Your search keyword '"Kis, Andras"' showing total 43 results

1. Deterministic grayscale nanotopography to engineer mobilities in strained MoS2 FETs.

Author

Liu, Xia, Erbas, Berke, Conde-Rubio, Ana, Rivano, Norma, Wang, Zhenyu, Jiang, Jin, Bienz, Siiri, Kumar, Naresh, Sohier, Thibault, Penedo, Marcos, Banerjee, Mitali, Fantner, Georg, Zenobi, Renato, Marzari, Nicola, Kis, Andras, Boero, Giovanni, and Brugger, Juergen

Subjects

VAN der Waals forces, DIELECTRIC materials, FIELD-effect transistors, GRAYSCALE model, TRANSISTORS

Abstract

Field-effect transistors (FETs) based on two-dimensional materials (2DMs) with atomically thin channels have emerged as a promising platform for beyond-silicon electronics. However, low carrier mobility in 2DM transistors driven by phonon scattering remains a critical challenge. To address this issue, we propose the controlled introduction of localized tensile strain as an effective means to inhibit electron-phonon scattering in 2DM. Strain is achieved by conformally adhering the 2DM via van der Waals forces to a dielectric layer previously nanoengineered with a gray-tone topography. Our results show that monolayer MoS2 FETs under tensile strain achieve an 8-fold increase in on-state current, reaching mobilities of 185 cm²/Vs at room temperature, in good agreement with theoretical calculations. The present work on nanotopographic grayscale surface engineering and the use of high-quality dielectric materials has the potential to find application in the nanofabrication of photonic and nanoelectronic devices. Improving the performance of 2D transistors is essential to enable their future application for beyond-silicon electronics. Here, the authors report a method to induce localized tensile strain in monolayer MoS2 transistors, leading to enhanced electron mobilities up to 185 cm2/Vs and an 8-fold increase of the on-state current densities. [ABSTRACT FROM AUTHOR]

Published

2024

2. Combining thermal scanning probe lithography and dry etching for grayscale nanopattern amplification

Author

European Research Council, European Commission, Swiss National Science Foundation, Agencia Estatal de Investigación (España), Erbas, Berke [0000-0002-6977-7227], Liu, Xia [0000-0003-1886-6825], Bertsch, Arnaud [0000-0002-1044-0478], Penedo, Marcos [0000-0002-2936-7354], Fantner, Georg [0000-0001-5889-3022], Brugger, Juergen [0000-0002-7710-5930], Erbas, Berke, Conde Rubio, Ana, Liu, Xia, Pernollet, Joffrey, Wang, Zhenyu, Bertsch, Arnaud, Penedo, Marcos, Fantner, Georg, Banerjee, Mitali, Kis, Andras, Boero, Giovanni, Brugger, Juergen, European Research Council, European Commission, Swiss National Science Foundation, Agencia Estatal de Investigación (España), Erbas, Berke [0000-0002-6977-7227], Liu, Xia [0000-0003-1886-6825], Bertsch, Arnaud [0000-0002-1044-0478], Penedo, Marcos [0000-0002-2936-7354], Fantner, Georg [0000-0001-5889-3022], Brugger, Juergen [0000-0002-7710-5930], Erbas, Berke, Conde Rubio, Ana, Liu, Xia, Pernollet, Joffrey, Wang, Zhenyu, Bertsch, Arnaud, Penedo, Marcos, Fantner, Georg, Banerjee, Mitali, Kis, Andras, Boero, Giovanni, and Brugger, Juergen

Abstract

Grayscale structured surfaces with nanometer-scale features are used in a growing number of applications in optics and fluidics. Thermal scanning probe lithography achieves a lateral resolution below 10 nm and a vertical resolution below 1 nm, but its maximum depth in polymers is limited. Here, we present an innovative combination of nanowriting in thermal resist and plasma dry etching with substrate cooling, which achieves up to 10-fold amplification of polymer nanopatterns into SiO2 without proportionally increasing surface roughness. Sinusoidal nanopatterns in SiO2 with 400 nm pitch and 150 nm depth are fabricated free of shape distortion after dry etching. To exemplify the possible applications of the proposed method, grayscale dielectric nanostructures are used for scalable manufacturing through nanoimprint lithography and for strain nanoengineering of 2D materials. Such a method for aspect ratio amplification and smooth grayscale nanopatterning has the potential to find application in the fabrication of photonic and nanoelectronic devices.

Published

2024

3. CVD graphene contacts for lateral heterostructure MoS2 field effect transistors.

Author

Schneider, Daniel S., Lucchesi, Leonardo, Reato, Eros, Wang, Zhenyu, Piacentini, Agata, Bolten, Jens, Marian, Damiano, Marin, Enrique G., Radenovic, Aleksandra, Wang, Zhenxing, Fiori, Gianluca, Kis, Andras, Iannaccone, Giuseppe, Neumaier, Daniel, and Lemme, Max C.

Subjects

FIELD-effect transistors, SCHOTTKY barrier, GRAPHENE, LOGIC circuits, FUTURE (Logic), OHMIC contacts, TRANSISTORS

Abstract

Intensive research has been carried out on two-dimensional materials, in particular molybdenum disulfide, towards high-performance field effect transistors for integrated circuits1. Fabricating transistors with ohmic contacts is a challenging task due to the formation of a high Schottky barrier that severely limits the performance of the transistors for real-world applications. Graphene-based heterostructures can be used in addition to, or as a substitute for unsuitable metals. In this paper, we present lateral heterostructure transistors made of scalable chemical vapor-deposited molybdenum disulfide and chemical vapor-deposited graphene achieving a low contact resistances of about 9 kΩ·µm and high on/off current ratios of 108. Furthermore, we also present a theoretical model calibrated on our experiments showing further potential for scaling transistors and contact areas into the few nanometers range and the possibility of a substantial performance enhancement by means of layer optimizations that would make transistors promising for use in future logic integrated circuits. [ABSTRACT FROM AUTHOR]

Published

2024

4. Nanofluidic logic with mechano–ionic memristive switches.

Author

Emmerich, Theo, Teng, Yunfei, Ronceray, Nathan, Lopriore, Edoardo, Chiesa, Riccardo, Chernev, Andrey, Artemov, Vasily, Di Ventra, Massimiliano, Kis, Andras, and Radenovic, Aleksandra

Published

2024

5. Combining thermal scanning probe lithography and dry etching for grayscale nanopattern amplification.

Author

Erbas, Berke, Conde-Rubio, Ana, Liu, Xia, Pernollet, Joffrey, Wang, Zhenyu, Bertsch, Arnaud, Penedo, Marcos, Fantner, Georg, Banerjee, Mitali, Kis, Andras, Boero, Giovanni, and Brugger, Juergen

