Your search keyword '"Zettl, Alex"' showing total 1,285 results

1. Repairable and Reconfigurable Structured Liquid Circuits

Author

Fink, Zachary, Kim, Paul Y, Han, Jiale, Wu, Xuefei, Popple, Derek, Zhu, Shipei, Xue, Han, Zettl, Alex, Ashby, Paul D, Helms, Brett A, and Russell, Thomas P

Subjects

Engineering, Materials Engineering, Electronics, Sensors and Digital Hardware, 3D printing, liquid electronics, reconfigurable, structured liquid, sulfonated PANI, MSD-General, MSD-Structured Liquids, Physical Sciences, Chemical Sciences, Materials, Chemical sciences, Physical sciences

Abstract

The advance of printed electronics is significantly bolstered by the development of liquid-state electronics that overcome the inherent limitations in flexibility and reconfigurability of solid-state electronics. By integrating the biocompatibility and conductivity of sulfonated polyaniline (S-PANI) and phytic acid (PA) with the reconfigurability of structured liquids, highly conductive all-liquid threads are developed. The dense packing and overlap of PA/S-PANI complexes at an oil/water interface promotes in-plane electron transport, and standard four-point probe measurements of PA/S-PANI interfacial assemblies demonstrate enhanced electrical properties. Notably, the rapid jetting of the ink phase into the matrix phase allows for liquid threads to be printed, enabling the fabrication of large-scale, conductive pathways between two electrodes and liquid circuits. Upon mechanical cleavage of the liquid wires, circuits can be broken, but will easily self-repair using an electric field, making this motif useful in the design of switches as well as restoring conductive pathways in series or in parallel. The demonstrated flexibility and reconfigurability these PA/S-PANI wires possess hold significant promise for their practical use in the design of flexible and adaptive bioelectronics that can be repaired on demand, signifying a transformative step in the evolution of liquid electronic materials.

Published

2024

2. Responsive‐Hydrogel Aquabots

Author

Zhu, Shipei, Cui, Huanqing, Pan, Yi, Popple, Derek, Xie, Ganhua, Fink, Zachary, Han, Jiale, Zettl, Alex, Shum, Ho Cheung, and Russell, Thomas P

Subjects

Engineering, Materials Engineering, Electronics, Sensors and Digital Hardware, Biomedical Engineering, Bioengineering, Generic health relevance, all-liquid robots, aqueous two-phase systems, adaptive materials, flexible electronics, responsive hydrogels, all‐liquid robots, aqueous two‐phase systems

Abstract

It remains a challenge to produce soft robots that can mimic the responsive adaptability of living organisms. Rather than fabricating soft robots from bulk hydrogels,hydrogels are integrated into the interfacial assembly of aqueous two-phase systems to generate ultra-soft and elastic all-aqueous aquabots that exhibit responsive adaptability, that can shrink on demand and have electrically conductive functions. The adaptive functions of the aquabots provide a new platform to develop minimally invasive surgical devices, targeted drug delivery systems, and flexible electronic sensors and actuators.

Published

2024

3. SiX2 (X = S, Se) Single Chains and (Si–Ge)X2 Quaternary Alloys

Author

Lee, Yangjin, Choi, Young Woo, Li, Linxuan, Zhou, Wu, Cohen, Marvin L, Kim, Kwanpyo, and Zettl, Alex

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Engineering, Physical Sciences, Condensed Matter Physics, one-dimensional materials, silicon dichalcogenides, nanotubes, atomic chain, transmission electronmicroscopy, density functional theory, transmission electron microscopy, Nanoscience & Nanotechnology

Abstract

Layered or chain materials have received significant research attention owing to their interesting physical properties, which can dramatically change when the material is thinned from bulk (three-dimensional) to thin two-dimensional sheet or one-dimensional (1D) chain form. Materials with the stoichiometry AX2 with A = Si or Ge and X = S or Se form an especially intriguing semiconducting class. For example, bulk silicon dichalcogenides (SiX2) consist of 1D chains held together by van der Waals forces. Although this structural configuration has the potential to reveal interesting physical phenomena within the 1D limit, obtaining SiX2 single chains has been challenging. We here examine experimentally and theoretically SiX2 materials in the low chain number limit. Carbon nanotubes serve as growth templates and stabilize and protect the structures, and atomic-resolution scanning transmission electron microscopy directly identifies the atomic structure. Two distinct chain structures are observed for SiX2. SixGe1-xS2(1-y)Se2y quaternary alloy chains are also synthesized and characterized, demonstrating tunable semiconducting properties at the atomic-chain level. Density functional theory calculations reveal that the band gap of these alloy chains can be widely tuned through composition engineering. This work offers the possibilities for synthesizing and controlling semiconductor compositions at the single-chain limit to tailor material properties.

Published

2024

4. Three-dimensional structure of buried heterointerfaces revealed by multislice ptychography

Author

O’Leary, Colum M, Sha, Haozhi, Zhang, Jianhua, Su, Cong, Kahn, Salman, Jiang, Huaidong, Zettl, Alex, Ciston, Jim, and Miao, Jianwei

Subjects

Physical Sciences, Condensed Matter Physics, Bioengineering, Engineering, Physical sciences

Abstract

We report on the three-dimensional (3D) structure determination of a twisted hexagonal boron nitride (h-BN) heterointerface from a single-view dataset using multislice ptychography. We identify the buried heterointerface between two twisted h-BN flakes with a lateral resolution of 0.57 Å and a depth resolution of 2.5 nm. The latter represents a significant improvement (∼2.7 times) over the aperture-limited depth resolution of incoherent imaging modes, such as annular-dark-field scanning transmission electron microscopy. This improvement is attributed to the diffraction signal extending beyond the aperture edge, with the depth resolution set by the curvature of the Ewald sphere. Future advancements in this approach could enhance the depth resolution to the subnanometer level and enable the identification of individual dopants, defects, and color centers in twisted heterointerfaces and other materials.

Published

2024

5. Fundamentals and emerging optical applications of hexagonal boron nitride: a tutorial

Author

Su, Cong, Janzen, Eli, He, Mingze, Li, Chi, Zettl, Alex, Caldwell, Joshua D, Edgar, James H, and Aharonovich, Igor

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, Optical Physics, Nanotechnology, Atomic, molecular and optical physics, Classical physics

Abstract

Hexagonal boron nitride (hBN), also known as white graphite, is a transparent layered crystal with a wide bandgap. Its crystal structure resembles graphite, featuring layers composed of honeycomb lattices held together through van der Waals forces. The layered crystal structure of hBN facilitates exfoliation into thinner flakes and makes it highly anisotropic in in-plane and out-of-plane directions. Unlike graphite, hBN is both insulating and transparent, making it an ideal material for isolating devices from the environment and acting as a waveguide. As a result, hBN has found extensive applications in optical devices, electronic devices, and quantum photonic devices. This comprehensive tutorial aims to provide readers with a thorough understanding of hBN, covering its synthesis, lattice and spectroscopic characterization, and various applications in optoelectronic and quantum photonic devices. This tutorial is designed for both readers without prior experience in hBN and those with expertise in specific fields seeking to understand its relevance and connections to others.

Published

2024

6. Imaging Tunable Luttinger Liquid Systems in van der Waals Heterostructures

Author

Li, Hongyuan, Xiang, Ziyu, Wang, Tianle, Naik, Mit H., Kim, Woochang, Nie, Jiahui, Li, Shiyu, Ge, Zhehao, He, Zehao, Ou, Yunbo, Banerjee, Rounak, Taniguchi, Takashi, Watanabe, Kenji, Tongay, Sefaattin, Zettl, Alex, Louie, Steven G., Zaletel, Michael P., Crommie, Michael F., and Wang, Feng

Subjects

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

Abstract

One-dimensional (1D) interacting electrons are often described as a Luttinger liquid1-4 having properties that are intrinsically different from Fermi liquids in higher dimensions5,6. 1D electrons in materials systems exhibit exotic quantum phenomena that can be tuned by both intra- and inter-1D-chain electronic interactions, but their experimental characterization can be challenging. Here we demonstrate that layer-stacking domain walls (DWs) in van der Waals heterostructures form a broadly tunable Luttinger liquid system including both isolated and coupled arrays. We have imaged the evolution of DW Luttinger liquids under different interaction regimes tuned by electron density using a novel scanning tunneling microscopy (STM) technique. Single DWs at low carrier density are highly susceptible to Wigner crystallization consistent with a spin-incoherent Luttinger liquid, while at intermediate densities dimerized Wigner crystals form due to an enhanced magneto-elastic coupling. Periodic arrays of DWs exhibit an interplay between intra- and inter-chain interactions that gives rise to new quantum phases. At low electron densities inter-chain interactions are dominant and induce a 2D electron crystal composed of phased-locked 1D Wigner crystal in a staggered configuration. Increased electron density causes intra-chain fluctuation potentials to dominate, leading to an electronic smectic liquid crystal phase where electrons are ordered with algebraical correlation decay along the chain direction but disordered between chains. Our work shows that layer-stacking DWs in 2D heterostructures offers new opportunities to explore Luttinger liquid physics.

