图 1  体光伏效应发展历程

Figure 1.  History of bulk photovoltaic effect.

图 2  体光伏效应的几种介观模型　(a) 楔形反对称散射中心^[40]; (b) 光激发载流子在非对称势阱中的不对称散射^[40]; (c) Rashba自旋轨道耦合^[40]; (d) 金属/铁电体/金属结构中的退极化场机理示意图^[41,42]

Figure 2.  Several mesoscopic models for the bulk photovoltaic effect: (a) Asymmetric carrier scattering centers^[40]; (b) asymmetric potential well at a carrier generation center^[40]; (c) the minimum band splitting arising from spin-orbit coupling^[40]; (d) schematic diagram of depolarization field in a metal/ferroelectric/metal structure^[41,42].

图 3  (a) 位移电流微观机理示意图; (b) 体光伏效应电流(含位移电流j_sh和弹道电流j_b)微观示意图^[44]

Figure 3.  (a) Schematic of mechanism of shift current; (b) schematic of mechanism of BPVE current (including shift and ballistic currents) during the excitation (ex), scattering, and recombination (rec) process^[44].

图 4  WS₂ 纳米管体光伏响应　(a) 单层WS₂和(b) WS₂ 纳米管器件的短路电流与激光光斑在器件不同位置的依赖关系; (c) 不同辐照强度条件下WS₂纳米管的I-V变化曲线; (d)不同激发波长下短路电流随激光功率密度变化关系, 插图为不同波长激发的可能跃迁路径^[56]

Figure 4.  Bulkphotovoltaic response for WS₂ nanotubes: The dependence of I_sc on the position of the laser spot in a WS₂ monolayer device (a) and WS₂ nanotube device (b); (c) I–V characteristics recorded at different illumination intensities; (d) dependence of I_sc on P_laser for three different wavelengths. The bottom right inset illustrates possible excitation paths from the valence band (VB) to the conduction band (CB) for each wavelength^[56].

图 5  (a) 二维CuInP₂S₆ BPVE器件图像及器件表面短路电流分布图; (b) 二维CuInP₂S₆ BPVE器件在明暗条件下的J-V输出曲线; (c) 二维CuInP₂S₆器件分别在经过正向极化、 无极化和反向极化后的J-V输出曲线; (d) BPVE性能随CuInP₂S₆厚度的变化关系; (e) 开路电压随温度的变化关系^[57]

Figure 5.  (a) The optical image and corresponding short-circuit photocurrent density mapping of the two dimensional CuInP₂S₆ BPVE device; (b) the characteristic output I-V curves of the two dimensional CuInP₂S₆ BPVE device at dark and bright conditions; (c) output J-V curves at specific poling voltages with the positively, zero voltage, and negatively poled respectively; (d) the thickness dependent BPVE in CuInP₂S₆; (e) the open-circuit voltage as a function of the temperature, the V_oc vanishes when the temperature increases to the phase transition temperature at about 315 K^[57].

图 6  (a) 单层1T_d WTe₂晶体结构示意图及对称性分析; (b) 双栅极单层WTe₂器件的结构示意图及光学图像; (c) 红、黑和蓝3个位置处, 光电流$I_{\hat{a}} $随激光偏振态的依赖关系, 插图分别为光电流$I_{\hat{a}} $与${\hat{a}}\text{-}{\hat{b}} $平面内位置关系; (d) 不同位移场极化下的圆偏振光伏效应电流, T = 20 K^[58]

Figure 6.  (a) Crystal structure monolayer 1T_d WTe₂; (b) schematic and optical image of a dual-gated monolayer WTe₂ device; (c) polarization-dependent $I_{\hat{a}} $ with the light spot fixed at the red, black, and blue dots shown in the inset, inset depicts the photocurrent along ${\hat{b}} $ with linear polarized light as a function of the beam spot location in the ${\hat{a}}\text{-}{\hat{b}} $ plane; (d) polarization-dependent circular photo galvanic effect currents for different displacement fields at T = 20 K^[58].

图 7  TDBG光探测器输运特性　(a) TDBG光探测器示意图; (b) 在不同栅极偏置电压(V_BG, V_TG)条件下线性BPVE光伏电压随激发光源偏振角度依赖关系; (c) T = 79 K, λ = 5 μm时, 不同栅极偏置电压下TDBG中的可调谐圆偏振BPVE; (d) 5 μm椭圆偏振光(χ = 36.5°, ψ = 110°)激发产生光电压(V_ph)分布图, 插图中χ 和 ψ分别为偏振椭圆的椭圆率和方位角^[62]