Subjects

PLASMA etching, GRAYSCALE model, NANOIMPRINT lithography, LITHOGRAPHY, THERMAL plasmas

Abstract

Grayscale structured surfaces with nanometer-scale features are used in a growing number of applications in optics and fluidics. Thermal scanning probe lithography achieves a lateral resolution below 10 nm and a vertical resolution below 1 nm, but its maximum depth in polymers is limited. Here, we present an innovative combination of nanowriting in thermal resist and plasma dry etching with substrate cooling, which achieves up to 10-fold amplification of polymer nanopatterns into SiO2 without proportionally increasing surface roughness. Sinusoidal nanopatterns in SiO2 with 400 nm pitch and 150 nm depth are fabricated free of shape distortion after dry etching. To exemplify the possible applications of the proposed method, grayscale dielectric nanostructures are used for scalable manufacturing through nanoimprint lithography and for strain nanoengineering of 2D materials. Such a method for aspect ratio amplification and smooth grayscale nanopatterning has the potential to find application in the fabrication of photonic and nanoelectronic devices. [ABSTRACT FROM AUTHOR]

Published

2024

6. A large-scale integrated vector–matrix multiplication processor based on monolayer molybdenum disulfide memories.

Author

Migliato Marega, Guilherme, Ji, Hyun Goo, Wang, Zhenyu, Pasquale, Gabriele, Tripathi, Mukesh, Radenovic, Aleksandra, and Kis, Andras

Published

2023

7. Disorder-induced bulk photovoltaic effect in a centrosymmetric van der Waals material.

Author

Cheon, Cheol-Yeon, Sun, Zhe, Cao, Jiang, Gonzalez Marin, Juan Francisco, Tripathi, Mukesh, Watanabe, Kenji, Taniguchi, Takashi, Luisier, Mathieu, and Kis, Andras

Subjects

PHOTOVOLTAIC effect, PHOTOCONDUCTIVITY, PHOTOVOLTAIC cells, RENEWABLE energy sources, ELECTRIC fields

Abstract

Sunlight is widely seen as one of the most abundant forms of renewable energy, with photovoltaic cells based on pn junctions being the most commonly used platform attempting to harness it. Unlike in conventional photovoltaic cells, the bulk photovoltaic effect (BPVE) allows for the generation of photocurrent and photovoltage in a single material without the need to engineer a pn junction and create a built-in electric field, thus offering a solution that can potentially exceed the Shockley–Queisser efficiency limit. However, it requires a material with no inversion symmetry and is therefore absent in centrosymmetric materials. Here, we demonstrate that breaking the inversion symmetry by structural disorder can induce BPVE in ultrathin PtSe2, a centrosymmetric semiconducting van der Waals material. Homogenous illumination of defective PtSe2 by linearly and circularly polarized light results in a photoresponse termed as linear photogalvanic effect (LPGE) and circular photogalvanic effect (CPGE), which is mostly absent in the pristine crystal. First-principles calculations reveal that LPGE originates from Se vacancies that act as asymmetric scattering centers for the photo-generated electron-hole pairs. Our work emphasizes the importance of defects to induce photovoltaic functionality in centrosymmetric materials and shows how the range of materials suitable for light sensing and energy-harvesting applications can be extended. [ABSTRACT FROM AUTHOR]

Published

2023

8. Electrical control of hybrid exciton transport in a van der Waals heterostructure.

Author

Tagarelli, Fedele, Lopriore, Edoardo, Erkensten, Daniel, Perea-Causín, Raül, Brem, Samuel, Hagel, Joakim, Sun, Zhe, Pasquale, Gabriele, Watanabe, Kenji, Taniguchi, Takashi, Malic, Ermin, and Kis, Andras

Abstract

Interactions between out-of-plane dipoles in bosonic gases enable the long-range propagation of excitons. The lack of direct control over collective dipolar properties has so far limited the degrees of tunability and the microscopic understanding of exciton transport. In this work we modulate the layer hybridization and interplay between many-body interactions of excitons in a van der Waals heterostructure with an applied vertical electric field. By performing spatiotemporally resolved measurements supported by microscopic theory, we uncover the dipole-dependent properties and transport of excitons with different degrees of hybridization. Moreover, we find constant emission quantum yields of the transporting species as a function of excitation power with radiative decay mechanisms dominating over nonradiative ones, a fundamental requirement for efficient excitonic devices. Our findings provide a complete picture of the many-body effects in the transport of dilute exciton gases, and have crucial implications for studying emerging states of matter such as Bose–Einstein condensation and optoelectronic applications based on exciton propagation. The dipole-dependent propagation of hybrid excitons in a van der Waals heterostructure containing a WSe2 bilayer is characterized by modulating the layer hybridization and interplay between many-body interactions of excitons with an applied vertical electric field. [ABSTRACT FROM AUTHOR]

Published

2023

9. High durability and stability of 2D nanofluidic devices for long-term single-molecule sensing.

Author

Thakur, Mukeshchand, Cai, Nianduo, Zhang, Miao, Teng, Yunfei, Chernev, Andrey, Tripathi, Mukesh, Zhao, Yanfei, Macha, Michal, Elharouni, Farida, Lihter, Martina, Wen, Liping, Kis, Andras, and Radenovic, Aleksandra

Abstract

Nanopores in two-dimensional (2D) membranes hold immense potential in single-molecule sensing, osmotic power generation, and information storage. Recent advances in 2D nanopores, especially on single-layer MoS2, focus on the scalable growth and manufacturing of nanopore devices. However, there still remains a bottleneck in controlling the nanopore stability in atomically thin membranes. Here, we evaluate the major factors responsible for the instability of the monolayer MoS2 nanopores. We identify chemical oxidation and delamination of monolayers from their underlying substrates as the major reasons for the instability of MoS2 nanopores. Surface modification of the substrate and reducing the oxygen from the measurement solution improves nanopore stability and dramatically increases their shelf-life. Understanding nanopore growth and stability can provide insights into controlling the pore size, shape and can enable long-term measurements with a high signal-to-noise ratio and engineering durable nanopore devices. [ABSTRACT FROM AUTHOR]

Published

2023

10. Electrical spectroscopy of defect states and their hybridization in monolayer MoS2.

Author

Zhao, Yanfei, Tripathi, Mukesh, Čerņevičs, Kristiāns, Avsar, Ahmet, Ji, Hyun Goo, Gonzalez Marin, Juan Francisco, Cheon, Cheol-Yeon, Wang, Zhenyu, Yazyev, Oleg V., and Kis, Andras

Subjects

DEEP level transient spectroscopy, OPTICAL aberrations, SEMICONDUCTOR devices, MONOMOLECULAR films, FIELD-effect transistors, SCANNING transmission electron microscopy, SEMICONDUCTOR defects