Published

2024

7. Low Resistance Contact to P‑Type Monolayer WSe2

Author

Xie, Jingxu, Zhang, Zuocheng, Zhang, Haodong, Nagarajan, Vikram, Zhao, Wenyu, Kim, Ha-Leem, Sanborn, Collin, Qi, Ruishi, Chen, Sudi, Kahn, Salman, Watanabe, Kenji, Taniguchi, Takashi, Zettl, Alex, Crommie, Michael F, Analytis, James, and Wang, Feng

Subjects

Physical Sciences, Engineering, Nanotechnology, Condensed Matter Physics, ohmic contacts, p-type monolayer WSe2 FET, charge transfer, type-III band alignment, alpha-RuCl3, α-RuCl3, Nanoscience & Nanotechnology

Abstract

Advanced microelectronics in the future may require semiconducting channel materials beyond silicon. Two-dimensional (2D) semiconductors, with their atomically thin thickness, hold great promise for future electronic devices. One challenge to achieving high-performance 2D semiconductor field effect transistors (FET) is the high contact resistance at the metal-semiconductor interface. In this study, we develop a charge-transfer doping strategy with WSe2/α-RuCl3 heterostructures to achieve low-resistance ohmic contact for p-type monolayer WSe2 transistors. We show that hole doping as high as 3 × 1013 cm-2 can be achieved in the WSe2/α-RuCl3 heterostructure due to its type-III band alignment, resulting in an ohmic contact with resistance of 4 kΩ μm. Based on that, we demonstrate p-type WSe2 transistors with an on-current of 35 μA·μm-1 and an ION/IOFF ratio exceeding 109 at room temperature.

Published

2024

8. Wigner Molecular Crystals from Multi-electron Moir\'e Artificial Atoms

Author

Li, Hongyuan, Xiang, Ziyu, Reddy, Aidan P., Devakul, Trithep, Sailus, Renee, Banerjee, Rounak, Taniguchi, Takashi, Watanabe, Kenji, Tongay, Sefaattin, Zettl, Alex, Fu, Liang, Crommie, Michael F., and Wang, Feng

Subjects

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

Abstract

Semiconductor moir\'e superlattices provide a versatile platform to engineer new quantum solids composed of artificial atoms on moir\'e sites. Previous studies have mostly focused on the simplest correlated quantum solid - the Fermi-Hubbard model - where intra-atom interactions are simplified to a single onsite repulsion energy U. These studies have revealed novel quantum phases ranging from Mott insulators to quantum anomalous Hall insulators at a filling of one electron per moir\'e unit cell. New types of quantum solids should arise at even higher filling factors where the multi-electron configuration of moir\'e artificial atoms provides new degrees of freedom. Here we report the experimental observation of Wigner molecular crystals emerging from multi-electron artificial atoms in twisted bilayer WS2 moir\'e superlattices. Moir\'e artificial atoms, unlike natural atoms, can host qualitatively different electron states due to the interplay between quantized energy levels and Coulomb interactions. Using scanning tunneling microscopy (STM), we demonstrate that Wigner molecules appear in multi-electron artificial atoms when Coulomb interactions dominate. Three-electron Wigner molecules, for example, are seen to exhibit a characteristic trimer pattern. The array of Wigner molecules observed in a moir\'e superlattice comprises a new crystalline phase of electrons: the Wigner molecular crystal. We show that these Wigner molecular crystals are highly tunable through mechanical strain, moir\'e period, and carrier charge type. Our study presents new opportunities for exploring quantum phenomena in moir\'e quantum solids composed of multi-electron artificial atoms.

Published

2023

9. Low Resistance Ohmic Contact to P-type Monolayer WSe2

Author

Xie, Jingxu, Zhang, Zuocheng, Zhang, Haodong, Nagarajan, Vikram, Zhao, Wenyu, Kim, Haleem, Sanborn, Collin, Qi, Ruishi, Chen, Sudi, Kahn, Salman, Watanabe, Kenji, Taniguchi, Takashi, Zettl, Alex, Crommie, Michael, Analytis, James, and Wang, Feng

Subjects

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

Abstract

Advanced microelectronics in the future may require semiconducting channel materials beyond silicon. Two-dimensional (2D) semiconductors, characterized by their atomically thin thickness, hold immense promise for high-performance electronic devices at the nanometer scale with lower heat dissipation. One challenge for achieving high-performance 2D semiconductor field effect transistors (FET), especially for p-type materials, is the high electrical contact resistance present at the metal-semiconductor interface. In conventional bulk semiconductors, low resistance ohmic contact is realized through heavy substitutional doping with acceptor or donor impurities at the contact region. The strategy of substitutional doping, however, does not work for p-type 2D semiconductors such as monolayer tungsten diselenide (WSe$_2$).In this study, we developed highly efficient charge-transfer doping with WSe$_2$/$\alpha$-RuCl$_3$ heterostructures to achieve low-resistance ohmic contact for p-type WSe$_2$ transistors. We show that a hole doping as high as 3$\times$10$^{13}$ cm$^{-2}$ can be achieved in the WSe$_2/\alpha$-RuCl$_3$ heterostructure due to its type-III band alignment. It results in an Ohmic contact with resistance lower than 4 k Ohm $\mu$m at the p-type monolayer WSe$_2$/metal junction. at room temperature. Using this low-resistance contact, we demonstrate high-performance p-type WSe$_2$ transistors with a saturation current of 35 $\mu$A$\cdot$ $\mu$m$^{-1}$ and an I$_{ON}$/I$_{OFF}$ ratio exceeding 10$^9$ It could enable future microelectronic devices based on 2D semiconductors and contribute to the extension of Moore's law.

Published

2023

10. Electrically controlled interlayer trion fluid in electron-hole bilayers

Author

Qi, Ruishi, Li, Qize, Zhang, Zuocheng, Chen, Sudi, Xie, Jingxu, Ou, Yunbo, Cui, Zhiyuan, Dai, David D., Joe, Andrew Y., Taniguchi, Takashi, Watanabe, Kenji, Tongay, Sefaattin, Zettl, Alex, Fu, Liang, and Wang, Feng

Subjects

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

Abstract

The combination of repulsive and attractive Coulomb interactions in a quantum electron(e)-hole(h) fluid can give rise to novel correlated phases of multiparticle charge complexes such as excitons, trions and biexcitons. Here we report the first experimental realization of an electrically controlled interlayer trion fluid in two-dimensional van der Waals heterostructures. We demonstrate that in the strong coupling regime of electron-hole bilayers, electrons and holes in separate layers can spontaneously form three-particle trion bound states that resemble positronium ions in high energy physics. The interlayer trions can assume 1e-2h and 2e-1h configurations, where electrons and holes are confined in different transition metal dichalcogenide layers. We show that the two correlated holes in 1e-2h trions form a spin-singlet state with a spin gap of ~1meV. By electrostatic gating, the equilibrium state of our system can be continuously tuned into an exciton fluid, a trion fluid, an exciton-trion mixture, a trion-charge mixture or an electron-hole plasma. Upon optical excitation, the system can host novel high-order multiparticle charge complexes including interlayer four-particle complex (tetrons) and five-particle complex (pentons). Our work demonstrates a unique platform to study novel correlated phases of tunable Bose-Fermi mixtures and opens up new opportunities to realize artificial ions/molecules in electronic devices.

Published

2023

11. Manipulation of chiral interface states in a moiré quantum anomalous Hall insulator

Author

Zhang, Canxun, Zhu, Tiancong, Kahn, Salman, Soejima, Tomohiro, Watanabe, Kenji, Taniguchi, Takashi, Zettl, Alex, Wang, Feng, Zaletel, Michael P., and Crommie, Michael F.

Published

2024

12. Engineering correlated insulators in bilayer graphene with a remote Coulomb superlattice

Author

Zhang, Zuocheng, Xie, Jingxu, Zhao, Wenyu, Qi, Ruishi, Sanborn, Collin, Wang, Shaoxin, Kahn, Salman, Watanabe, Kenji, Taniguchi, Takashi, Zettl, Alex, Crommie, Michael, and Wang, Feng

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, MSD-General, MSD-VdW Heterostructures, Nanoscience & Nanotechnology

Abstract

Electron superlattices allow the engineering of correlated and topological quantum phenomena. The recent emergence of moiré superlattices in two-dimensional heterostructures has led to exciting discoveries related to quantum phenomena. However, the requirement for the moiré pattern poses stringent limitations, and its potential cannot be switched on and off. Here, we demonstrate remote engineering and on/off switching of correlated states in bilayer graphene. Employing a remote Coulomb superlattice realized by localized electrons in twisted bilayer WS2, we impose a Coulomb superlattice in the bilayer graphene with period and strength determined by the twisted bilayer WS2. When the remote superlattice is turned off, the two-dimensional electron gas in the bilayer graphene is described by a Fermi liquid. When it is turned on, correlated insulating states at both integer and fractional filling factors emerge. This approach enables in situ control of correlated quantum phenomena in two-dimensional materials hosting a two-dimensional electron gas.

