[1] J Y PARK, L R BAKER, G A SOMORJAI. Role of hot electrons and metal-oxide interfaces in surface chemistry and catalytic reactions. Chemical Reviews, 115, 2781-2817(2015).
[2] S TONGAY, J ZHOU, C ATACA et al. Thermally driven crossover from indirect toward direct bandgap in 2D semiconductors: MoSe2 versus MoS2. Nano Letters, 12, 5576-5580(2012).
[3] X WANG, Y GONG, G SHI et al. Chemical vapor deposition growth of crystalline monolayer MoSe2. ACS Nano, 8, 5125-5131(2014).
[4] Q H WANG, K KALANTAR-ZADEH et al. Electronics and optoelectronics of two-dimensional transition metal dichalcogenides. Nature Nanotechnology, 7, 699-712(2012).
[5] P TONNDORF, R SCHMIDT, P BOETTGER et al. Photoluminescence emission and Raman response of monolayer MoS2, MoSe2, and WSe2. Optics Express, 21, 4908-4916(2013).
[6] J S ROSS, S WU, H YU et al. Electrical control of neutral and charged excitons in a monolayer semiconductor. Nature Communications, 4, 1474(2013).
[7] C T LE, D J CLARK, F ULLAH et al. Nonlinear optical characteristics of monolayer MoSe2. Annalen Der Physik, 528, 551-559(2016).
[8] D Z ZHANG, C Y WEN, J B MCCLIMON et al. Rapid growth of monolayer MoSe2 films for large-area electronics. Advanced Electronic Materials, 7, 2001219(2021).
[9] Y XU, Y M MA, Y Q YU et al. Self-powered, ultra-high detectivity and high-speed near-infrared photodetectors from stacked-layered MoSe2/Si heterojunction. Nanotechnology, 32(2021).
[10] L LAFETA, A CORRADI, T. Y ZHANG et al. Second- and third-order optical susceptibilities across excitons states in 2D monolayer transition metal dichalcogenides. 2D Materials, 8(2021).
[11] B FERGUSON, X C ZHANG. Materials for terahertz science and technology. Nature Materials, 1, 26-33(2002).
[12] M TONOUCHI. Cutting-edge terahertz technology. Nature Photonics, 1, 97-105(2007).
[13] T KAMPFRATH, K TANAKA, K A NELSON. Resonant and nonresonant control over matter and light by intense terahertz transients. Nature Photonics, 7, 680-690(2013).
[14] E Yiwen, Liangliang ZHANG, Anton TCYPKIN et al. Broadband THz sources from gases to liquids. Ultrafast Science, 2021, 9892763(2021).
[15] Z FAN, M XU, Y HUANG et al. Terahertz surface emission from MoSe2 at the monolayer limit. ACS Applied Materials & Interfaces, 12, 48161-48169(2020).
[16] L ZHU, Y HUANG, Z YAO et al. Enhanced polarization-sensitive terahertz emission from vertically grown graphene by a dynamical photon drag effect. Nanoscale, 9, 10301-10311(2017).
[17] P C M PLANKEN, H K NIENHUYS, H J BAKKER et al. Measurement and calculation of the orientation dependence of terahertz pulse detection in ZnTe. Journal of the Optical Society of America B-Optical Physics, 18, 313-317(2001).
[18] Y HUANG, Z YAO, C HE et al. Terahertz surface and interface emission spectroscopy for advanced materials. Journal of Physics-Condensed Matter, 31, 153001(2019).
[19] Y HUANG, L ZHU, Q ZHAO et al. Surface optical rectification from layered MoS2 crystal by THz time domain surface emission spectroscopy. ACS Applied Materials & Interfaces, 9, 4956-4965(2017).
[20] X WU, X XU, X LU et al. Terahertz emission from semi-insulating GaAs with octadecanthiol-passivated surface. Applied Surface Science, 279, 92-96(2013).
[21] M REID, R FEDOSEJEVS. Terahertz emission from (100)InAs surfaces at high excitation fluences. Applied Physics Letters, 86(2005).
[22] L ZHANG, Y HUANG, L ZHU et al. Polarized THz emission from in-plane dipoles in monolayer tungsten disulfide by linear and circular optical rectification. Advanced Optical Materials, 7, 1801314(2019).