Abstract

Defects in solids are unavoidable and can create complex electronic states that can significantly influence the electrical and optical properties of semiconductors. With the rapid progress in the integration of 2D semiconductors in practical devices, it is imperative to understand and characterize the influence of defects in this class of materials. Here, we examine the electrical response of defect filling and emission using deep level transient spectroscopy (DLTS) and reveal defect states and their hybridization in a monolayer MOCVD-grown material deposited on CMOS-compatible substrates. Supported by aberration-corrected STEM imaging and theoretical calculations, we find that neighboring sulfur vacancy pairs introduce additional shallow trap states via hybridization of individual vacancy levels. Even though such vacancy pairs only represent ~10% of the total defect concentration, they can have a substantial influence on the off currents and switching slopes of field-effect transistors based on 2D semiconductors. Our technique, which can quantify the energy states of different defects and their interactions, allows rapid and nondestructive electrical characterization of defect states important for the defect engineering of 2D semiconductors. Deep level transient spectroscopy (DLTS) is an established characterization technique used to study electrically active defects in 3D semiconductors. Here, the authors show that DLTS can also be applied to monolayer semiconductors, enabling in-situ characterization of the energy states of different defects and their interactions. [ABSTRACT FROM AUTHOR]

Published

2023

11. Electrical control of glass-like dynamics in vanadium dioxide for data storage and processing.

Author

Samizadeh Nikoo, Mohammad, Soleimanzadeh, Reza, Krammer, Anna, Migliato Marega, Guilherme, Park, Yunkyu, Son, Junwoo, Schueler, Andreas, Kis, Andras, Moll, Philip J. W., and Matioli, Elison

Published

2022

12. Room-temperature electrical control of polarization and emission angle in a cavity-integrated 2D pulsed LED.

Author

Gonzalez Marin, Juan Francisco, Unuchek, Dmitrii, Sun, Zhe, Cheon, Cheol Yeon, Tagarelli, Fedele, Watanabe, Kenji, Taniguchi, Takashi, and Kis, Andras

Subjects

BREWSTER'S angle, EMISSION control, LIGHT emitting diodes, OPTICAL polarization, LIGHT sources, EXCITON theory, SEMICONDUCTOR lasers, COMPLEMENTARY metal oxide semiconductors

Abstract

Devices based on two-dimensional (2D) semiconductors hold promise for the realization of compact and versatile on-chip interconnects between electrical and optical signals. Although light emitting diodes (LEDs) are fundamental building blocks for integrated photonics, the fabrication of light sources made of bulk materials on complementary metal-oxide-semiconductor (CMOS) circuits is challenging. While LEDs based on van der Waals heterostructures have been realized, the control of the emission properties necessary for information processing remains limited. Here, we show room-temperature electrical control of the location, directionality and polarization of light emitted from a 2D LED operating at MHz frequencies. We integrate the LED in a planar cavity to couple the polariton emission angle and polarization to the in-plane exciton momentum, controlled by a lateral voltage. These findings demonstrate the potential of TMDCs as fast, compact and tunable light sources, promising for the realization of electrically driven polariton lasers. 2D semiconductors offer a promising platform for the realization of compact and CMOS-compatible optoelectronic components. Here, the authors report the realization of light-emitting diodes based on 2D WSe2 integrated with a planar cavity, showing the electrical control of the emission angle and polarization at room temperature. [ABSTRACT FROM AUTHOR]

Published

2022

13. Excitonic devices with van der Waals heterostructures: valleytronics meets twistronics.

Author

Ciarrocchi, Alberto, Tagarelli, Fedele, Avsar, Ahmet, and Kis, Andras

Published

2022

14. Excitonic transport driven by repulsive dipolar interaction in a van der Waals heterostructure.

Author

Sun, Zhe, Ciarrocchi, Alberto, Tagarelli, Fedele, Gonzalez Marin, Juan Francisco, Watanabe, Kenji, Taniguchi, Takashi, and Kis, Andras

Abstract

Dipolar bosonic gases are currently the focus of intensive research due to their interesting many-body physics in the quantum regime. Their experimental embodiments range from Rydberg atoms to GaAs double quantum wells and van der Waals heterostructures built from transition metal dichalcogenides. Although quantum gases are very dilute, mutual interactions between the particles could lead to exotic many-body phenomena such as Bose–Einstein condensation and high-temperature superfluidity. Here we report the effect of repulsive dipolar interactions on the dynamics of interlayer excitons in the dilute regime. By using spatially and temporally resolved photoluminescence imaging, we observe the dynamics of exciton transport, enabling a direct estimation of exciton mobility. The presence of interactions significantly modifies the diffusive transport of excitons, effectively acting as a source of drift force and enhancing the diffusion coefficient by one order of magnitude. Combining repulsive dipolar interactions with the electrical control of interlayer excitons opens up appealing new perspectives for excitonic devices. Spatially and temporally resolved exciton diffusion experiments on a two-dimensional WSe2/hBN/MoSe2 heterostructure are reported, where an excitation-power-dependent exciton diffusion pattern is observed and phenomena with dipole–dipole repulsive interaction are quantitatively modelled. [ABSTRACT FROM AUTHOR]

Published

2022

15. Logic-in-memory based on an atomically thin semiconductor.

Author

Migliato Marega, Guilherme, Zhao, Yanfei, Avsar, Ahmet, Wang, Zhenyu, Tripathi, Mukesh, Radenovic, Aleksandra, and Kis, Andras

Abstract

The growing importance of applications based on machine learning is driving the need to develop dedicated, energy-efficient electronic hardware. Compared with von Neumann architectures, which have separate processing and storage units, brain-inspired in-memory computing uses the same basic device structure for logic operations and data storage1–3, thus promising to reduce the energy cost of data-centred computing substantially4. Although there is ample research focused on exploring new device architectures, the engineering of material platforms suitable for such device designs remains a challenge. Two-dimensional materials5,6 such as semiconducting molybdenum disulphide, MoS2, could be promising candidates for such platforms thanks to their exceptional electrical and mechanical properties7–9. Here we report our exploration of large-area MoS2 as an active channel material for developing logic-in-memory devices and circuits based on floating-gate field-effect transistors (FGFETs). The conductance of our FGFETs can be precisely and continuously tuned, allowing us to use them as building blocks for reconfigurable logic circuits in which logic operations can be directly performed using the memory elements. After demonstrating a programmable NOR gate, we show that this design can be simply extended to implement more complex programmable logic and a functionally complete set of operations. Our findings highlight the potential of atomically thin semiconductors for the development of next-generation low-power electronics. Logic operations and reconfigurable circuits are demonstrated that can be directly implemented using memory elements based on floating-gate field-effect transistors with monolayer MoS2 as the active channel material. [ABSTRACT FROM AUTHOR]

