bowen, additional, Watanabe, Kenji, additional, Taniguchi, Takashi, additional, Bartels, Ludwig, additional, Shi, Jing, additional, Stampfer, Christoph, additional, and Beschoten, Bernd, additional

Published
2020
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39. Chemical insight from density functional modeling of molecular adsorption: Tracking the bonding and diffusion of anthracene derivatives on Cu(111) with molecular orbitals.

Author

Wyrick, Jonathan, Einstein, T. L., and Bartels, Ludwig

Subjects
DENSITY functional theory, MOLECULAR orbitals, ANTHRACENE derivatives, COPPER compounds, DIFFUSION, ELECTRONIC structure
Abstract

We present a method of analyzing the results of density functional modeling of molecular adsorption in terms of an analogue of molecular orbitals. This approach permits intuitive chemical insight into the adsorption process. Applied to a set of anthracene derivates (anthracene, 9,10-anthraquinone, 9,10-dithioanthracene, and 9,10-diselenonanthracene), we follow the electronic states of the molecules that are involved in the bonding process and correlate them to both the molecular adsorption geometry and the species' diffusive behavior. We additionally provide computational code to easily repeat this analysis on any system. [ABSTRACT FROM AUTHOR]

Published
2015
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41. Low Resistivity and High Breakdown Current Density of 10 nm Diameter van der Waals TaSe3 Nanowires by Chemical Vapor Deposition

Author

Empante, Thomas A., primary, Martinez, Aimee, additional, Wurch, Michelle, additional, Zhu, Yanbing, additional, Geremew, Adane K., additional, Yamaguchi, Koichi, additional, Isarraraz, Miguel, additional, Rumyantsev, Sergey, additional, Reed, Evan J., additional, Balandin, Alexander A., additional, and Bartels, Ludwig, additional

Published
2019
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42. Towards Higher Alcohol Formation using a single-layer MoS2 activated Au on Silica: Methanol Carbonylation to Acetaldehyde

Author

Almeida, Kortney, primary, Chagoya, Katerina L., additional, Felix, Alan, additional, Jiang, Tao, additional, Le, Duy, additional, Rawal, Takat B., additional, Evans, Prescott E., additional, Wurch, Michelle, additional, Yamaguchi, Koichi, additional, Dowben, Peter A., additional, Bartels, Ludwig, additional, Rahman, Talat S., additional, and Blair, Richard G., additional

Published
2019
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44. A semi-empirical integrated microring cavity approach for 2D material optical index identification at 1.55 ��m

Author

Maiti, Rishi, Hemnani, Rohit A., Amin, Rubab, Ma, Zhizhen, Tahersima, Mohammad H., Empante, Tom A., Dalir, Hamed, Agarwal, Ritesh, Bartels, Ludwig, and Sorger, Volker J.

Subjects
Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Applied Physics (physics.app-ph)
Abstract

Atomically thin two-dimensional (2D) materials provide a wide range of basic building blocks with unique properties, making them ideal for heterogeneous integration with a mature chip platform for advances in optical communication technology. Control and understanding of the precise value of the optical index of these materials, however, is challenging, due to the small lateral flake dimension. Here we demonstrate a semi-empirical method to determine the index of a 2D material (nMoTe2 of 4.36+0.011i) near telecommunication-relevant wavelength by integrating few layers of MoTe2 onto a micro-ring resonator. The placement, control, and optical-property understanding of 2D materials with integrated photonics paves a way for further studies of active 2D material-based optoelectronics and circuits., arXiv admin note: substantial text overlap with arXiv:1807.03945

Published
2018
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46. Metallic Transport in Chemical Vapor Deposition ZrTe3Nanoribbons on a SiO2Wafer Substrate

Author

Jin, Jing, Wurch, Michelle, Baraghani, Saba, Coyle, Daniel J., Empante, Thomas A., Kargar, Fariborz, Balandin, Alexander A., and Bartels, Ludwig

Abstract

We report on the chemical vapor deposition (CVD) growth of quasi-one-dimensional zirconium tritelluride (ZrTe3) at temperatures below 600 °C and process times under an hour, which results in a material on a SiO2/Si wafer substrate that offers electrical conductivity comparable to the bulk. This study combines tailored CVD processing using a tube-in-a-tube technique with characterization by optical microscopy, Raman spectroscopy, and scanning electron microscopy. Transmission electron microscopy validates the composition and offers atomic contrast. Electrical transport measurements employ an yttrium-gold stack to achieve good adhesion and low contact resistance. A positive temperature coefficient is observed, as expected for a metallic material. The obtained results are important for the proposed applications of quasi-one-dimensional van der Waals materials in the next-generation electronic devices.

Published
2021
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49. Hybrid single-layer/bulk tungsten diselenide transistors by lithographic encoding of material thickness in chemical vapor deposition

Author

Liao, Ingrid, primary, Barroso, David, additional, Nguyen, Ariana E, additional, Duong, Natalie, additional, Yurek, Quinten B, additional, Merida, Cindy S, additional, Peña, Pedro, additional, Lu, I-Hsi, additional, Valentin, Michael D, additional, Stecklein, Gordon, additional, and Bartels, Ludwig, additional

Published
2018
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