Figure 7.  Transport properties of the TDBG photodetector: (a) Schematic of the TDBG photo detector; (b) linear BPVE voltage(V_ph) as a function of polarization angle at a set of fixed gate voltage biases (V_BG, V_TG), the data are fitted by using V_ph=V_Ccos(2ψ)+V_S sin(22ψ)+V_const; (c) circular BPVE photovoltage (V_ph) as a function of the angle of the quarter-wave plate (θ) at different gate voltage biases(V_BG, V_TG), measured at T = 79 K and λ = 5 μm; (d) photovoltage mapping excited by elliptically polarized light at 5 μm, with χ = 36.5° and ψ = 110°. χ and ψ are the ellipticity and orientation angles of the polarization ellipse in the inset, respectively^[62]

图 8  (a) 双层MoS₂的不同堆叠方式(2H和3R)晶体结构及石墨烯/3R-MoS₂/石墨烯异质结隧道结器件结构示意图; (b) 双层3R-MoS₂器件图片及光电流分布图像(白色虚线内部); (c) 双层3R-MoS₂的两种可能堆叠畴结构(左)及器件中不同畴位置处光电流分布图像(右); (d) AB畴位光电流大小随着偏置电压及激光强度的依赖关系^[63]

Figure 8.  (a) Schematic of H stacking (2H) and R stacking (3R) of bilayer MoS₂ and the tunneling junction device (composed of graphene/3R-MoS₂/graphene heterostructure); (b) optical image of the BPVE device and scanning photovoltaic current map of BPVE device (consisting of one, two and three layers); (c) schematic of two possible stacking domains (AB and BA) of a 3R bilayer MoS₂ (left) and the scanning photo voltaic current map of device (right), the positive and negative photo response areas correspond to the AB and BA domains with almost symmetric responsivity; (d) bias voltage dependence of the photovoltaic current in the AB domain at different laser powers between 10 and 70 µW^[63].

图 9  (a)单层WSe₂/BP异质结晶体结构示意图; WSe₂/BP异质结器件图像(b)和沿着器件中ab直线的光电流分布关系(c); WSe₂/BP异质结器件图像(d)与器件沿E1-E2光电流分布(e); (f) 线偏振体光伏光电流与激光功率的依赖关系^[64]

Figure 9.  Schematic illustrations of hetero interface of WSe₂/BP (the mirror planes of both WSe₂ and BP are parallel); WSe₂/BP device (b) and photocurrent mapping in device along ab direction (c); WSe₂/BP device (d) and photocurrent mapping in device along the E1 and E2 electrodes (e); (f) laser power P dependence of the photocurrent I for two different wavelengths of 632.8 nm and 532 nm^[64].

图 10  CrI₃器件的光伏响应　(a) 4层CrI₃(AFM基态)异质结器件示意图; (b) 4层CrI₃异质结器件的光电流随外磁场强度的变化曲线; (c) 3层CrI₃异质结器件中光电流随1/4玻片角度变化曲线; (d) 差分光电流$I_{\rm ph}(\sigma^+) - I_{\rm ph} (\sigma^-) $随外磁场的变化曲线^[65]

Figure 10.  Photocurrent response of CrI₃ junction device: (a) Schematic of a four layer CrI₃ junction device in AFM ground state (↑↓↑↓); (b) photocurrent as a function of external magnetic field (H) measured from the four layer CrI₃ junction device; (c) photocurrent as a function of quarter-wave plate angle for ↑↑↑ state (2 T) and ↓↓↓ state (–2 T) measured from the trilayer CrI₃ junction device; (d) the change in photocurrent $I_{\rm ph}(\sigma^+) - I_{\rm ph} (\sigma^-) $as a function of μ₀H measured from the same device^[65].

图 11  (a) 相变材料混合系统中二维材料应变梯度工程示意图及二维材料中的应变梯度曲线; (b) VO₂/MoS₂异质结中MoS₂拉曼$ {\text{E}}_{{\text{2g}}}^{1} $模式映射图; (c) VO₂/MoS₂异质结器件结构示意图及器件在激光照射下光斑1 (Laser@1)和光斑2 (Laser@2)及暗态时的I-V曲线; (d) 405 nm激光照射下器件中 3 (Laser@3)和4 (Laser@4)处短路电流的偏振依赖性^[44]

Figure 11.  (a) Strain-gradient engineering of a 2D material by using a phase-change material in a hybrid system, on a reversible structural phase transition between phase I and phase II, strain gradients are generated in the 2D material at the edge of the phase-change material, inducing shifts of electron charge centers (dipole moments), the strain plot illustrates strain gradients in the 2D material(bottom panel); (b) Raman mapping of $ {\text{E}}_{{\text{2g}}}^{1} $ mode of MoS₂ on a VO₂/MoS₂ device; (c) the schematic diagram of VO₂/MoS₂ device and current-voltage curves of the device under laser illumination at spot 1 (Laser@1) and 2 (Laser@2) and dark conditions; (d) light polarization dependence of the short-circuit current under laser (405 nm) illumination at spots 3 (Laser@3) and 4 (Laser@4) in a device^[44].