Published

2020

16. Wafer-scale MOCVD growth of monolayer MoS2 on sapphire and SiO2.

Author

Cun, Huanyao, Macha, Michal, Kim, HoKwon, Liu, Ke, Zhao, Yanfei, LaGrange, Thomas, Kis, Andras, and Radenovic, Aleksandra

Abstract

High-quality and large-scale growth of monolayer molybdenum disulfide (MoS2) has caught intensive attention because of its potential in many applications due to unique electronic properties. Here, we report the wafer-scale growth of high-quality monolayer MoS2 on singlecrystalline sapphire and also on SiO2 substrates by a facile metal-organic chemical vapor deposition (MOCVD) method. Prior to growth, an aqueous solution of sodium molybdate (Na2MoO4) is spun onto the substrates as the molybdenum precursor and diethyl sulfide ((C2H5)2S) is used as the sulfur precursor during the growth. The grown MoS2 films exhibit crystallinity, good electrical performance (electron mobility of 22 cm2·V-1·s-1) and structural continuity maintained over the entire wafer. The sapphire substrates are reusable for subsequent growth. The same method is applied for the synthesis of tungsten disulfide (WS2). Our work provides a facile, reproducible and cost-efficient method for the scalable fabrication of high-quality monolayer MoS2 for versatile applications, such as electronic and optoelectronic devices as well as the membranes for desalination and power generation. [ABSTRACT FROM AUTHOR]

Published

2019

17. Polarization switching and electrical control of interlayer excitons in two-dimensional van der Waals heterostructures.

Author

Ciarrocchi, Alberto, Unuchek, Dmitrii, Avsar, Ahmet, Watanabe, Kenji, Taniguchi, Takashi, and Kis, Andras

Abstract

The long-lived interlayer excitons in van der Waals heterostructures based on transition-metal dichalcogenides, together with unique spin-valley physics, make them promising for next-generation photonic and valleytronic devices. Although the emission characteristics of interlayer excitons have been studied, efficient manipulation of their valley states, a necessary requirement for information encoding, is still lacking. Here, we demonstrate comprehensive electrical control of interlayer excitons in a MoSe2/WSe2 heterostructure. Encapsulation of our well-aligned stack with hexagonal boron nitride (h-BN) allows us to resolve two separate narrow interlayer transitions with opposite helicities under circularly polarized excitation, either preserving or reversing the polarization of incoming light. By electrically controlling their relative intensities, we realize a polarization switch with tunable emission intensity and wavelength. Finally, we observe large g-factors of these two transitions on application of an external magnetic field. These results are interpreted within the picture of moiré-induced brightening of forbidden optical transitions. The ability to control the polarization of interlayer excitons is a step towards the manipulation of the valley degree of freedom in realistic device applications. A device capable of inverting the polarization of light by efficient control of interlayer excitons in a van der Waals heterostructure is demonstrated, representing an important step towards implementing logic operations in valleytronics. [ABSTRACT FROM AUTHOR]

Published

2019

18. Author Correction: A large-scale integrated vector–matrix multiplication processor based on monolayer molybdenum disulfide memories.

Author

Migliato Marega, Guilherme, Ji, Hyun Goo, Wang, Zhenyu, Pasquale, Gabriele, Tripathi, Mukesh, Radenovic, Aleksandra, and Kis, Andras

Published

2023

19. Patterning metal contacts on monolayer MoS2 with vanishing Schottky barriers using thermal nanolithography.

Author

Zheng, Xiaorui, Calò, Annalisa, Albisetti, Edoardo, Liu, Xiangyu, Alharbi, Abdullah Sanad M., Arefe, Ghidewon, Liu, Xiaochi, Spieser, Martin, Yoo, Won Jong, Taniguchi, Takashi, Watanabe, Kenji, Aruta, Carmela, Ciarrocchi, Alberto, Kis, Andras, Lee, Brian S., Lipson, Michal, Hone, James, Shahrjerdi, Davood, and Riedo, Elisa

Published

2019

20. Room-temperature electrical control of exciton flux in a van der Waals heterostructure.

Author

Unuchek, Dmitrii, Ciarrocchi, Alberto, Avsar, Ahmet, Watanabe, Kenji, Taniguchi, Takashi, and Kis, Andras

Abstract

Devices that rely on the manipulation of excitons—bound pairs of electrons and holes—hold great promise for realizing efficient interconnects between optical data transmission and electrical processing systems. Although exciton-based transistor actions have been demonstrated successfully in bulk semiconductor-based coupled quantum wells1-3, the low temperature required for their operation limits their practical application. The recent emergence of two-dimensional semiconductors with large exciton binding energies4,5 may lead to excitonic devices and circuits that operate at room temperature. Whereas individual two-dimensional materials have short exciton diffusion lengths, the spatial separation of electrons and holes in different layers in heterostructures could help to overcome this limitation and enable room-temperature operation of mesoscale devices6-8. Here we report excitonic devices made of MoS2-WSe2 van der Waals heterostructures encapsulated in hexagonal boron nitride that demonstrate electrically controlled transistor actions at room temperature. The long-lived nature of the interlayer excitons in our device results in them diffusing over a distance of five micrometres. Within our device, we further demonstrate the ability to manipulate exciton dynamics by creating electrically reconfigurable confining and repulsive potentials for the exciton flux. Our results make a strong case for integrating two-dimensional materials in future excitonic devices to enable operation at room temperature. Heterobilayer excitonic devices consisting of two different van der Waals materials, in which excitons are shared between the layers, exhibit electrically controlled switching actions at room temperature. [ABSTRACT FROM AUTHOR]

Published

2018

21. Thickness-modulated metal-to-semiconductor transformation in a transition metal dichalcogenide.

Author

Ciarrocchi, Alberto, Avsar, Ahmet, Ovchinnikov, Dmitry, and Kis, Andras

Abstract

The possibility of tailoring physical properties by changing the number of layers in van der Waals crystals is one of the driving forces behind the emergence of two-dimensional materials. One example is bulk MoS2, which changes from an indirect gap semiconductor to a direct bandgap semiconductor in the monolayer form. Here, we show a much bigger tuning range with a complete switching from a metal to a semiconductor in atomically thin PtSe2 as its thickness is reduced. Crystals with a thickness of ~13 nm show metallic behavior with a contact resistance as low as 70 Ω·μm. As they are thinned down to 2.5 nm and below, we observe semiconducting behavior. In such thin crystals, we demonstrate ambipolar transport with a bandgap smaller than 2.2 eV and an on/off ratio of ~102. Our results demonstrate that PtSe2 possesses an unusual behavior among 2D materials, enabling novel applications in nano and optoelectronics. [ABSTRACT FROM AUTHOR]

Published

2018

22. Resolving the spin splitting in the conduction band of monolayer MoS2.

Author

Marinov, Kolyo, Avsar, Ahmet, Kis, Andras, Watanabe, Kenji, and Takashi Taniguchi