Published

2024

13. 1D Magnetic MX3 Single‐Chains (M = Cr, V and X = Cl, Br, I)

Author

Lee, Yangjin, Choi, Young Woo, Lee, Kihyun, Song, Chengyu, Ercius, Peter, Cohen, Marvin L, Kim, Kwanpyo, and Zettl, Alex

Subjects

Physical Sciences, Condensed Matter Physics, 1D materials, atomic chain, density functional theory, magnetic chain, nanotubes, transition metal halide, transmission electron microscopy, Chemical Sciences, Engineering, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

Magnetic materials in reduced dimensions are not only excellent platforms for fundamental studies of magnetism, but they play crucial roles in technological advances. The discovery of intrinsic magnetism in monolayer 2D van der Waals systems has sparked enormous interest, but the single-chain limit of 1D magnetic van der Waals materials has been largely unexplored. This paper reports on a family of 1D magnetic van der Waals materials with composition MX3 (M = Cr, V, and X = Cl, Br, I), prepared in fully-isolated fashion within the protective cores of carbon nanotubes. Atomic-resolution scanning transmission electron microscopy identifies unique structures that differ from the well-known 2D honeycomb lattice MX3 structure. Density functional theory calculations reveal charge-driven reversible magnetic phase transitions.

Published

2023

14. Three-dimensional imaging of buried heterointerfaces

Author

O'Leary, Colum M., Sha, Haozhi, Zhang, Jianhua, Su, Cong, Kahn, Salman, Jiang, Huaidong, Zettl, Alex, Ciston, Jim, and Miao, Jianwei

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics

Abstract

We report three-dimensional (3D) structure determination of a twisted hexagonal boron nitride (h-BN) heterointerface from a single-view data set using multislice ptychography. We identify the buried heterointerface between two twisted h-BN flakes with a lateral resolution of 0.57 {\AA} and a depth resolution of 2.5 nm. The latter is a significant improvement (~2.7 times) over the aperture-limited depth resolution of incoherent imaging modes such as annular-dark-field scanning transmission electron microscopy. This is attributed to the diffraction signal extending beyond the aperture edge with the depth resolution set by the curvature of the Ewald sphere. Future advances to this approach could improve the depth resolution to the sub-nanometer level and enable the identification of individual dopants, defects and color centers in twisted heterointerfaces and other materials.

Published

2023

15. Imaging Moir\'e Excited States with Photocurrent Tunneling Microscopy

Author

Li, Hongyuan, Xiang, Ziyu, Naik, Mit H., Kim, Woochang, Li, Zhenglu, Sailus, Renee, Banerjee, Rounak, Taniguchi, Takashi, Watanabe, Kenji, Tongay, Sefaattin, Zettl, Alex, da Jornada, Felipe H., Louie1, Steven G., Crommie, Michael F., and Wang, Feng

Subjects

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

Abstract

Moir\'e superlattices provide a highly tunable and versatile platform to explore novel quantum phases and exotic excited states ranging from correlated insulators1-17 to moir\'e excitons7-10,18. Scanning tunneling microscopy has played a key role in probing microscopic behaviors of the moir\'e correlated ground states at the atomic scale1,11-15,19. Atomic-resolution imaging of quantum excited state in moir\'e heterostructures, however, has been an outstanding experimental challenge. Here we develop a novel photocurrent tunneling microscopy by combining laser excitation and scanning tunneling spectroscopy (laser-STM) to directly visualize the electron and hole distribution within the photoexcited moir\'e exciton in a twisted bilayer WS2 (t-WS2). We observe that the tunneling photocurrent alternates between positive and negative polarities at different locations within a single moir\'e unit cell. This alternating photocurrent originates from the exotic in-plane charge-transfer (ICT) moir\'e exciton in the t-WS2 that emerges from the competition between the electron-hole Coulomb interaction and the moir\'e potential landscape. Our photocurrent maps are in excellent agreement with our GW-BSE calculations for excitonic states in t-WS2. The photocurrent tunneling microscopy creates new opportunities for exploring photoexcited non-equilibrium moir\'e phenomena at the atomic scale.

Published

2023

16. Imaging Field‐Driven Melting of a Molecular Solid at the Atomic Scale

Author

Liou, Franklin, Tsai, Hsin‐Zon, Goodwin, Zachary AH, Aikawa, Andrew S, Ha, Ethan, Hu, Michael, Yang, Yiming, Watanabe, Kenji, Taniguchi, Takashi, Zettl, Alex, Lischner, Johannes, and Crommie, Michael F

Subjects

Physical Sciences, Condensed Matter Physics, Affordable and Clean Energy, field-driven phase transitions, graphene field-effect transistor, molecular solids, nonequilibrium dynamics, solid-liquid phase coexistence, Chemical Sciences, Engineering, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

Solid-liquid phase transitions are basic physical processes, but atomically resolved microscopy has yet to capture their full dynamics. A new technique is developed for controlling the melting and freezing of self-assembled molecular structures on a graphene field-effect transistor (FET) that allows phase-transition behavior to be imaged using atomically resolved scanning tunneling microscopy. This is achieved by applying electric fields to 2,3,5,6-tetrafluoro-7,7,8,8-tetracyanoquinodimethane-decorated FETs to induce reversible transitions between molecular solid and liquid phases at the FET surface. Nonequilibrium melting dynamics are visualized by rapidly heating the graphene substrate with an electrical current and imaging the resulting evolution toward new 2D equilibrium states. An analytical model is developed that explains observed mixed-state phases based on spectroscopic measurement of solid and liquid molecular energy levels. The observed nonequilibrium melting dynamics are consistent with Monte Carlo simulations.

Published

2023

17. Mapping charge excitations in generalized Wigner crystals

Author

Li, Hongyuan, Xiang, Ziyu, Regan, Emma, Zhao, Wenyu, Sailus, Renee, Banerjee, Rounak, Taniguchi, Takashi, Watanabe, Kenji, Tongay, Sefaattin, Zettl, Alex, Crommie, Michael F., and Wang, Feng

Published

2024

18. Imaging moiré excited states with photocurrent tunnelling microscopy

Author

Li, Hongyuan, Xiang, Ziyu, Naik, Mit H., Kim, Woochang, Li, Zhenglu, Sailus, Renee, Banerjee, Rounak, Taniguchi, Takashi, Watanabe, Kenji, Tongay, Sefaattin, Zettl, Alex, da Jornada, Felipe H., Louie, Steven G., Crommie, Michael F., and Wang, Feng

Published

2024

19. Linearly dispersive bands at the onset of correlations in K$_x$C$_{60}$ films

Author

Ai, Ping, Moreschini, Luca, Mori, Ryo, Latzke, Drew W., Denlinger, Jonathan D., Zettl, Alex, Ojeda-Aristizabal, Claudia, and Lanzara, Alessandra

Subjects

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

Abstract

Molecular crystals are a flexible platform to induce novel electronic phases. Due to the weak forces between molecules, intermolecular distances can be varied over relatively larger ranges than interatomic distances in atomic crystals. On the other hand, the hopping terms are generally small, which results in narrow bands, strong correlations and heavy electrons. Here, by growing K$_x$C$_{60}$ fullerides on hexagonal layered Bi$_2$Se$_3$, we show that upon doping the series undergoes a Mott transition from a molecular insulator to a correlated metal, and an in-gap state evolves into highly dispersive Dirac-like fermions at half filling, where superconductivity occurs. This picture challenges the commonly accepted description of the low energy quasiparticles as appearing from a gradual electron doping of the conduction states, and suggests an intriguing parallel with the more famous family of the cuprate superconductors. More in general, it indicates that molecular crystals offer a viable route to engineer electron-electron interactions., Comment: 5 pages, 4 figures. Accepted at Physical Review Research

Published

2023

20. Visualizing and manipulating chiral interface states in a moir\'e quantum anomalous Hall insulator

Author

Zhang, Canxun, Zhu, Tiancong, Kahn, Salman, Soejima, Tomohiro, Watanabe, Kenji, Taniguchi, Takashi, Zettl, Alex, Wang, Feng, Zaletel, Michael P., and Crommie, Michael F.

