Growth of nanostructured ZnTe thin films through annealing of the MSELD-prepared stack of precursors for photonic applications

IF 3.8 Q2 CHEMISTRY, PHYSICAL

Chemical Physics Impact Pub Date : 2025-01-23 DOI:10.1016/j.chphi.2025.100837

Dimple Singh, Naresh Padha, Zakir Hussain, Zahoor Ahmed, Padma Dolma

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Abstract

ZnTe thin films were developed by annealing a stack of precursors deposited using the multisource sequentially evaporated layer deposition method. The deposition was carried out via thermal evaporation in a vacuum of 2 × 10^–4 Pa. Annealing was performed at temperatures ranging from 373 K to 573 K under a vacuum of 1 × 10^–1 Pa. Structural studies of the as-deposited stack and the films grown on annealing were conducted using X-ray diffraction (XRD). At lower temperatures (373 K and 473 K), the samples exhibited a mixture of ZnTe, Zn, and Te phases. However, at 573 K, a single phase of ZnTe was observed, providing a most significant (111) peak and an impurity peak corresponding to zinc at (002). The ZnTe phase exhibited a cubic crystal structure with a space group of F43 m [213], having a unit cell parameter of a = 6.129 Å and a cell volume of 230 Å³. The Raman spectra of the films grown at 573 K showed peaks at wave numbers of 206, 410, and 616 cm^-1, which are attributed to the first, second, and third orders of longitudinal optical (LO) phonon scattering in the ZnTe phase, thus, indicating improved crystallinity of the thin films at this temperature. The direct bandgap values of the films range from 0.67 eV to 1.24 eV at annealing temperatures from 373 to 573 K. Additionally, these films demonstrate a strong absorption coefficient (α) in the range of 2.6 × 10⁴ - 2 × 10⁵ cm⁻¹. These layers displayed a single-phase ZnTe nanostructure with a resistivity of 0.381 Ω·cm and a mobility of 34.7 cm²/V·s, making them suitable for use as an absorber layer in solar cell structures. Consequently, the ZnTe thin films offered potential applications in various photonic devices and served as a viable alternative for absorber layers in solar cell structures.

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通过mseld制备的光子前驱体堆栈的退火生长纳米结构ZnTe薄膜

采用多源顺序蒸发层沉积法，对沉积的前驱体进行退火制备了ZnTe薄膜。在2 × 10-4 Pa的真空中通过热蒸发进行沉积。退火温度为373 ~ 573 K，真空为1 × 10-1 Pa。利用x射线衍射（XRD）对沉积层和退火生长薄膜的结构进行了研究。在较低温度下（373 K和473 K），样品呈现出ZnTe、Zn和Te相的混合物。然而，在573 K时，观察到单相ZnTe，提供了一个最显著的（111）峰和一个杂质峰，对应于锌（002）。ZnTe相为立方晶体结构，空间群为F43 m[213]，晶胞参数a = 6.129 Å，晶胞体积为230 Å3。在573 K下生长的薄膜的拉曼光谱显示出波数为206、410和616 cm-1的峰值，这是由于ZnTe相中纵向光学（LO）声子的一、二、三阶散射，因此表明在该温度下薄膜的结晶度有所提高。在373 ~ 573 K的退火温度下，薄膜的直接带隙值为0.67 ~ 1.24 eV。此外，这些薄膜显示出很强的吸收系数（α），范围为2.6 × 10⁴- 2 × 10 cm⁻¹。这些层显示出单相ZnTe纳米结构，电阻率为0.381 Ω·cm，迁移率为34.7 cm²/V·s，适合用作太阳能电池结构中的吸收层。因此，ZnTe薄膜在各种光子器件中提供了潜在的应用，并作为太阳能电池结构中吸收层的可行替代品。

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