Subjects

MOLYBDENUM disulfide, MONOMOLECULAR films, CONDUCTION bands, TIME reversal, SPINTRONICS

Abstract

Time-reversal symmetry and broken spin degeneracy enable the exploration of spin and valley quantum degrees of freedom in monolayer transition-metal dichalcogenides. While the strength of the large spin splitting in the valance band of these materials is now well-known, probing the 10-100 times smaller splitting in the conduction band poses significant challenges. Since it is easier to achieve n-type conduction in most of them, resolving the energy levels in the conduction band is crucial for the prospect of developing new spintronic and valleytronic devices. Here, we study quantum transport in high mobility monolayer MoS2 devices where we observe well-developed quantized conductance in multiples of e2/h in zero magnetic field. We extract a sub-band spacing energy of 0.8 meV. The application of a magnetic field gradually increases the interband spacing due to the valley-Zeeman effect. Here, we extract a g-factor of ~2.16 in the conduction band of monolayer MoS2. [ABSTRACT FROM AUTHOR]

Published

2017

23. Single-layer MoS2 nanopores as nanopower generators.

Author

Feng, Jiandong, Graf, Michael, Liu, Ke, Ovchinnikov, Dmitry, Dumcenco, Dumitru, Heiranian, Mohammad, Nandigana, Vishal, Aluru, Narayana R., Kis, Andras, and Radenovic, Aleksandra

Published

2016

24. Electrical contacts to two-dimensional semiconductors.

Author

Allain, Adrien, Kang, Jiahao, Banerjee, Kaustav, and Kis, Andras

Subjects

SEMICONDUCTORS, OPTOELECTRONIC devices, GRAPHENE, TRANSITION metals, MOLYBDENUM

Abstract

The performance of electronic and optoelectronic devices based on two-dimensional layered crystals, including graphene, semiconductors of the transition metal dichalcogenide family such as molybdenum disulphide (MoS2) and tungsten diselenide (WSe2), as well as other emerging two-dimensional semiconductors such as atomically thin black phosphorus, is significantly affected by the electrical contacts that connect these materials with external circuitry. Here, we present a comprehensive treatment of the physics of such interfaces at the contact region and discuss recent progress towards realizing optimal contacts for two-dimensional materials. We also discuss the requirements that must be fulfilled to realize efficient spin injection in transition metal dichalcogenides. [ABSTRACT FROM AUTHOR]

Published

2015

25. Electronic properties of transition-metal dichalcogenides.

Author

Kuc, Agnieszka, Heine, Thomas, and Kis, Andras

Subjects

TRANSITION metals, ELECTRIC fields, SEMICONDUCTORS, GRAPHENE, FIELD-effect transistors

Abstract

Graphene is not the only prominent example of two-dimensional (2D) materials. Due to their interesting combination of high mechanical strength and optical transparency, direct bandgap and atomic scale thickness transition-metal dichalcogenides (TMDCs) are an example of other materials that are now vying for the attention of the materials research community. In this article, the current state of quantum-theoretical calculations of the electronic and mechanical properties of semiconducting TMDC materials are presented. In particular, the intriguing interplay between external parameters (electric field, strain) and band structure, as well as the basic properties of heterostructures formed by vertical stacking of different 2D TMDCs are reviewed. Electrical measurements of MoS2, WS2, and WSe2 and their heterostructures, starting from simple field-effect transistors to more demanding logic circuits, high-frequency transistors, and memory devices, are also presented. [ABSTRACT FROM AUTHOR]

Published

2015

26. Optically active quantum dots in monolayer WSe2.

Author

Srivastava, Ajit, Sidler, Meinrad, Allain, Adrien V., Lembke, Dominik S., Kis, Andras, and Imamoğlu, A.

Subjects

QUANTUM dots, MONOMOLECULAR films, TUNGSTEN selenide, SEMICONDUCTORS, QUBITS, QUANTUM information theory

Abstract

Semiconductor quantum dots have emerged as promising candidates for the implementation of quantum information processing, because they allow for a quantum interface between stationary spin qubits and propagating single photons. In the meantime, transition-metal dichalcogenide monolayers have moved to the forefront of solid-state research due to their unique band structure featuring a large bandgap with degenerate valleys and non-zero Berry curvature. Here, we report the observation of zero-dimensional anharmonic quantum emitters, which we refer to as quantum dots, in monolayer tungsten diselenide, with an energy that is 20-100 meV lower than that of two-dimensional excitons. Photon antibunching in second-order photon correlations unequivocally demonstrates the zero-dimensional anharmonic nature of these quantum emitters. The strong anisotropic magnetic response of the spatially localized emission peaks strongly indicates that radiative recombination stems from localized excitons that inherit their electronic properties from the host transition-metal dichalcogenide. The large ∼1 meV zero-field splitting shows that the quantum dots have singlet ground states and an anisotropic confinement that is most probably induced by impurities or defects. The possibility of achieving electrical control in van der Waals heterostructures and to exploit the spin-valley degree of freedom renders transition-metal-dichalcogenide quantum dots interesting for quantum information processing. [ABSTRACT FROM AUTHOR]

Published

2015

27. Valley Zeeman effect in elementary optical excitations of monolayer WSe2.

Author

Srivastava, Ajit, Sidler, Meinrad, Allain, Adrien V., Lembke, Dominik S., Kis, Andras, and Imamoğlu, A.

Subjects

ZEEMAN effect, TUNGSTEN selenide, MONOMOLECULAR films, EXCITON theory, BAND gaps, THIN films, OPTICAL properties, BRILLOUIN zones, MAGNETIC moments

Abstract

A monolayer of a transition metal dichalcogenide such as WSe2 is a two-dimensional direct-bandgap valley-semiconductor having an effective honeycomb lattice structure with broken inversion symmetry. The inequivalent valleys in the Brillouin zone could be selectively addressed using circularly polarized light fields, suggesting the possibility for magneto-optical measurement and manipulation of the valley pseudospin degree of freedom . Here we report such experiments that demonstrate the valley Zeeman effect-strongly anisotropic lifting of the degeneracy of the valley pseudospin degree of freedom using an external magnetic field. The valley-splitting measured using the exciton transition deviates appreciably from values calculated using a three-band tight-binding model for an independent electron-hole pair at ±K valleys. We show, on the other hand, that a theoretical model taking into account the strongly bound nature of the exciton yields an excellent agreement with the experimentally observed splitting. In contrast to the exciton, the trion transition exhibits an unexpectedly large valley Zeeman effect that cannot be understood within the same framework, hinting at a different contribution to the trion magnetic moment. Our results raise the possibility of controlling the valley degree of freedom using magnetic fields in monolayer transition metal dichalcogenides or observing topological states of photons strongly coupled to elementary optical excitations in a microcavity. [ABSTRACT FROM AUTHOR]