Subjects

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

Abstract

Moir\'e systems made from stacked two-dimensional materials host novel correlated and topological states that can be electrically controlled via applied gate voltages. We have used this technique to manipulate Chern domains in an interaction-driven quantum anomalous Hall insulator made from twisted monolayer-bilayer graphene (tMBLG). This has allowed the wavefunction of chiral interface states to be directly imaged using a scanning tunneling microscope (STM). To accomplish this tMBLG carrier concentration was tuned to stabilize neighboring domains of opposite Chern number, thus providing topological interfaces completely devoid of any structural boundaries. STM tip pulse-induced quantum dots were utilized to induce new Chern domains and thereby create new chiral interface states with tunable chirality at predetermined locations. Theoretical analysis confirms the chiral nature of observed interface states and enables the determination of the characteristic length scale of valley polarization reversal across neighboring tMBLG Chern domains. tMBLG is shown to be a useful platform for imaging the exotic topological properties of correlated moir\'e systems., Comment: 30 pages, 13 figures, 1 table

Published

2022

21. Tuning the Sharing Modes and Composition in a Tetrahedral GeX2 (X = S, Se) System via One-Dimensional Confinement

Author

Lee, Yangjin, Choi, Young Woo, Lee, Kihyun, Song, Chengyu, Ercius, Peter, Cohen, Marvin L, Kim, Kwanpyo, and Zettl, Alex

Subjects

Physical Sciences, Condensed Matter Physics, One-dimensional materials, Germanium dichalcogenide, Atomic chain, Nanotubes, Transmission electron microscopy, MSD-General, MSD-Functional Nanomachines, MSD-Theory, MSD-VdW Heterostructures, Nanoscience & Nanotechnology

Abstract

The packing and connectivity of tetrahedral units are central themes in the structural and electronic properties of a host of solids. Here, we report one-dimensional (1D) chains of GeX2 (X = S or Se) with modification of the tetrahedral connectivity at the single-chain limit. Precise tuning of the edge- and corner-sharing modes between GeX2 blocks is achieved by diameter-dependent 1D confinement inside a carbon nanotube. Atomic-resolution scanning transmission electron microscopy directly confirms the existence of two distinct types of GeX2 chains. Density functional theory calculations corroborate the diameter-dependent stability of the system and reveal an intriguing electronic structure that sensitively depends on tetrahedral connectivity and composition. GeS2(1-x)Se2x compound chains are also realized, which demonstrate the tunability of the system's semiconducting properties through composition engineering.

Published

2023

22. High-Order Fractal Quantum Oscillations in Graphene/BN Superlattices in the Extreme Doping Limit

Author

Shi, Wu, Kahn, Salman, Leconte, Nicolas, Taniguchi, Takashi, Watanabe, Kenji, Crommie, Michael, Jung, Jeil, and Zettl, Alex

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, Brain Disorders, MSD-General, MSD-Functional Nanomachines, MSD-VdW Heterostructures, Mathematical Sciences, Engineering, General Physics, Mathematical sciences, Physical sciences

Abstract

Recent studies of van der Waals (vdW) heterostructures and superlattices have shown intriguing quantum phenomena, but these have been largely explored only in the moderate carrier density regime. Here, we report the probe of high-temperature fractal Brown-Zak (BZ) quantum oscillations through magnetotransport in the extreme doping regimes by applying a newly developed electron beam doping technique. This technique gives access to both ultrahigh electron and hole densities beyond the dielectric breakdown limit in graphene/BN superlattices, enabling the observation of nonmonotonic carrier-density dependence of fractal BZ states and up to fourth-order fractal BZ features despite strong electron-hole asymmetry. Theoretical tight-binding simulations qualitatively reproduce all observed fractal BZ features and attribute the nonmonotonic dependence to the weakening of superlattice effects at high carrier densities.

Published

2023

23. All‐Liquid Reconfigurable Electronics Using Jammed MXene Interfaces

Author

Popple, Derek, Shekhirev, Mikhail, Dai, Chunhui, Kim, Paul, Wang, Katherine Xiaoxin, Ashby, Paul, Helms, Brett A, Gogotsi, Yury, Russell, Thomas P, and Zettl, Alex

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Sciences, Affordable and Clean Energy, liquid devices, MXene, reconfigurable electronics, self-assembly, structured liquids, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

Rigid, solid-state components represent the current paradigm for electronic systems, but they lack post-production reconfigurability and pose ever-increasing challenges to efficient end-of-life recycling. Liquid electronics may overcome these limitations by offering flexible in-the-field redesign and separation at end-of-life via simple liquid phase chemistries. Up to now, preliminary work on liquid electronics has focused on liquid metal components, but these devices still require an encapsulating polymer and typically use alloys of rare elements like indium. Here, using the self-assembly of jammed 2D titanium carbide (Ti3 C2 Tx ) MXene nanoparticles at liquid-liquid interfaces, "all-liquid" electrically conductive sheets, wires, and simple functional devices are described including electromechanical switches and photodetectors. These assemblies combine the high conductivity of MXene nanosheets with the controllable form and reconfigurability of structured liquids. Such configurations can have applications not only in electronics, but also in catalysis and microfluidics, especially in systems where the product and substrate have affinity for solvents of differing polarity.

Published

2023

24. Imaging gate-induced molecular melting on a graphene field-effect transistor

Author

Liou, Franklin, Tsai, Hsin-Zon, Goodwin, Zachary A. H., Aikawa, Andrew S., Ha, Ethan, Hu, Michael, Yang, Yiming, Watanabe, Kenji, Taniguchi, Takashi, Zettl, Alex, Lischner, Johannes, and Crommie, Michael F.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Solid-liquid phase transitions are fundamental physical processes, but atomically-resolved microscopy has yet to capture both the solid and liquid dynamics for such a transition. We have developed a new technique for controlling the melting and freezing of 2D molecular layers on a graphene field-effect transistor (FET) that allows us to image phase transition dynamics via atomically-resolved scanning tunneling microscopy. Back-gate voltages applied to a F4TCNQ-decorated graphene FET induce reversible transitions between a charge-neutral solid phase and a negatively charged liquid phase. Nonequilibrium molecular melting dynamics are visualized by rapidly heating the graphene surface with electrical current and imaging the resulting evolution toward new equilibrium states. An analytical model has been developed that explains the observed equilibrium mixed-state phases based on spectroscopic measurement of both solid and liquid molecular energy levels. Observed non-equilibrium melting dynamics are consistent with Monte Carlo simulations.

Published

2022

25. Imaging the electron charge density in monolayer MoS2 at the {\AA}ngstrom scale

Author

Martis, Joel, Susarla, Sandhya, Rayabharam, Archith, Su, Cong, Paule, Timothy, Pelz, Philipp, Huff, Cassandra, Xu, Xintong, Li, Hao-Kun, Jaikissoon, Marc, Chen, Victoria, Pop, Eric, Saraswat, Krishna, Zettl, Alex, Aluru, Narayana R., Ramesh, Ramamoorthy, Ercius, Peter, and Majumdar, Arun

Subjects

Condensed Matter - Materials Science, Physics - Applied Physics

Abstract

Four-dimensional scanning transmission electron microscopy (4D-STEM) has recently gained widespread attention for its ability to image atomic electric fields with sub-{\AA}ngstrom spatial resolution. These electric field maps represent the integrated effect of the nucleus, core electrons and valence electrons, and separating their contributions is non-trivial. In this paper, we utilized simultaneously acquired 4D-STEM center of mass (CoM) images and annular dark field (ADF) images to determine the electron charge density in monolayer MoS2. We find that both the core electrons and the valence electrons contribute to the derived electron charge density. However, due to blurring by the probe shape, the valence electron contribution forms a nearly featureless background while most of the spatial modulation comes from the core electrons. Our findings highlight the importance of probe shape in interpreting charge densities derived from 4D STEM.

Published

2022

26. Local spectroscopy of a gate-switchable moir\'e quantum anomalous Hall insulator

Author

Zhang, Canxun, Zhu, Tiancong, Soejima, Tomohiro, Kahn, Salman, Watanabe, Kenji, Taniguchi, Takashi, Zettl, Alex, Wang, Feng, Zaletel, Michael P., and Crommie, Michael F.

