Your search keyword '"Ye, Jianting"' showing total 8 results

1. Quantum Hall effect in a CVD-grown oxide.

Author

Zheliuk, Oleksandr, Kreminska, Yuliia, Fu, Qundong, Pizzirani, Davide, Ammerlaan, Andrew A.L.N., Wang, Ying, Hameed, Sardar, Wan, Puhua, Peng, Xiaoli, Wiedmann, Steffen, Liu, Zheng, Ye, Jianting, and Zeitler, Uli

Subjects

QUANTUM Hall effect, QUANTUM confinement effects, ELECTRIC field effects, CHEMICAL vapor deposition, QUANTUM theory

Abstract

Two-dimensional (2D) electron systems are promising for investigating correlated quantum phenomena. In particular, 2D oxides provide a platform that can host various quantum phases such as quantized Hall effect, superconductivity, or magnetism. The realization of such quantum phases in 2D oxides heavily relies on dedicated heterostructure growths. Here we show the integer quantum Hall effect achieved in chemical vapor deposition grown Bi2O2Se - a representative member of a more accessible oxide family. A single or few subband 2D electron system can be prepared in thin films of Bi2O2Se, where the film thickness acts as the key subband design parameter and the occupation is determined by the electric field effect. This oxide platform exhibits characteristic advantages in structural flexibility due to its layered nature, making it suitable for scalable growth. The unique small mass distinguishes Bi2O2Se from other high-mobility oxides, providing a new platform for exploring quantum Hall physics in 2D oxides. The authors demonstrate quantum Hall effect in semiconducting layered oxide Bi2O2Se. Its unique low mass among the oxides of 0.14 me and pronounced layered structure makes Bi2O2Se highly susceptible to the quantum confinement effects. [ABSTRACT FROM AUTHOR]

Published

2024

2. Orbital Fulde–Ferrell–Larkin–Ovchinnikov state in an Ising superconductor.

Author

Wan, Puhua, Zheliuk, Oleksandr, Yuan, Noah F. Q., Peng, Xiaoli, Zhang, Le, Liang, Minpeng, Zeitler, Uli, Wiedmann, Steffen, Hussey, Nigel E., Palstra, Thomas T. M., and Ye, Jianting

Abstract

In superconductors possessing both time and inversion symmetries, the Zeeman effect of an external magnetic field can break the time-reversal symmetry, forming a conventional Fulde–Ferrell–Larkin–Ovchinnikov (FFLO) state characterized by Cooper pairings with finite momentum1,2. In superconductors lacking (local) inversion symmetry, the Zeeman effect may still act as the underlying mechanism of FFLO states by interacting with spin–orbit coupling (SOC). Specifically, the interplay between the Zeeman effect and Rashba SOC can lead to the formation of more accessible Rashba FFLO states that cover broader regions in the phase diagram3–5. However, when the Zeeman effect is suppressed because of spin locking in the presence of Ising-type SOC, the conventional FFLO scenarios are no longer effective. Instead, an unconventional FFLO state is formed by coupling the orbital effect of magnetic fields with SOC, providing an alternative mechanism in superconductors with broken inversion symmetries6–8. Here we report the discovery of such an orbital FFLO state in the multilayer Ising superconductor 2H-NbSe2. Transport measurements show that the translational and rotational symmetries are broken in the orbital FFLO state, providing the hallmark signatures of finite-momentum Cooper pairings. We establish the entire orbital FFLO phase diagram, consisting of a normal metal, a uniform Ising superconducting phase and a six-fold orbital FFLO state. This study highlights an alternative route to achieving finite-momentum superconductivity and provides a universal mechanism to preparing orbital FFLO states in similar materials with broken inversion symmetries.The discovery of an orbital Fulde–Ferrell–Larkin–Ovchinnikov state in the multilayer Ising superconductor 2H-NbSe2, in which the translational and rotational symmetries are broken, enables the preparation of such states in other materials with broken inversion symmetries. [ABSTRACT FROM AUTHOR]

Published

2023

3. Mechanical stimulation controls osteoclast function through the regulation of Ca2+-activated Cl− channel Anoctamin 1.

Author

Sun, Weijia, Li, Yuheng, Li, Jianwei, Tan, Yingjun, Yuan, Xinxin, Meng, Haoye, Ye, Jianting, Zhong, Guohui, Jin, XiaoYan, Liu, Zizhong, Du, Ruikai, Xing, Wenjuan, Zhao, Dingsheng, Song, Jinping, Li, Youyou, Pan, Junjie, Zhao, Yunzhang, Li, Qi, Wang, Aiyuan, and Ling, Shukuan