Published

2015

28. Mechanical Properties of Carbon Nanotubes.

Author

Avouris, Phaedon, Bhushan, Bharat, Bimberg, Dieter, Klitzing, Klaus, Sakaki, Hiroyuki, Wiesendanger, Roland, Gnecco, Enrico, Meyer, Ernst, Kulik, Andrzej J., Kis, Andras, Lukic, Branimir, Lee, Kyumin, and Forró, Laszló

Published

2007

29. Nanoscale Mechanical Properties – Measuring Techniques and Applications.

Author

Kulik, Andrzej, Kis, Andras, Gremaud, Gérard, Hengsberger, Stefan, Luengo, Gustavo, Zysset, Philippe, and Forró, László

Abstract

This chapter describes local measurements and applications of nanoscale mechanical properties. It includes detailed state of the art presentation and in-depth analysis of experimental techniques, results and interpretations. After a short introduction, the second part of the chapter explores the application of local mechanical spectroscopy using coupled atomic force microscopy and ultrasound. This technique allows us to rapidly map elasticity and anelastic properties. Semiquantitative measurements can be taken as a function of temperature at specific point in the sample. The results obtained on the nanoscale are similar to those from bulk measurements, with interpretable differences. The local elasticity and damping were measured during phase transitions of polymer samples and shape-memory alloys. The third part describes the ˵nano-Swiss cheese″ method of measuring the elastic properties of nanosized tubular objects such as carbon nanotubes and microtubules. It is probably the only experiment in which the properties of single-wall nanotube ropes have been measured as a function of the rope diameter. We extended this idea to biological objects, microtubules, and successfully solved major experimental difficulties. We not only measured the temperature dependency of the microtubule modulus under pseudo-physiological conditions, but we also estimated the shear modulus using the same microtubule with several lengths of suspended segments. The fourth section describes the scanning nanoindentation technique as applied to human bone tissue. This instrument allows topography scans and indentation tests to be performed using an identical tip. The technique allows the indenter tip to be positioned on structures of interest with great precision during suface scans. For very inhomogeneous samples, such as bone tissue, this tool provides a way to detect local variations in mechanical properties. The indentation test allows us to study quantitative parameters like elastic modulus and hardness at the submicron level. Using this, local mechanical properties of compact and trabecular bone lamellae were tested under both dry and pseudo-physiological conditions. The chapter ends with a discussion of future prospects for the field and some conclusions. [ABSTRACT FROM AUTHOR]

Published

2007

30. Mobility engineering and a metal-insulator transition in monolayer MoS2.

Author

Radisavljevic, Branimir and Kis, Andras

Subjects

*MOBILITY (Structural dynamics), *METAL-insulator transitions, *MONOMOLECULAR films, *NANOELECTRONICS, *PHOTONICS, *MESOSCOPIC systems

Abstract

Two-dimensional (2D) materials are a new class of materials with interesting physical properties and applications ranging from nanoelectronics to sensing and photonics. In addition to graphene, the most studied 2D material, monolayers of other layered materials such as semiconducting dichalcogenides MoS2 or WSe2 are gaining in importance as promising channel materials for field-effect transistors (FETs). The presence of a direct bandgap in monolayer MoS2 due to quantum-mechanical confinement allows room-temperature FETs with an on/off ratio exceeding 108. The presence of high- κ dielectrics in these devices enhanced their mobility, but the mechanisms are not well understood. Here, we report on electrical transport measurements on MoS2 FETs in different dielectric configurations. The dependence of mobility on temperature shows clear evidence of the strong suppression of charged-impurity scattering in dual-gate devices with a top-gate dielectric. At the same time, phonon scattering shows a weaker than expected temperature dependence. High levels of doping achieved in dual-gate devices also allow the observation of a metal-insulator transition in monolayer MoS2 due to strong electron-electron interactions. Our work opens up the way to further improvements in 2D semiconductor performance and introduces MoS2 as an interesting system for studying correlation effects in mesoscopic systems. [ABSTRACT FROM AUTHOR]

Published

2013

31. Mobility engineering and a metal-insulator transition in monolayer MoS2.

Author

Radisavljevic, Branimir and Kis, Andras

Subjects

MOBILITY (Structural dynamics), METAL-insulator transitions, MONOMOLECULAR films, NANOELECTRONICS, PHOTONICS, MESOSCOPIC systems

Abstract

Two-dimensional (2D) materials are a new class of materials with interesting physical properties and applications ranging from nanoelectronics to sensing and photonics. In addition to graphene, the most studied 2D material, monolayers of other layered materials such as semiconducting dichalcogenides MoS2 or WSe2 are gaining in importance as promising channel materials for field-effect transistors (FETs). The presence of a direct bandgap in monolayer MoS2 due to quantum-mechanical confinement allows room-temperature FETs with an on/off ratio exceeding 108. The presence of high- κ dielectrics in these devices enhanced their mobility, but the mechanisms are not well understood. Here, we report on electrical transport measurements on MoS2 FETs in different dielectric configurations. The dependence of mobility on temperature shows clear evidence of the strong suppression of charged-impurity scattering in dual-gate devices with a top-gate dielectric. At the same time, phonon scattering shows a weaker than expected temperature dependence. High levels of doping achieved in dual-gate devices also allow the observation of a metal-insulator transition in monolayer MoS2 due to strong electron-electron interactions. Our work opens up the way to further improvements in 2D semiconductor performance and introduces MoS2 as an interesting system for studying correlation effects in mesoscopic systems. [ABSTRACT FROM AUTHOR]

Published

2013

32. Ultrasensitive photodetectors based on monolayer MoS2.

Author

Lopez-Sanchez, Oriol, Lembke, Dominik, Kayci, Metin, Radenovic, Aleksandra, and Kis, Andras

Subjects

PHOTODETECTORS, MONOMOLECULAR films, MOLYBDENUM sulfides, ELECTRIC properties, FIELD-effect transistors, GRAPHENE

Abstract

Two-dimensional materials are an emerging class of new materials with a wide range of electrical properties and potential practical applications. Although graphene is the most well-studied two-dimensional material, single layers of other materials, such as insulating BN (ref. 2) and semiconducting MoS2 (refs 3, 4) or WSe2 (refs 5, 6), are gaining increasing attention as promising gate insulators and channel materials for field-effect transistors. Because monolayer MoS2 is a direct-bandgap semiconductor due to quantum-mechanical confinement, it could be suitable for applications in optoelectronic devices where the direct bandgap would allow a high absorption coefficient and efficient electron-hole pair generation under photoexcitation. Here, we demonstrate ultrasensitive monolayer MoS2 phototransistors with improved device mobility and ON current. Our devices show a maximum external photoresponsivity of 880 A W−1 at a wavelength of 561 nm and a photoresponse in the 400-680 nm range. With recent developments in large-scale production techniques such as liquid-scale exfoliation and chemical vapour deposition-like growth, MoS2 shows important potential for applications in MoS2-based integrated optoelectronic circuits, light sensing, biomedical imaging, video recording and spectroscopy. [ABSTRACT FROM AUTHOR]

Published

2013

33. Electronics and optoelectronics of two-dimensional transition metal dichalcogenides.

Author

Wang, Qing Hua, Kalantar-Zadeh, Kourosh, Kis, Andras, Coleman, Jonathan N., and Strano, Michael S.