Subjects

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

Abstract

In recent years, correlated insulating states, unconventional superconductivity, and topologically non-trivial phases have all been observed in several moir\'e heterostructures. However, understanding of the physical mechanisms behind these phenomena is hampered by the lack of local electronic structure data. Here, we use scanning tunnelling microscopy and spectroscopy to demonstrate how the interplay between correlation, topology, and local atomic structure determines the behaviour of electron-doped twisted monolayer-bilayer graphene. Through gate- and magnetic field-dependent measurements, we observe local spectroscopic signatures indicating a quantum anomalous Hall insulating state with a total Chern number of $\pm 2$ at a doping level of three electrons per moir\'e unit cell. We show that the sign of the Chern number and associated magnetism can be electrostatically switched only over a limited range of twist angle and sample hetero-strain values. This results from a competition between the orbital magnetization of filled bulk bands and chiral edge states, which is sensitive to strain-induced distortions in the moir\'e superlattice., Comment: Article 14 pages, 4 figures & Supplementary Information 13 pages, 9 figures

Published

2022

27. Mapping Charge Excitations in Generalized Wigner Crystals

Author

Li, Hongyuan, Xiang, Ziyu, Regan, Emma, Zhao, Wenyu, Sailus, Renee, Banerjee, Rounak, Taniguchi, Takashi, Watanabe, Kenji, Tongay, Sefaattin, Zettl, Alex, Crommie, Michael F., and Wang, Feng

Subjects

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

Abstract

Transition metal dichalcogenide-based moire superlattices exhibit very strong electron-electron correlations, thus giving rise to strongly correlated quantum phenomena such as generalized Wigner crystal states. Theoretical studies predict that unusual quasiparticle excitations across the correlated gap between upper and lower Hubbard bands can arise due to long-range Coulomb interactions in generalized Wigner crystal states. Here we describe a new scanning single-electron charging (SSEC) spectroscopy technique with nanometer spatial resolution and single-electron charge resolution that enables us to directly image electron and hole wavefunctions and to determine the thermodynamic gap of generalized Wigner crystal states in twisted WS2 moire heterostructures. High-resolution SSEC spectroscopy was achieved by combining scanning tunneling microscopy (STM) with a monolayer graphene sensing layer, thus enabling the generation of individual electron and hole quasiparticles in generalized Wigner crystals. We show that electron and hole quasiparticles have complementary wavefunction distributions and that thermodynamic gaps of order 50meV exist for the 1/3 and 2/3 generalized Wigner crystal states.

Published

2022

28. Imaging Quantum Interference in Stadium-Shaped Monolayer and Bilayer Graphene Quantum Dots

Author

Ge, Zhehao, Wong, Dillon, Lee, Juwon, Joucken, Frederic, Quezada-Lopez, Eberth A., Kahn, Salman, Tsai, Hsin-Zon, Taniguchi, Takashi, Watanabe, Kenji, Wang, Feng, Zettl, Alex, Crommie, Michael F., and Velasco Jr, Jairo

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Experimental realization of graphene-based stadium-shaped quantum dots (QDs) have been few and incompatible with scanned probe microscopy. Yet, direct visualization of electronic states within these QDs is crucial for determining the existence of quantum chaos in these systems. We report the fabrication and characterization of electrostatically defined stadium-shaped QDs in heterostructure devices composed of monolayer graphene (MLG) and bilayer graphene (BLG). To realize a stadium-shaped QD, we utilized the tip of a scanning tunneling microscope to charge defects in a supporting hexagonal boron nitride flake. The stadium states visualized are consistent with tight-binding-based simulations, but lack clear quantum chaos signatures. The absence of quantum chaos features in MLG-based stadium QDs is attributed to the leaky nature of the confinement potential due to Klein tunneling. In contrast, for BLG-based stadium QDs (which have stronger confinement) quantum chaos is precluded by the smooth confinement potential which reduces interference and mixing between states.

Published

2022

29. Solving Complex Nanostructures With Ptychographic Atomic Electron Tomography

Author

Pelz, Philipp M, Griffin, Sinead, Stonemeyer, Scott, Popple, Derek, Devyldere, Hannah, Ercius, Peter, Zettl, Alex, Scott, Mary C, and Ophus, Colin

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science, Physics - Instrumentation and Detectors

Abstract

Transmission electron microscopy (TEM) is a potent technique for the determination of three-dimensional atomic scale structure of samples in structural biology and materials science. In structural biology, three-dimensional structures of proteins are routinely determined using phase-contrast single-particle cryo-electron microscopy from thousands of identical proteins, and reconstructions have reached atomic resolution for specific proteins. In materials science, three-dimensional atomic structures of complex nanomaterials have been determined using a combination of annular dark field (ADF) scanning transmission electron microscopic (STEM) tomography and subpixel localization of atomic peaks, in a method termed atomic electron tomography (AET). However, neither of these methods can determine the three-dimensional atomic structure of heterogeneous nanomaterials containing light elements. Here, we perform mixed-state electron ptychography from 34.5 million diffraction patterns to reconstruct a high-resolution tilt series of a double wall-carbon nanotube (DW-CNT), encapsulating a complex $\mathrm{ZrTe}$ sandwich structure. Class averaging of the resulting reconstructions and subpixel localization of the atomic peaks in the reconstructed volume reveals the complex three-dimensional atomic structure of the core-shell heterostructure with 17 picometer precision. From these measurements, we solve the full $\mathrm{Zr_{11}Te_{50}}$ structure, which contains a previously unobserved $\mathrm{ZrTe_{2}}$ phase in the core. The experimental realization of ptychographic atomic electron tomography (PAET) will allow for structural determination of a wide range of nanomaterials which are beam-sensitive or contain light elements., Comment: 17 pages 3 figures in main text, 7 figures in supplementary materials

Published

2022

30. Observation of hydrodynamic plasmons and energy waves in graphene

Author

Zhao, Wenyu, Wang, Shaoxin, Chen, Sudi, Zhang, Zuocheng, Watanabe, Kenji, Taniguchi, Takashi, Zettl, Alex, and Wang, Feng

Subjects

Maritime Engineering, Engineering, Physical Sciences, Condensed Matter Physics, Affordable and Clean Energy, General Science & Technology

Abstract

Thermally excited electrons and holes form a quantum-critical Dirac fluid in ultraclean graphene and their electrodynamic responses are described by a universal hydrodynamic theory. The hydrodynamic Dirac fluid can host intriguing collective excitations distinctively different from those in a Fermi liquid1-4. Here we report the observation of the hydrodynamic plasmon and energy wave in ultraclean graphene. We use the on-chip terahertz (THz) spectroscopy technique to measure the THz absorption spectra of a graphene microribbon as well as the propagation of the energy wave in graphene close to charge neutrality. We observe a prominent high-frequency hydrodynamic bipolar-plasmon resonance and a weaker low-frequency energy-wave resonance of the Dirac fluid in ultraclean graphene. The hydrodynamic bipolar plasmon is characterized by the antiphase oscillation of massless electrons and holes in graphene. The hydrodynamic energy wave is an electron-hole sound mode with both charge carriers oscillating in phase and moving together. The spatial-temporal imaging technique shows that the energy wave propagates at a characteristic speed of [Formula: see text] near the charge neutrality2-4. Our observations open new opportunities to explore collective hydrodynamic excitations in graphene systems.

Published

2023

31. Deep-Learning Electron Diffractive Imaging

Author

Chang, Dillan J, O'Leary, Colum M, Su, Cong, Jacobs, Daniel A, Kahn, Salman, Zettl, Alex, Ciston, Jim, Ercius, Peter, and Miao, Jianwei

Subjects

Physical Sciences, Condensed Matter Physics, Bioengineering, Deep Learning, Electrons, Gold, Metal Nanoparticles, Neural Networks, Computer, Algorithms, Mathematical Sciences, Engineering, General Physics, Mathematical sciences, Physical sciences

Abstract

We report the development of deep-learning coherent electron diffractive imaging at subangstrom resolution using convolutional neural networks (CNNs) trained with only simulated data. We experimentally demonstrate this method by applying the trained CNNs to recover the phase images from electron diffraction patterns of twisted hexagonal boron nitride, monolayer graphene, and a gold nanoparticle with comparable quality to those reconstructed by a conventional ptychographic algorithm. Fourier ring correlation between the CNN and ptychographic images indicates the achievement of a resolution in the range of 0.70 and 0.55 Å. We further develop CNNs to recover the probe function from the experimental data. The ability to replace iterative algorithms with CNNs and perform real-time atomic imaging from coherent diffraction patterns is expected to find applications in the physical and biological sciences.