Subjects

BONE resorption, OSTEOCLAST inhibition, BONE cells, BONE remodeling, STRAINS & stresses (Mechanics), OSTEOCLASTS, CALCIUM ions

Abstract

Mechanical force loading is essential for maintaining bone homeostasis, and unloading exposure can lead to bone loss. Osteoclasts are the only bone resorbing cells and play a crucial role in bone remodeling. The molecular mechanisms underlying mechanical stimulation-induced changes in osteoclast function remain to be fully elucidated. Our previous research found Ca2+-activated Cl− channel Anoctamin 1 (Ano1) was an essential regulator for osteoclast function. Here, we report that Ano1 mediates osteoclast responses to mechanical stimulation. In vitro, osteoclast activities are obviously affected by mechanical stress, which is accompanied by the changes of Ano1 levels, intracellular Cl− concentration and Ca2+ downstream signaling. Ano1 knockout or calcium binding mutants blunts the response of osteoclast to mechanical stimulation. In vivo, Ano1 knockout in osteoclast blunts loading induced osteoclast inhibition and unloading induced bone loss and. These results demonstrate that Ano1 plays an important role in mechanical stimulation induced osteoclast activity changes. An essential role of the Ca2+-activated Cl− channel, Anoctamin 1, is identified in mediating the response of osteoclasts to mechanical stimulation. Ano1 knockout in osteoclasts inhibits unloading- induced osteoclast activation and unloading-induced bone loss. [ABSTRACT FROM AUTHOR]

Published

2023

4. Strong anisotropic enhancement of photoluminescence in WS2 integrated with plasmonic nanowire array.

Author

Han, Chunrui, Wang, Yu, Zhou, Weihu, Liang, Minpeng, and Ye, Jianting

Subjects

TRANSITION metals, PHOTONICS, OPTOELECTRONICS, BAND gaps, PHOTOLUMINESCENCE, NANOWIRE devices

Abstract

Layered transition metal dichalcogenides (TMDCs) have shown great potential for a wide range of applications in photonics and optoelectronics. Nevertheless, valley decoherence severely randomizes its polarization which is important to a light emitter. Plasmonic metasurface with a unique way to manipulate the light-matter interaction may provide an effective and practical solution. Here by integrating TMDCs with plasmonic nanowire arrays, we demonstrate strong anisotropic enhancement of the excitonic emission at different spectral positions. For the indirect bandgap transition in bilayer WS2, multifold enhancement can be achieved with the photoluminescence (PL) polarization either perpendicular or parallel to the long axis of nanowires, which arises from the coupling of WS2 with localized or guided plasmon modes, respectively. Moreover, PL of high linearity is obtained in the direct bandgap transition benefiting from, in addition to the plasmonic enhancement, the directional diffraction scattering of nanowire arrays. Our method with enhanced PL intensity contrasts to the conventional form-birefringence based on the aspect ratio of nanowire arrays where the intensity loss is remarkable. Our results provide a prototypical plasmon-exciton hybrid system for anisotropic enhancement of the PL at the nanoscale, enabling simultaneous control of the intensity, polarization and wavelength toward practical ultrathin photonic devices based on TMDCs. [ABSTRACT FROM AUTHOR]

Published

2021

5. Logical modeling of thymus and natural killer lymphocyte differentiation.

Author

Ye, Jianting, Chen, Qingxi, and Wang, Ruiqi

Subjects

*T cell differentiation, *LYMPHOCYTES, *CELL differentiation, *KILLER cells, *THYMUS

Abstract

Thymus (T) and natural killer (NK) lymphocytes are important barriers against diseases. Therefore, it is necessary to understand regulatory mechanisms related to the cell fate decisions involved in the production of these cells. Although some individual information related to T and NK lymphocyte cell fate decisions have been revealed, the related network and its dynamical characteristics still have not been well understood. By integrating individual information and comparing with experimental data, we construct a comprehensive regulatory network and a logical model related to T and NK lymphocyte differentiation. We aim to explore possible mechanisms of how each lineage differentiation is realized by systematically screening individual perturbations. When determining the perturbation strategies, the state transition can be used to identify the roles of specific genes in cell type selection and reprogramming. In agreement with experimental observations, the dynamics of the model correctly restates the cell differentiation processes from common lymphoid progenitors to CD4+ T cells, CD8+ T cells, and NK cells. Our analysis reveals that some specific perturbations can give rise to directional cell differentiation or reprogramming. We test our in silico results by using known experimental observations. The integrated network and the logical model presented here might be a good candidate for providing qualitative mechanisms of cell fate specification involved in T and NK lymphocyte cell fate decisions. [ABSTRACT FROM AUTHOR]

