2025年

• [1] Wu, J. et al. Sensitive Sub-THz Photodetection in Twisted Graphene with Broad Spectral Response. Advanced Science 2025, e12851.
• [2] Zhao, J. et al. Gallium oxide/indium gallium zinc oxide heterojunction Schottky barrier thin-film transistors with ultrahigh 2D electron density over 6 × 10¹³/cm². Journal of Vacuum Science & Technology A 2025, 43, 043409.
• [3] Liu, Y. et al. Resolving Spin Orientation in the van der Waals Antiferromagnet CrCl₃ via the Exciton-Enhanced Magneto-Optical Voigt Effect. ACS Nano 2025, 19, 25395.
• [4] Liu, Y. et al. Sensitive photodetection in a violet phosphorus tunnel junction. Optics Letters 2025, 50, 3114.
• [5] Fan, Y. et al. Probing ultraweak in-plane magnetic anisotropy within a two-dimensional layered antiferromagnet. PNAS 2025, 122, e2414668122.
• [6] Zhu, S. et al. Polarity-Switchable Sensitive Photodetection in a Superconducting van der Waals Heterostructure. ACS Applied Materials & Interfaces 2025, 17, 22060.
• [7] Mei, J. et al. Tunable Photoconductivity Polarity in a Two-Dimensional Ferromagnet for Enhanced Image Recognition. ACS Photonics 2025, 12, 1746.
• [8] Zhu, S. et al. Tuning the interfacial transport behavior in a superconducting van der Waals heterostructure. Applied Physics Letters 2025, 126, 5.
• [9] Zhu, S. et al. Tunable Ambipolar Transport in a 2D Kagome Semiconductor. Advanced Optical Materials 2025, 13, 2.

2024年

• [1] Zhang, R. et al. Probing the photocurrent in two-dimensional titanium disulfide. Nanotechnology 2024, 35, 015708.
• [2] Zhang, R. et al. Low-temperature transport and relaxation of photo-carriers in TiS₂. Applied Physics Letters 2024, 125, 221104.
• [3] Zhang, R. et al. Enhanced Photobolometric Effect in an All-Semimetal van der Waals Heterostructure. ACS Applied Materials & Interfaces 2024, 16, 66655.
• [4] Xie, B. et al. Resonant Tunneling-Enhanced Photoresponsivity in a Twisted Graphene van der Waals Heterostructure. Nano Letters 2024, 24, 2870.
• [5] Fan, Y. et al. Tuning magnetoresistance of chromium chloride tunnel junction through the interface and multi-field effect. Acta Physica Sinica 2024, 73, 137302.
• [6] Chen, W. et al. An Ultrahigh-Contrast Violet Phosphorus Van der Waals Phototransistor. Advanced Optical Materials 2024, 12, 2301399.
• [7] Wu, G. et al. A piezoelectric driven amphibious microrobot capable of fast and controllable movement. Smart Materials and Structures 2024, 33, 115035.
• [8] Wu, G. et al. A Piezoelectrically Driven Microrobot Using a Novel Monolithic Spatial Parallel Mechanism as Its Hip Joint. Journal of Bionic Engineering 2024, 21, 803.

2023年

• [1] Xie, B. et al. Probing the Inelastic Electron Tunneling via the Photocurrent in a Vertical Graphene van der Waals Heterostructure. ACS Nano 2023, 17, 18352.
• [2] Ji, Z. et al. Tunable Photoresponse in a Two-Dimensional Superconducting Heterostructure. Nanomaterials 2023, 13, 421.
• [3] Chen, W. et al. Strong In-Plane Optoelectronic Anisotropy and Polarization Sensitivity in Low-Symmetry 2D Violet Phosphorus. Nano Letters 2023, 23, 10821.

更早

• [1] Jin, Z. et al. Controlled Synthesis of a Two-Dimensional Non-van der Waals Ferromagnet toward a Magnetic Moire Superlattice. ACS Nano 2022, 16, 7572.
• [2] Ji, Y. et al. Multiple mechanisms of the low temperature photoresponse in niobium diselenide. Applied Physics Letters 2021, 119, 221104.
• [3] Chen, W. et al. Voltage Control of a van der Waals Spin-Filter Magnetic Tunnel Junction. Nano Letters 2019, 19, 915.
• [4] Shi, Y. et al. Imaging quantum spin Hall edges in monolayer WTe₂. Science Advances 2019, 5, eaat8799.
• [5] Cao, X. et al. Atomically Thin CrCl₃: An In-Plane Layered Antiferromagnetic Insulator. Nano Letters 2019, 19, 3993.
• [6] Song, T. et al. Giant tunneling magnetoresistance in spin-filter van der Waals heterostructures. Science 2018, 360, 1214.
• [7] Fei, Z. et al. Edge conduction in monolayer WTe₂. Nature Physics 2017, 13, 677.
• [8] Jadidi, M. M. et al. Tunable Ultrafast Thermal Relaxation in Graphene Measured by Continuous-Wave Photomixing. Physical Review Letters 2016, 117, 257401.
• [9] Wang, Y. et al. Electronic transport properties of Ir-decorated graphene. Scientific Reports 2015, 5, 15764.
• [10] Wang, Y. et al. Neutral-current Hall effects in disordered graphene. Physical Review B 2015, 92, 161411.
• [11] Wan, J. et al. In Situ Investigations of Li-MoS₂ with Planar Batteries. Advanced Energy Materials 2015, 5, 1401742.
• [12] Cai, X. et al. Plasmon-Enhanced Terahertz Photodetection in Graphene. Nano Letters 2015, 15, 4295.
• [13] Cai, X. et al. Pulsed Near-IR Photoresponse in a Bi-metal Contacted Graphene Photodetector. Scientific Reports 2015, 5, 14803.
• [14] Wang, Y. et al. Electronic transport properties of Ir-decorated graphene. Scientific Reports 2015, 5, 15764.
• [15] Bao, W. et al. Approaching the limits of transparency and conductivity in graphitic materials through lithium intercalation. Nature Communications 2014, 5, 4224.
• [16] Bao, W. et al. High mobility ambipolar MoS₂ field-effect transistors: Substrate and dielectric effects. Applied Physics Letters 2013, 102, 042104.