Published

2023

32. Enhanced ZIF-8-enabled colorimetric CO2 sensing through dye-precursor synthesis

Author

Davey, Adrian K, Li, Zhou, Lefton, Natalie, Leonhardt, Branden E, Pourghaderi, Alireza, McElhany, Stuart, Popple, Derek, Dai, Chunhui, Kahn, Salman, Dods, Matthew N, Zettl, Alex, Carraro, Carlo, and Maboudian, Roya

Subjects

Inorganic Chemistry, Chemical Sciences, Indoor air quality, Volatile organic compound, in-situ ultraviolet-visible (UV-Vis) spectroscopy, Dye-precursor synthesis, MSD-General, MSD-Functional Nanomachines, MSD-VdW Heterostructures, Optical Physics, Analytical Chemistry, Materials Engineering, Analytical chemistry, Chemical engineering, Materials engineering

Abstract

The accumulation of carbon dioxide (CO2) within enclosed spaces, along with volatile organic compounds, under certain humidity, temperature, and ventilation conditions is associated with detrimental human health symptoms such as fatigue. Color-based chemical sensing is a promising approach to detect CO2 levels relevant to indoor air quality through producing fast, quantifiable output visible to the naked eye. In a prior work, a colorimetric gas sensor was fabricated through synthesizing the metal-organic framework, ZIF-8, as the adsorbent, followed by post-synthetic mixing with a dye, phenol red (PSP), and primary amine, ethylenediamine (ED). While this sensor (termed PSP-ED/ZIF-8) maintained its structural integrity in atmospheric conditions and exhibited an increasing fuchsia-to-yellow color change with increasing CO2 levels in dry environment, the colorimetric response greatly suffered in the presence of humid CO2. In this work, a significantly improved colorimetric CO2 sensor (referred to as ED/PSP:ZIF-8) is accomplished through directly incorporating phenol red in the ZIF-8 metal and linker precursor solutions and then blending with ethylenediamine. MATLAB-generated color distributions and in-situ ultraviolet-visible (UV-Vis) spectroscopic studies quantitatively demonstrate an enhanced colorimetric gas response of ED/PSP:ZIF-8 compared to that of PSP-ED/ZIF-8 across an important range of CO2 for indoor air quality monitoring (500 – 3500 ppm) and across a range of humidity. The new sensor also exhibits high selectivity to CO2 compared to select volatile organic compounds, such as acetone and ethanol, which contribute to human health symptoms experienced indoors. The enhanced performance is attributed to the proposed incorporation of phenol red within ZIF-8, while maintaining the chemical stability of the MOF.

Published

2023

33. Solving complex nanostructures with ptychographic atomic electron tomography

Author

Pelz, Philipp M, Griffin, Sinéad M, Stonemeyer, Scott, Popple, Derek, DeVyldere, Hannah, Ercius, Peter, Zettl, Alex, Scott, Mary C, and Ophus, Colin

Subjects

Chemical Sciences, Engineering, Physical Sciences, Nanotechnology, Condensed Matter Physics, Bioengineering, Generic health relevance

Abstract

Transmission electron microscopy (TEM) is essential for determining atomic scale structures in structural biology and materials science. In structural biology, three-dimensional structures of proteins are routinely determined from thousands of identical particles using phase-contrast TEM. In materials science, three-dimensional atomic structures of complex nanomaterials have been determined using atomic electron tomography (AET). However, neither of these methods can determine the three-dimensional atomic structure of heterogeneous nanomaterials containing light elements. Here, we perform ptychographic electron tomography from 34.5 million diffraction patterns to reconstruct an atomic resolution tilt series of a double wall-carbon nanotube (DW-CNT) encapsulating a complex ZrTe sandwich structure. Class averaging the resulting tilt series images and subpixel localization of the atomic peaks reveals a Zr11Te50 structure containing a previously unobserved ZrTe2 phase in the core. The experimental realization of atomic resolution ptychographic electron tomography will allow for the structural determination of a wide range of beam-sensitive nanomaterials containing light elements.

Published

2023

34. Imaging the electron charge density in monolayer MoS2 at the Ångstrom scale

Author

Martis, Joel, Susarla, Sandhya, Rayabharam, Archith, Su, Cong, Paule, Timothy, Pelz, Philipp, Huff, Cassandra, Xu, Xintong, Li, Hao-Kun, Jaikissoon, Marc, Chen, Victoria, Pop, Eric, Saraswat, Krishna, Zettl, Alex, Aluru, Narayana R, Ramesh, Ramamoorthy, Ercius, Peter, and Majumdar, Arun

Subjects

Physical Sciences, Condensed Matter Physics, Bioengineering, MSD-General, MSD-Functional Nanomachines, MSD-Quantum Materials, MSD-VdW Heterostructures

Abstract

Four-dimensional scanning transmission electron microscopy (4D-STEM) has recently gained widespread attention for its ability to image atomic electric fields with sub-Ångstrom spatial resolution. These electric field maps represent the integrated effect of the nucleus, core electrons and valence electrons, and separating their contributions is non-trivial. In this paper, we utilized simultaneously acquired 4D-STEM center of mass (CoM) images and annular dark field (ADF) images to determine the projected electron charge density in monolayer MoS2. We evaluate the contributions of both the core electrons and the valence electrons to the derived electron charge density; however, due to blurring by the probe shape, the valence electron contribution forms a nearly featureless background while most of the spatial modulation comes from the core electrons. Our findings highlight the importance of probe shape in interpreting charge densities derived from 4D-STEM and the need for smaller electron probes.

Published

2023

35. Evolution of nanopores in hexagonal boron nitride

Author

Dai, Chunhui, Popple, Derek, Su, Cong, Park, Ji-Hoon, Watanabe, Kenji, Taniguchi, Takashi, Kong, Jing, and Zettl, Alex

Subjects

Chemical Sciences, Chemical sciences

Abstract

The engineering of atomically-precise nanopores in two-dimensional materials presents exciting opportunities for both fundamental science studies as well as applications in energy, DNA sequencing, and quantum information technologies. The exceptional chemical and thermal stability of hexagonal boron nitride (h-BN) suggest that exposed h-BN nanopores will retain their atomic structure even when subjected to extended periods of time in gas or liquid environments. Here we employ transmission electron microscopy to examine the time evolution of h-BN nanopores in vacuum and in air and find, even at room temperature, dramatic geometry changes due to atom motion and edge contamination adsorption, for timescales ranging from one hour to one week. The discovery of nanopore evolution contrasts with general expectations and has profound implications for nanopore applications of two-dimensional materials.

Published

2023

36. Local spectroscopy of a gate-switchable moiré quantum anomalous Hall insulator

Author

Zhang, Canxun, Zhu, Tiancong, Soejima, Tomohiro, Kahn, Salman, Watanabe, Kenji, Taniguchi, Takashi, Zettl, Alex, Wang, Feng, Zaletel, Michael P, and Crommie, Michael F

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, Spectrum Analysis, Electrons, Graphite, Magnetic Fields, Microscopy, Scanning Tunneling

Abstract

In recent years, correlated insulating states, unconventional superconductivity, and topologically non-trivial phases have all been observed in several moiré heterostructures. However, understanding of the physical mechanisms behind these phenomena is hampered by the lack of local electronic structure data. Here, we use scanning tunnelling microscopy and spectroscopy to demonstrate how the interplay between correlation, topology, and local atomic structure determines the behaviour of electron-doped twisted monolayer-bilayer graphene. Through gate- and magnetic field-dependent measurements, we observe local spectroscopic signatures indicating a quantum anomalous Hall insulating state with a total Chern number of ±2 at a doping level of three electrons per moiré unit cell. We show that the sign of the Chern number and associated magnetism can be electrostatically switched only over a limited range of twist angle and sample hetero-strain values. This results from a competition between the orbital magnetization of filled bulk bands and chiral edge states, which is sensitive to strain-induced distortions in the moiré superlattice.

Published

2023

37. Charge-induced phase transition in encapsulated HfTe2 nanoribbons

Author

Popple, Derek, Dogan, Mehmet, Hoang, Tony Vo, Stonemeyer, Scott, Ercius, Peter, Bustillo, Karen C, Cohen, Marvin, and Zettl, Alex

Subjects

Physical Sciences, Engineering, Nanotechnology, Ferrari, Lamborghini, MSD-General, MSD-Theory, MSD-VdW Heterostructures, Macromolecular and materials chemistry, Materials engineering, Condensed matter physics

Abstract

Nanotube encapsulation is a powerful technique for coaxing solids into unconventional configurations. By synthesizing materials within the interior confines of hollow nanotubes, lower dimensional morphologies, such as one-dimensional chains or nanoribbons, are favored. We have used carbon nanotube encapsulation to realize ultranarrow, atomically precise HfTe2 nanoribbons. A local, electron-beam-stimulated transition from the metallic 1T phase to the previously unreported semiconducting 1H phase is observed. We study computationally how charging can drive the phase transition and the stability of the different atomic configurations.