Subjects

CHALCOGENIDES, ELECTRONICS, OPTOELECTRONICS, TWO-dimensional models, TRANSITION metals, NANOELECTRONICS, BAND gaps, NANOSTRUCTURED materials

Abstract

The remarkable properties of graphene have renewed interest in inorganic, two-dimensional materials with unique electronic and optical attributes. Transition metal dichalcogenides (TMDCs) are layered materials with strong in-plane bonding and weak out-of-plane interactions enabling exfoliation into two-dimensional layers of single unit cell thickness. Although TMDCs have been studied for decades, recent advances in nanoscale materials characterization and device fabrication have opened up new opportunities for two-dimensional layers of thin TMDCs in nanoelectronics and optoelectronics. TMDCs such as MoS2, MoSe2, WS2 and WSe2 have sizable bandgaps that change from indirect to direct in single layers, allowing applications such as transistors, photodetectors and electroluminescent devices. We review the historical development of TMDCs, methods for preparing atomically thin layers, their electronic and optical properties, and prospects for future advances in electronics and optoelectronics. [ABSTRACT FROM AUTHOR]

Published

2012

34. How we made the 2D transistor.

Author

Kis, Andras

Published

2021

35. Probing magnetism in atomically thin semiconducting PtSe2.

Author

Avsar, Ahmet, Cheon, Cheol-Yeon, Pizzochero, Michele, Tripathi, Mukesh, Ciarrocchi, Alberto, Yazyev, Oleg V., and Kis, Andras

Subjects

MAGNETISM, MAGNETIC moments, TRANSMISSION electron microscopy, POINT defects, TRANSITION metals

Abstract

Atomic-scale disorder in two-dimensional transition metal dichalcogenides is often accompanied by local magnetic moments, which can conceivably induce long-range magnetic ordering into intrinsically non-magnetic materials. Here, we demonstrate the signature of long-range magnetic orderings in defective mono- and bi-layer semiconducting PtSe2 by performing magnetoresistance measurements under both lateral and vertical measurement configurations. As the material is thinned down from bi- to mono-layer thickness, we observe a ferromagnetic-to-antiferromagnetic crossover, a behavior which is opposite to the one observed in the prototypical 2D magnet CrI3. Our first-principles calculations, supported by aberration-corrected transmission electron microscopy imaging of point defects, associate this transition to the interplay between the defect-induced magnetism and the interlayer interactions in PtSe2. Furthermore, we show that graphene can be effectively used to probe the magnetization of adjacent semiconducting PtSe2. Our findings in an ultimately scaled monolayer system lay the foundation for atom-by-atom engineering of magnetism in otherwise non-magnetic 2D materials. Beneficiary defects could be utilized to introduce magnetism into materials that are not intrinsically magnetic. Here, the authors demonstrate long range magnetic order in the air-stable, defective Platinum Diselenide in the ultimate limit of thickness by using proximitized graphene as a probe. [ABSTRACT FROM AUTHOR]

Published

2020

36. Self-sensing, tunable monolayer MoS2 nanoelectromechanical resonators.

Author

Manzeli, Sajedeh, Dumcenco, Dumitru, Migliato Marega, Guilherme, and Kis, Andras

Subjects

RESONATORS, NANOELECTROMECHANICAL systems, MONOMOLECULAR films, TACTILE sensors, MOLYBDENUM disulfide, CHALCOGENIDES

Abstract

Excellent mechanical properties and the presence of piezoresistivity make single layers of transition metal dichalcogenides (TMDCs) viable candidates for integration in nanoelectromechanical systems (NEMS). We report on the realization of electromechanical resonators based on single-layer MoS2 with both piezoresistive and capacitive transduction schemes. Operating in the ultimate limit of membrane thickness, the resonant frequency of MoS2 resonators is primarily defined by the built-in mechanical tension and is in the very high frequency range. Using electrostatic interaction with a gate electrode, we tune the resonant frequency, allowing for the extraction of resonator parameters such as mass density and built-in strain. Furthermore, we study the origins of nonlinear dynamic response at high driving force. The results shed light on the potential of TMDC-based NEMS for the investigation of nanoscale mechanical effects at the limits of vertical downscaling and applications such as resonators for RF-communications, force and mass sensors. Suitable materials for nanoelectromechanical systems should possess excellent mechanical properties and allow displacement self-sensing. Here, the authors fabricate electromechanical resonators based on single-layer MoS2 with electrical readout, operating in the very high frequency range. [ABSTRACT FROM AUTHOR]

Published

2019

37. MoS2 photodetectors integrated with photonic circuits.

Author

Gonzalez Marin, Juan Francisco, Unuchek, Dmitrii, Watanabe, Kenji, Taniguchi, Takashi, and Kis, Andras

Subjects

MOLYBDENUM disulfide, PHOTODETECTORS, PHOTONICS, OPTOELECTRONICS, OPTICAL properties, BAND gaps

Abstract

In recent years, two-dimensional materials have risen as an attractive platform for integrated optoelectronics, due to their atomic scale thickness, favorable electrical, mechanical, and optical properties. In particular, graphene has been exploited as an ultrafast light modulator and photodetector, operating at telecommunication wavelengths. However, materials with larger bandgaps are required for light detection in the visible range of the spectrum, with wide applications in space communication, industrial quality controls, light sensing, etc. Even though TMDC-based light emitting and detecting devices in the visible spectrum have already been realized, efficient light absorption and photocurrent generation on integrated devices has not been achieved yet. Here, we demonstrate the integration of an ultrasensitive MoS2 photodetector with a silicon nitride photonic circuit. In contrast to the limited vertical light absorption, we observe near-unity lateral absorption, which results in even higher responsivity. By fabricating an alternative device where the MoS2 semiconducting channel is combined with a hexagonal boron nitride (h-BN) substrate, we significantly improve the speed of the photodetector. Low power operation is further achieved in a third device with graphene local gates. These results pave the way for future TMDC-based integrated optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published

2019

38. Disorder engineering and conductivity dome in ReS2 with electrolyte gating.

Author

Ovchinnikov, Dmitry, Gargiulo, Fernando, Allain, Adrien, Pasquier, Diego José, Dumcenco, Dumitru, Ho, Ching-Hwa, Yazyev, Oleg V., and Kis, Andras

