Abstract

We report a joint experimental and theoretical investigation of the high pressure structural and vibrational properties of terbium sesquioxide (Tb2O3). Powder X-ray diffraction and Raman scattering measurements show that cubic Ia3̅ (C-type) Tb2O3 undergoes two phase transitions up to 25 GPa. We observe a first irreversible reconstructive transition to the monoclinic C2/m (B-type) phase at ∼7 GPa and a subsequent reversible displacive transition from the monoclinic to the trigonal P3̅m1 (A-type) phase at ∼12 GPa. Thus, Tb2O3 is found to follow the well-known C → B → A phase transition sequence found in other cubic rare earth sesquioxides with cations of larger atomic mass than Tb. Our ab initio theoretical calculations predict phase transition pressures and bulk moduli for the three phases in rather good agreement with experimental results. Moreover, Raman-active modes of the three phases have been monitored as a function of pressure, while lattice-dynamics calculations have allowed us to confirm the assignment of the experimental phonon modes in the C- and A-type phases as well as to make a tentative assignment of the symmetry of most vibrational modes in the B-type phase. Finally, we extract the bulk moduli and the Raman-active mode frequencies together with their pressure coefficients for the three phases of Tb2O3. These results are thoroughly compared and discussed in relation to those reported for rare earth and other related sesquioxides as well as with new calculations for selected sesquioxides. It is concluded that the evolution of the volume and bulk modulus of all the three phases of these technologically relevant compounds exhibit a nearly linear trend with respect to the third power of the ionic radii of the cations and that the values of the bulk moduli for the three phases depend on the filling of the f orbitals.

Highlights

  • Rare earth (RE) sesquioxides (SOs), in particular lanthanideSOs (Ln2O3; Ln = La to Lu, Y, and Sc), are an important family of materials due to their remarkable fundamental properties and potential applications

  • The bixbyite structure is an intermediate observed that all the scans from 0 to ∼7 GPa are dominated by peaks of the C-type phase

  • We have reported a joint experimental and theoretical study of the structural and vibrational properties of cubic terbium sesquioxide at high pressure

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Summary

Introduction

SOs (Ln2O3; Ln = La to Lu, Y, and Sc), are an important family of materials due to their remarkable fundamental properties and potential applications. These compounds are highly interesting and versatile for different types of applications because the Ln radius can be finely tuned along the lanthanide family with the filling of f orbitals, enabling a wide range of technological advances including light emitters (lasers and improved phosphors), catalysts, and high-dielectric constant (high-k) gates. Terbium sesquioxide y(Teabr2sOa3s)ahhaisgha-tktramcatetedricaol1n−s3idaenrdabalelsoatatsenatnioanctiinvethmeatpearsiat l few for optical insulators and high-performance optoelectronic devices.[4−6] It is well-known that RE SOs exhibit three polymorphic modifications at room conditions, depending on the RE radius:. Tb2O3 was observed to undergo the Received: March 19, 2020 Published: June 25, 2020

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