Published

2023

38. Observation of a multitude of correlated states at the surface of bulk 1T-TaSe$_2$ crystals

Author

Chen, Yi, Ruan, Wei, Cain, Jeffrey D., Lee, Ryan L., Kahn, Salman, Jia, Caihong, Zettl, Alex, and Crommie, Michael F.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

The interplay between electron-electron interactions and structural ordering can yield exceptionally rich correlated electronic phases. We have used scanning tunneling microscopy to investigate bulk 1T-TaSe2 and have uncovered surprisingly diverse correlated surface states thereof. These surface states exhibit the same in-plane charge density wave ordering but dramatically different electronic ground states ranging from insulating to metallic. The insulating variety of surface state shows signatures of a decoupled surface Mott layer. The metallic surface states, on the other hand, exhibit zero-bias peaks of varying strength that suggest Kondo phases arising from coupling between the Mott surface layer and the metallic bulk of 1T-TaSe2. The surface of bulk 1T-TaSe2 thus constitutes a rare realization of the periodic Anderson model covering a wide parameter regime, thereby providing a model system for accessing different correlated phenomena in the same crystal. Our results highlight the central role played by strong correlations in this material family.

Published

2022

39. Deep Learning Coherent Diffractive Imaging

Author

Chang, Dillan J., O'Leary, Colum M., Su, Cong, Kahn, Salman, Zettl, Alex, Ciston, Jim, Ercius, Peter, and Miao, Jianwei

Subjects

Condensed Matter - Materials Science

Abstract

We report the development of deep learning coherent electron diffractive imaging at sub-angstrom resolution using convolutional neural networks (CNNs) trained with only simulated data. We experimentally demonstrate this method by applying the trained CNNs to directly recover the phase images from electron diffraction patterns of twisted hexagonal boron nitride, monolayer graphene and a Au nanoparticle with comparable quality to those reconstructed by a conventional ptychographic method. Fourier ring correlation between the CNN and ptychographic images indicates the achievement of a spatial resolution in the range of 0.70 and 0.55 angstrom (depending on different resolution criteria). The ability to replace iterative algorithms with CNNs and perform real-time imaging from coherent diffraction patterns is expected to find broad applications in the physical and biological sciences., Comment: 19 pages, 7 figures

Published

2022

40. Correlated interlayer exciton insulator in heterostructures of monolayer WSe2 and moiré WS2/WSe2

Author

Zhang, Zuocheng, Regan, Emma C, Wang, Danqing, Zhao, Wenyu, Wang, Shaoxin, Sayyad, Mohammed, Yumigeta, Kentaro, Watanabe, Kenji, Taniguchi, Takashi, Tongay, Sefaattin, Crommie, Michael, Zettl, Alex, Zaletel, Michael P, and Wang, Feng

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, MSD-General, MSD-VdW Heterostructures, Mathematical Sciences, Fluids & Plasmas, Mathematical sciences, Physical sciences

Abstract

Moiré superlattices in van der Waals heterostructures have emerged as a powerful tool for engineering quantum phenomena. Here we report the observation of a correlated interlayer exciton insulator in a double-layer heterostructure composed of a WSe2 monolayer and a WS2/WSe2 moiré bilayer that are separated by ultrathin hexagonal boron nitride. The moiré WS2/WSe2 bilayer features a Mott insulator state when the density of holes is one per moiré lattice site. When electrons are added to the Mott insulator in the WS2/WSe2 moiré bilayer and an equal number of holes are injected into the WSe2 monolayer, a new interlayer exciton insulator emerges with the holes in the WSe2 monolayer and the electrons in the doped Mott insulator bound together through interlayer Coulomb interactions. The interlayer exciton insulator is stable up to a critical hole density in the WSe2 monolayer, beyond which the interlayer exciton dissociates. Our study highlights the opportunities for realizing quantum phases in double-layer moiré systems due to the interplay between the moiré flat band and strong interlayer electron interactions.

Published

2022

41. A laser-assisted chlorination process for reversible writing of doping patterns in graphene

Author

Rho, Yoonsoo, Lee, Kyunghoon, Wang, Letian, Ko, Changhyun, Chen, Yabin, Ci, Penghong, Pei, Jiayun, Zettl, Alex, Wu, Junqiao, and Grigoropoulos, Costas P

Subjects

Engineering, Electrical Engineering, Electronics, Sensors and Digital Hardware, Electrical engineering, Electronics, sensors and digital hardware

Abstract

Chemical doping can be used to control the charge-carrier polarity and concentration in two-dimensional van der Waals materials. However, conventional methods based on substitutional doping or surface functionalization result in the degradation of electrical mobility due to structural disorder, and the maximum doping density is set by the solubility limit of dopants. Here we show that a reversible laser-assisted chlorination process can be used to create high doping concentrations (above 3 × 1013 cm−2) in graphene monolayers with minimal drops in mobility. The approach uses two lasers—with distinct photon energies and geometric configurations—that are designed for chlorination and subsequent chlorine removal, allowing highly doped patterns to be written and erased without damaging the graphene. To illustrate the capabilities of our approach, we use it to create rewritable photoactive junctions for graphene-based photodetectors.

Published

2022

42. Tuning colour centres at a twisted hexagonal boron nitride interface

Author

Su, Cong, Zhang, Fang, Kahn, Salman, Shevitski, Brian, Jiang, Jingwei, Dai, Chunhui, Ungar, Alex, Park, Ji-Hoon, Watanabe, Kenji, Taniguchi, Takashi, Kong, Jing, Tang, Zikang, Zhang, Wenqing, Wang, Feng, Crommie, Michael, Louie, Steven G, Aloni, Shaul, and Zettl, Alex

Subjects

Quantum Physics, Physical Sciences, Condensed Matter Physics, Boron Compounds, Color, Ferrari, Lamborghini, Aston Martin, Nanoscience & Nanotechnology

Abstract

The colour centre platform holds promise for quantum technologies, and hexagonal boron nitride has attracted attention due to the high brightness and stability, optically addressable spin states and wide wavelength coverage discovered in its emitters. However, its application is hindered by the typically random defect distribution and complex mesoscopic environment. Here, employing cathodoluminescence, we demonstrate on-demand activation and control of colour centre emission at the twisted interface of two hexagonal boron nitride flakes. Further, we show that colour centre emission brightness can be enhanced by two orders of magnitude by tuning the twist angle. Additionally, by applying an external voltage, nearly 100% brightness modulation is achieved. Our ab initio GW and GW plus Bethe-Salpeter equation calculations suggest that the emission is correlated to nitrogen vacancies and that a twist-induced moiré potential facilitates electron-hole recombination. This mechanism is further exploited to draw nanoscale colour centre patterns using electron beams.

Published

2022

43. Kirigami Engineering of Suspended Graphene Transducers

Author

Dai, Chunhui, Rho, Yoonsoo, Pham, Khanh, McCormick, Brady, Blankenship, Brian W, Zhao, Wenyu, Zhang, Zuocheng, Gilbert, S Matt, Crommie, Michael F, Wang, Feng, Grigoropoulos, Costas P, and Zettl, Alex

Subjects

Engineering, Physical Sciences, Condensed Matter Physics, Affordable and Clean Energy, Equipment Design, Graphite, Transducers, Vibration, graphene kirigami, graphene NEMS, acoustic transducer, MSD-General, MSD-Functional Nanomachines, Nanoscience & Nanotechnology

Abstract

The low mass density and high mechanical strength of graphene make it an attractive candidate for suspended-membrane energy transducers. Typically, the membrane size dictates the operational frequency and bandwidth. However, in many cases it would be desirable to both lower the resonance frequency and increase the bandwidth, while maintaining overall membrane size. We employ focused ion beam milling or laser ablation to create kirigami-like modification of suspended pure-graphene membranes ranging in size from microns to millimeters. Kirigami engineering successfully reduces the resonant frequency, increases the displacement amplitude, and broadens the effective bandwidth of the transducer. Our results present a promising route to miniaturized wide-band energy transducers with enhanced operational parameter range and efficiency.

Published

2022

44. Beam-driven dynamics of aluminium dopants in graphene

Author

Zagler, Georg, Stecher, Maximilian, Trentino, Alberto, Kraft, Fabian, Su, Cong, Postl, Andreas, Längle, Manuel, Pesenhofer, Christian, Mangler, Clemens, Åhlgren, E Harriet, Markevich, Alexander, Zettl, Alex, Kotakoski, Jani, Susi, Toma, and Mustonen, Kimmo

Subjects

Physical Sciences, Condensed Matter Physics, scanning transmission electron microscopy, atomic dynamics, heteroatom doping, Ferrari, Aston Martin, Macromolecular and Materials Chemistry, Materials Engineering, Nanotechnology, Materials engineering, Condensed matter physics

Abstract

Substituting heteroatoms into graphene can tune its properties for applications ranging from catalysis to spintronics. The further recent discovery that covalent impurities in graphene can be manipulated at atomic precision using a focused electron beam may open avenues towards sub-nanometer device architectures. However, the preparation of clean samples with a high density of dopants is still very challenging. Here, we report vacancy-mediated substitution of aluminium into laser-cleaned graphene, and without removal from our ultra-high vacuum apparatus, study their dynamics under 60 keV electron irradiation using aberration-corrected scanning transmission electron microscopy and spectroscopy. Three- and four-coordinated Al sites are identified, showing excellent agreement with ab initio predictions including binding energies and electron energy-loss spectrum simulations. We show that the direct exchange of carbon and aluminium atoms predicted earlier occurs under electron irradiation, although unexpectedly it is less probable than the same process for silicon. We also observe a previously unknown nitrogen-aluminium exchange that occurs at Al─N double-dopant sites at graphene divacancies created by our plasma treatment.

