图 1  (a) 单层(左图)和三层(右图)WTe₂的晶体结构. 单层中的黑点表示$ {C}_{2 a} $螺旋轴. 右图对比了将三层WTe₂进行$ {C}_{2 a} $操作之后的结构(阴影部分), 在第二层中无法与原结构重合, 因此双层与三层WTe₂均不具有中心对称性; (b) 不同厚度WTe₂的300 K拉曼光谱. 50 cm^–1以下和以上的光谱分别在垂直($ \perp $)和平行(//)偏振条件下获得. P0—P9为拉曼声子; (c), (d) P0, P1和P8峰位的厚度依赖, 由拟合图(b)中数据获得; (c)中实线为根据$\sqrt{1-\mathrm{cos}(\mathrm{\pi }/N)}$拟合的结果, N为层数

Fig. 1.  (a) Crystal structures of monolayer (left) and trilayer (right) WTe₂. The black dots in the monolayer structure indicate $ {C}_{2 a} $ screw rotation axes. The trilayer structure does not overlap with its counterpart after $ {C}_{2 a} $operation (shaded) in the second layer, meaning that bilayer and trilayer WTe₂ do not possess inversion symmetry. (b) Raman spectra of WTe₂ with thickness ranging from 1 to 4 layers, collected at 300 K. The spectral ranges below and above 50 cm^–1 are measured in the cross ($ \perp $) and parallel (//) polarization configurations, respectively. P0–P9 denote the observed Raman modes. (c), (d) Thickness dependence of the peak frequencies for P0, P1, and P8, obtained by fitting analysis of the data in Figure (b). The solid line in Figure (c) is a fit to $\sqrt{1-\mathrm{cos}(\mathrm{\pi }/N)}$, where N is the layer number.

图 2  (a)—(c) 1—3层 (1L—3L) WTe₂在平行偏振条件下的温度依赖拉曼散射强度图; (d)—(f) 分别为图(a)—(c)中300—460 cm^–1范围内在若干温度点的拉曼谱. 星号(*)标注的峰来自于蓝宝石衬底

Fig. 2.  (a)–(c) Temperature dependent Raman scattering intensity maps for monolayer, bilayer, and trilayer (1L–3L) WTe₂, measured in the parallel polarization configuration. (d)–(f) The corresponding spectra between 300 and 460 cm^–1 at selected temperatures. The peaks marked by the asterisks are from the sapphire substrate.

图 3  (a), (b) 双层 WTe₂样品在 4 K 的偏振角度依赖拉曼散射强度图, 分别在平行与垂直偏振条件下测得; (c) 各个拉曼峰的峰强随偏振角度的依赖. 实心与空心符号为实验数据, 实线为根据文中模型拟合的结果

Fig. 3.  (a), (b) Polarization angle dependent Raman scattering intensity maps for bilayer WTe₂, measured in the parallel and cross polarization configurations, respectively, at 4 K. (c) Polarization angle dependent intensity for each Raman mode. The filled and empty symbols are experimental data, and the solid lines are fits as described in the text.

图 4  (a) 机械剥离获得的WTe₂样品的光学照片. 数字和虚线分别代表样品的层数和不同厚度区域之间的分界线. 比例尺: 5 μm; (b), (c) 对图(a)中方框区域进行SHG扫描的成像图, 均在垂直偏振条件下获得, 入射光偏振方向分别对应于图(e)中的${30}^{\circ}$和${90}^{\circ}$; (d), (e) 单层WTe₂的偏振角度依赖SHG, 分别在平行($//$)和垂直($ \perp $)偏振条件下获得. 实线为根据正文中模型拟合的结果. 所有数据在4 K获得; (f) 上图为单层WTe₂在文献中普遍认为所具有的中心对称的$1{T}{'}$结构, 同图1(a). 下图为单层WTe₂中心对称性破缺的一种可能结构^[9], 称作${1{T}}_{{d}}$

Fig. 4.  (a) Optical image of mechanically exfoliated WTe₂, with layer numbers marked for the thin regions. The dashed lines represent the boundaries between regions of different thickness. Scale bar: 5 μm. (b)–(c) SHG intensity maps for the region marked by the square in (a), obtained in the cross polarization configuration, with the incident polarization angle set to ${30}^{\circ}$ and ${90}^{\circ}$ in (e), respectively. (d)–(e) Polarization angle dependent SHG for monolayer WTe₂, measured in the parallel ($//$) and cross ($ \perp $) polarization configurations, respectively. The solid lines are fits as discussed in the text. All data were obtained at 4 K. (f) The upper part is a schematic of the commonly adopted $1{T}{'}$ structure for monolayer WTe₂ (same as in Fig. 1(a)), which is centrosymmetric. The lower part shows a possible structure with broken inversion symmetry^[9], referred to as $ {1 T}_{d} $.

图 5  (a)—(d) 不同厚度WTe₂在4 K的偏振角度依赖SHG. 实心与空心符号对应的数据分别在平行($//$)与垂直($ \perp $)偏振条件下测得, 实线为根据正文中的模型拟合的结果; (e) 由图(a)—(d)中垂直偏振下的数据在0°—360°范围内积分得到的SHG强度的厚度依赖(双层2H-MoS₂的原始数据未给出)

Fig. 5.  (a)–(d) Polarization angle dependent SHG at 4 K for WTe₂ samples of various thickness. The filled and empty symbols represent data collected in the parallel ($//$) and cross ($ \perp $) polarization configurations, respectively. The solid lines are fits as described in the text. (e) Thickness dependence of the SHG, obtained by integrating the cross polarization data in Figure (a)–(d) from 0° to ${360}^{\circ}$. The raw data for bilayer 2H-MoS₂ are not shown.

图 6  实心符号为1—3层样品的SHG在垂直偏振下的温度依赖, 对应于左侧y轴. 空心符号为图2(b)中双层样品P11拉曼峰积分强度的温度依赖, 对应于右侧y轴

Fig. 6.  Left axis: temperature dependent SHG intensity for monolayer, bilayer, and trilayer WTe₂ in the cross polarization configuration, shown as filled circles. Right axis: temperature dependent integrated intensity for the P11 peak in the Raman spectra in Fig. 2(b) for bilayer WTe₂, shown as empty squares.