Published

2016

39. A robust molecular probe for Ångstrom-scale analytics in liquids.

Author

Nirmalraj, Peter, Thompson, Damien, Dimitrakopoulos, Christos, Gotsmann, Bernd, Dumcenco, Dumitru, Kis, Andras, and Riel, Heike

Published

2016

40. Electromechanical oscillations in bilayer graphene.

Author

Benameur, Muhammed M., Gargiulo, Fernando, Manzeli, Sajedeh, Autès, Gabriel, Tosun, Mahmut, Yazyev, Oleg V., and Kis, Andras

Subjects

NANOELECTROMECHANICAL systems, GRAPHENE, ELECTRON-phonon interactions, PHOTONIC band gap structures, NANORIBBONS

Abstract

Nanoelectromechanical systems constitute a class of devices lying at the interface between fundamental research and technological applications. Realizing nanoelectromechanical devices based on novel materials such as graphene allows studying their mechanical and electromechanical characteristics at the nanoscale and addressing fundamental questions such as electron-phonon interaction and bandgap engineering. In this work, we realize electromechanical devices using single and bilayer graphene and probe the interplay between their mechanical and electrical properties. We show that the deflection of monolayer graphene nanoribbons results in a linear increase in their electrical resistance. Surprisingly, we observe oscillations in the electromechanical response of bilayer graphene. The proposed theoretical model suggests that these oscillations arise from quantum mechanical interference in the transition region induced by sliding of individual graphene layers with respect to each other. Our work shows that bilayer graphene conceals unexpectedly rich and novel physics with promising potential in applications based on nanoelectromechanical systems. [ABSTRACT FROM AUTHOR]

Published

2015

41. Optically active quantum dots in monolayer WSe2.

Author

Srivastava, Ajit, Sidler, Meinrad, Allain, Adrien V., Lembke, Dominik S., Kis, Andras, and Imamoğlu, A.

Subjects

*QUANTUM dots, *MONOMOLECULAR films, *TUNGSTEN selenide, *SEMICONDUCTORS, *QUBITS, *QUANTUM information theory

Abstract

Semiconductor quantum dots have emerged as promising candidates for the implementation of quantum information processing, because they allow for a quantum interface between stationary spin qubits and propagating single photons. In the meantime, transition-metal dichalcogenide monolayers have moved to the forefront of solid-state research due to their unique band structure featuring a large bandgap with degenerate valleys and non-zero Berry curvature. Here, we report the observation of zero-dimensional anharmonic quantum emitters, which we refer to as quantum dots, in monolayer tungsten diselenide, with an energy that is 20-100 meV lower than that of two-dimensional excitons. Photon antibunching in second-order photon correlations unequivocally demonstrates the zero-dimensional anharmonic nature of these quantum emitters. The strong anisotropic magnetic response of the spatially localized emission peaks strongly indicates that radiative recombination stems from localized excitons that inherit their electronic properties from the host transition-metal dichalcogenide. The large ∼1 meV zero-field splitting shows that the quantum dots have singlet ground states and an anisotropic confinement that is most probably induced by impurities or defects. The possibility of achieving electrical control in van der Waals heterostructures and to exploit the spin-valley degree of freedom renders transition-metal-dichalcogenide quantum dots interesting for quantum information processing. [ABSTRACT FROM AUTHOR]

Published

2015

42. Valley Zeeman effect in elementary optical excitations of monolayer WSe2.

Author

Srivastava, Ajit, Sidler, Meinrad, Allain, Adrien V., Lembke, Dominik S., Kis, Andras, and Imamoğlu, A.

Subjects

*ZEEMAN effect, *TUNGSTEN selenide, *MONOMOLECULAR films, *EXCITON theory, *BAND gaps, *THIN films, *OPTICAL properties, *BRILLOUIN zones, *MAGNETIC moments

Abstract

A monolayer of a transition metal dichalcogenide such as WSe2 is a two-dimensional direct-bandgap valley-semiconductor having an effective honeycomb lattice structure with broken inversion symmetry. The inequivalent valleys in the Brillouin zone could be selectively addressed using circularly polarized light fields, suggesting the possibility for magneto-optical measurement and manipulation of the valley pseudospin degree of freedom . Here we report such experiments that demonstrate the valley Zeeman effect-strongly anisotropic lifting of the degeneracy of the valley pseudospin degree of freedom using an external magnetic field. The valley-splitting measured using the exciton transition deviates appreciably from values calculated using a three-band tight-binding model for an independent electron-hole pair at ±K valleys. We show, on the other hand, that a theoretical model taking into account the strongly bound nature of the exciton yields an excellent agreement with the experimentally observed splitting. In contrast to the exciton, the trion transition exhibits an unexpectedly large valley Zeeman effect that cannot be understood within the same framework, hinting at a different contribution to the trion magnetic moment. Our results raise the possibility of controlling the valley degree of freedom using magnetic fields in monolayer transition metal dichalcogenides or observing topological states of photons strongly coupled to elementary optical excitations in a microcavity. [ABSTRACT FROM AUTHOR]

Published

2015

43. Ultrasensitive photodetectors based on monolayer MoS2.

Author

Lopez-Sanchez, Oriol, Lembke, Dominik, Kayci, Metin, Radenovic, Aleksandra, and Kis, Andras

Subjects

*PHOTODETECTORS, *MONOMOLECULAR films, *MOLYBDENUM sulfides, *ELECTRIC properties, *FIELD-effect transistors, *GRAPHENE

Abstract

Two-dimensional materials are an emerging class of new materials with a wide range of electrical properties and potential practical applications. Although graphene is the most well-studied two-dimensional material, single layers of other materials, such as insulating BN (ref. 2) and semiconducting MoS2 (refs 3, 4) or WSe2 (refs 5, 6), are gaining increasing attention as promising gate insulators and channel materials for field-effect transistors. Because monolayer MoS2 is a direct-bandgap semiconductor due to quantum-mechanical confinement, it could be suitable for applications in optoelectronic devices where the direct bandgap would allow a high absorption coefficient and efficient electron-hole pair generation under photoexcitation. Here, we demonstrate ultrasensitive monolayer MoS2 phototransistors with improved device mobility and ON current. Our devices show a maximum external photoresponsivity of 880 A W−1 at a wavelength of 561 nm and a photoresponse in the 400-680 nm range. With recent developments in large-scale production techniques such as liquid-scale exfoliation and chemical vapour deposition-like growth, MoS2 shows important potential for applications in MoS2-based integrated optoelectronic circuits, light sensing, biomedical imaging, video recording and spectroscopy. [ABSTRACT FROM AUTHOR]

Published

2013