Published

2022

45. Imaging gate-tunable Tomonaga–Luttinger liquids in 1H-MoSe2 mirror twin boundaries

Author

Zhu, Tiancong, Ruan, Wei, Wang, Yan-Qi, Tsai, Hsin-Zon, Wang, Shuopei, Zhang, Canxun, Wang, Tianye, Liou, Franklin, Watanabe, Kenji, Taniguchi, Takashi, Neaton, Jeffrey B, Weber-Bargioni, Alexander, Zettl, Alex, Qiu, ZQ, Zhang, Guangyu, Wang, Feng, Moore, Joel E, and Crommie, Michael F

Subjects

Engineering, Physical Sciences, Condensed Matter Physics, MSD-General, MSD-NPQC, Nanoscience & Nanotechnology

Abstract

One-dimensional electron systems exhibit fundamentally different properties than higher-dimensional systems. For example, electron-electron interactions in one-dimensional electron systems have been predicted to induce Tomonaga-Luttinger liquid behaviour. Naturally occurring grain boundaries in single-layer transition metal dichalcogenides exhibit one-dimensional conducting channels that have been proposed to host Tomonaga-Luttinger liquids, but charge density wave physics has also been suggested to explain their behaviour. Clear identification of the electronic ground state of this system has been hampered by an inability to electrostatically gate such boundaries and tune their charge carrier concentration. Here we present a scanning tunnelling microscopy and spectroscopy study of gate-tunable mirror twin boundaries in single-layer 1H-MoSe2 devices. Gating enables scanning tunnelling microscopy and spectroscopy for different mirror twin boundary electron densities, thus allowing precise characterization of electron-electron interaction effects. Visualization of the resulting mirror twin boundary electronic structure allows unambiguous identification of collective density wave excitations having two velocities, in quantitative agreement with the spin-charge separation predicted by finite-length Tomonaga-Luttinger liquid theory.

Published

2022

46. Imaging reconfigurable molecular concentration on a graphene field-effect transistor

Author

Liou, Franklin, Tsai, Hsin-Zon, Aikawa, Andrew S., Natividad, Kyler C., Tang, Eric, Ha, Ethan, Riss, Alexander, Watanabe, Kenji, Taniguchi, Takashi, Lischner, Johannes, Zettl, Alex, and Crommie, Michael F.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The spatial arrangement of adsorbates deposited onto a clean surface in vacuum typically cannot be reversibly tuned. Here we use scanning tunneling microscopy to demonstrate that molecules deposited onto graphene field-effect transistors exhibit reversible, electrically-tunable surface concentration. Continuous gate-tunable control over the surface concentration of charged F4TCNQ molecules was achieved on a graphene FET at T = 4.5K. This capability enables precisely controlled impurity doping of graphene devices and also provides a new method for determining molecular energy level alignment based on the gate-dependence of molecular concentration. The gate-tunable molecular concentration can be explained by a dynamical molecular rearrangement process that reduces total electronic energy by maintaining Fermi level pinning in the device substrate. Molecular surface concentration in this case is fully determined by the device back-gate voltage, its geometric capacitance, and the energy difference between the graphene Dirac point and the molecular LUMO level.

Published

2021

47. Deep Learning Coherent Diffractive Imaging

Author

Chang, Dillan J, O'Leary, Colum M, Su, Cong, Kahn, Salman, Zettl, Alex, Ciston, Jim, Ercius, Peter, and Miao, Jianwei

Subjects

cond-mat.mtrl-sci

Abstract

We report the development of deep learning coherent electron diffractiveimaging at sub-angstrom resolution using convolutional neural networks (CNNs)trained with only simulated data. We experimentally demonstrate this method byapplying the trained CNNs to directly recover the phase images from electrondiffraction patterns of twisted hexagonal boron nitride, monolayer graphene anda Au nanoparticle with comparable quality to those reconstructed by aconventional ptychographic method. Fourier ring correlation between the CNN andptychographic images indicates the achievement of a spatial resolution in therange of 0.70 and 0.55 angstrom (depending on different resolution criteria).The ability to replace iterative algorithms with CNNs and perform real-timeimaging from coherent diffraction patterns is expected to find broadapplications in the physical and biological sciences.

Published

2022

48. Response to Comment on “Reversible disorder-order transitions in atomic crystal nucleation”

Author

Jeon, Sungho, Hwang, Sang-Yeon, Ciston, Jim, Bustillo, Karen C, Reed, Bryan W, Hong, Sukjoon, Zettl, Alex, Kim, Woo Youn, Ercius, Peter, Park, Jungwon, and Lee, Won Chul

Subjects

Chemical Sciences, Physical Sciences, Theoretical and Computational Chemistry, 1.1 Normal biological development and functioning, General Science & Technology

Abstract

Yu et al. suggested calculating precisely the size ranges of the three parts of our figure 3A, adjusting the free-energy levels in figure 3B, and considering the shape effect in the first-principles calculation. The first and second suggestions raise strong concerns for misinterpretation and overinterpretation of our experiments. The original calculation is sufficient to support our claim about crystalline-to-disordered transformations.

Published

2022

49. Targeting One- and Two-Dimensional Ta–Te Structures via Nanotube Encapsulation

Author

Stonemeyer, Scott, Dogan, Mehmet, Cain, Jeffrey D, Azizi, Amin, Popple, Derek C, Culp, Austin, Song, Chengyu, Ercius, Peter, Cohen, Marvin L, and Zettl, Alex

Subjects

Physical Sciences, Engineering, Nanotechnology, Condensed Matter Physics, Electronics, Nanotubes, Carbon, One-dimensional materials, two-dimensional materials, nanoribbons, transition metal dichalcogenides, scanning transmission electron microscopy, nanotubes, Nanoscience & Nanotechnology

Abstract

Fine control over material synthesis on the nanoscale can facilitate the stabilization of competing crystalline structures. Here, we demonstrate how carbon nanotube reaction vessels can be used to selectively create one-dimensional TaTe3 chains or two-dimensional TaTe2 nanoribbons with exquisite control of the chain number or nanoribbon thickness and width. Transmission electron microscopy and scanning transmission electron microscopy reveal the detailed atomic structure of the encapsulated materials. Complex superstructures such as multichain spiraling and apparent multilayer moirés are observed. The rare 2H phase of TaTe2 (1H in monolayer) is found to be abundant as an encapsulated nanoribbon inside carbon nanotubes. The experimental results are complemented by density functional theory calculations for the atomic and electronic structure, which uncovers the prevalence of 2H-TaTe2 due to nanotube-to-nanoribbon charge transfer and size confinement. Calculations also reveal new 1T' type charge density wave phases in TaTe2 that could be observed in experimental studies.

Published

2022

50. Correlated interlayer exciton insulator in double layers of monolayer WSe2 and moir\'e WS2/WSe2

Author

Zhang, Zuocheng, Regan, Emma C., Wang, Danqing, Zhao, Wenyu, Wang, Shaoxin, Sayyad, Mohammed, Yumigeta, Kentaro, Watanabe, Kenji, Taniguchi, Takashi, Tongay, Sefaattin, Crommie, Michael, Zettl, Alex, Zaletel, Michael P., and Wang, Feng

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Moir\'e superlattices in van der Waals heterostructures have emerged as a powerful tool for engineering novel quantum phenomena. Here we report the observation of a correlated interlayer exciton insulator in a double-layer heterostructure composed of a WSe2 monolayer and a WS2/WSe2 moir\'e bilayer that are separated by an ultrathin hexagonal boron nitride (hBN). The moir\'e WS2/WSe2 bilayer features a Mott insulator state at hole density p/p0 = 1, where p0 corresponds to one hole per moir\'e lattice site. When electrons are added to the Mott insulator in the WS2/WSe2 moir\'e bilayer and an equal number of holes are injected into the WSe2 monolayer, a new interlayer exciton insulator emerges with the holes in the WSe2 monolayer and the electrons in the doped Mott insulator bound together through interlayer Coulomb interactions. The excitonic insulator is stable up to a critical hole density of ~ 0.5p0 in the WSe2 monolayer, beyond which the system becomes metallic. Our study highlights the opportunities for realizing novel quantum phases in double-layer moir\'e systems due to the interplay between the moir\'e flat band and strong interlayer electron interactions.

Published

2021