Published

2021

6. Polarized resonant emission of monolayer WS2 coupled with plasmonic sawtooth nanoslit array.

Author

Han, Chunrui and Ye, Jianting

Subjects

LINEAR dichroism, SURFACE plasmon resonance, TEMPERATURE control, HYBRID systems, MONOMOLECULAR films, TRANSITION metals, EXCITON theory

Abstract

Transition metal dichalcogenide (TMDC) monolayers have enabled important applications in light emitting devices and integrated nanophotonics because of the direct bandgap, spin-valley locking and highly tunable excitonic properties. Nevertheless, the photoluminescence polarization is almost random at room temperature due to the valley decoherence. Here, we show the room temperature control of the polarization states of the excitonic emission by integrating WS2 monolayers with a delicately designed metasurface, i.e. a silver sawtooth nanoslit array. The random polarization is transformed to linear when WS2 excitons couple with the anisotropic resonant transmission modes that arise from the surface plasmon resonance in the metallic nanostructure. The coupling is found to enhance the valley coherence that contributes to ~30% of the total linear dichroism. Further modulating the transmission modes by optimizing metasurfaces, the total linear dichroism of the plasmon-exciton hybrid system can approach 80%, which prompts the development of photonic devices based on TMDCs. Here the authors show that WS2 coupled with a plasmonic sawtooth nanoslit array is an efficient exciton-plasmon hybrid system which enables polarization modulation of the excitonic emission at the nanoscale up to 80% and observation of valley coherence at room temperature. [ABSTRACT FROM AUTHOR]

Published

2020

7. Dirac-fermion-mediated ferromagnetism in a topological insulator.

Author

Checkelsky, Joseph G., Ye, Jianting, Onose, Yoshinori, Iwasa, Yoshihiro, and Tokura, Yoshinori

Subjects

*FERROMAGNETISM, *DIRAC function, *FERMIONS, *ELECTRIC insulators & insulation, *SYMMETRY (Physics), *GAUGE field theory, *QUANTUM theory

Abstract

Topological insulators are a newly discovered class of materials in which helical conducting modes exist on the surface of a bulk insulator. Recently, theoretical works have shown that breaking gauge symmetry or time-reversal symmetry in these materials produces exotic states that, if realized, represent substantial steps towards realizing new magnetoelectric effects and tools useful for quantum computing. Here we demonstrate the latter symmetry breaking in the form of ferromagnetism arising from the interaction between magnetic impurities and the Dirac fermions. Using devices based on cleaved single crystals of Mn-doped Bi2Te3?ySey, the application of both solid-dielectric and ionic-liquid gating allows us to measure the transport response of the surface states within the bulk bandgap in the presence of magnetic ions. By tracking the anomalous Hall effect we find that the surface modes support robust ferromagnetism as well as magnetoconductance that is consistent with enhanced one-dimensional edge-state transport on the magnetic domain wall. Observation of this evidence for quantum transport phenomena demonstrates the accessibility of these exotics states in devices and may serve to focus the wide range of proposed methods for experimentally realizing the quantum anomalous Hall effect and states required for quantum computing. [ABSTRACT FROM AUTHOR]

Published

2012

8. Superconductivity Series in Transition Metal Dichalcogenides by Ionic Gating.

Author

Shi, Wu, Ye, Jianting, Zhang, Yijin, Suzuki, Ryuji, Yoshida, Masaro, Miyazaki, Jun, Inoue, Naoko, Saito, Yu, and Iwasa, Yoshihiro

Subjects

*SUPERCONDUCTIVITY, *TRANSITION metals, *CHALCOGENIDES, *FIELD-effect transistors, *ELECTROSTATICS, *POLYETHYLENE glycol

Abstract

Functionalities of two-dimensional (2D) crystals based on semiconducting transition metal dichalcogenides (TMDs) have now stemmed from simple field effect transistors (FETs) to a variety of electronic and opto-valleytronic devices, and even to superconductivity. Among them, superconductivity is the least studied property in TMDs due to methodological difficulty accessing it in different TMD species. Here, we report the systematic study of superconductivity in MoSe2, MoTe2 and WS2 by ionic gating in different regimes. Electrostatic gating using ionic liquid was able to induce superconductivity in MoSe2 but not in MoTe2 because of inefficient electron accumulation limited by electronic band alignment. Alternative gating using KClO4/polyethylene glycol enabled a crossover from surface doping to bulk doping, which induced superconductivities in MoTe2 and WS2 electrochemically. These new varieties greatly enriched the TMD superconductor families and unveiled critical methodology to expand the capability of ionic gating to other materials. [ABSTRACT FROM AUTHOR]

Published

2015