Adam Babinski1,Igor Antoniazzi1,Amit Pawbake2,Natalia Zawadzka1,Magdalena Grzeszczyk3,Tomasz Wozniak1,Jordi Ibanez4,Zahir Muhammad5,Weisheng Zhao5,Clement Faugeras2,Maciej Molas1
University of Warsaw1,LNCMI2,National University of Singapore3,Geosciences Barcelona4,Beihang University5
Adam Babinski1,Igor Antoniazzi1,Amit Pawbake2,Natalia Zawadzka1,Magdalena Grzeszczyk3,Tomasz Wozniak1,Jordi Ibanez4,Zahir Muhammad5,Weisheng Zhao5,Clement Faugeras2,Maciej Molas1
University of Warsaw1,LNCMI2,National University of Singapore3,Geosciences Barcelona4,Beihang University5
Layered van der Waals crystals are an exciting class of materials of properties, which strongly depend on their thickness. Their structure makes them very sensitive to the interlayer spacing, which can be modulated by temperature or strain.This motivates the recent interest in the strain engineering as an effective way to modify their mechanical, optical, and electronic properties.<br/>We have addressed the effect of pressure on hafnium disulphide (HfS2), material of promising electrical properties. We study Raman scattering (RS) in bulk HfS<sub>2</sub> using λ=632.8 nm (1.96 eV) and λ=561 nm (2.21 eV) at room temperature under pressure up to 10 GPa. A methanol-ethanol mixture or crystallographic oil were used in our diamond anvil cell (DAC) as the pressure transmitting medium (PTM).<br/>HfS<sub>2</sub> under ambient conditions adopts the 1T octahedral structure with the RS spectrum dominated by the out-of-plane A<sub>1g</sub> mode.<br/>A systematic pressure-induced blue-shift of the RS features in the spectrum was observed when hydrostatic conditions of pressure were supported by a methanol-ethanol mixture as PTM, confirming that no phase transition occurred in HfS<sub>2</sub> up to 10 GPa.<br/>On the contrary, seven new modes appeared in the RS spectrum around P=7 GPa when crystallographic oil was used as PTM. The non-hydrostatic component of pressure in that case, which emerged around P=4 GPa was deduced from the characteristic splitting of ruby-related photoluminescence lines. Both ”low-pressure” and ”high pressure”-related peaks coexisted in the RS spectrum up to P=10 GPa with the former features systematically decreasing their intensity. The ”high-pressure” peaks were observed under decompression down to P=1.2 GPa pointing out to a metastability of the observed transition.<br/>Polarization angle-resolved measurements were performed at 7.4 GPa to study properties of all the observed RS peaks. A strong anisotropy of the RS for both the mode, evolving from the A<sub>1g </sub>symmetry vibrations and the ”high pressure” modes was observed. Moreover, the effect of excitation energy on the anisotropy was clearly appreciated. In particular for the A<sub>1g</sub>-related mode, the two-fold (four-fold) polar symmetry of the RS intensity for co- and cross-polarization conditions was observed for l=561 nm (l=632.8 nm) excitation.<br/>We conclude that the observed evolution of the RS spectra under pressure corresponds to the partial phase transition in HfS<sub>2</sub>. The transition was triggered around P=7 GPa by the non-hydrostatic component of pressure. Both phases coexist up to P=10 GPa and upon decompression down to P=1.2 GPa. The anisotropy of the RS polar dependence at P=7.4 GaP points out to the distortion of crystal lattice in both co-existing phases. The effect of excitation energy on the A<sub>1g</sub>-related mode was explained in terms of the non-resonant (λ=632.8 nm) and resonant λ=561 nm) excitation conditions. Our results confirm the critical effect of the PTM on the pressure-induced phase transition in HfS<sub>2</sub>, as revealed by the RS spectroscopy.