Alloy-induced reduction and anisotropy change of lattice thermal conductivity in Ruddlesden- Popper phase halide perovskites

Alloy-induced reduction and anisotropy change of lattice thermal conductivity in Ruddlesden- Popper phase halide perovskites

The effective modulation of the thermal conductivity of halide perovskites is of great importance in optimizing their optoelectronic device performance. Based on first-principles lattice dynamics calculations, we found that alloying at the B and X sites can significantly modulate the thermal transpo...

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Bibliographic Details
Published in:Frontiers of physics Vol. 18; no. 6; p. 63304
Main Authors: Mu, Huimin, Zhou, Kun, Tian, Fuyu, Zhou, Yansong, Zhao, Guoqi, Fu, Yuhao, Zhang, Lijun
Format: Journal Article
Language:English
Published: Beijing Higher Education Press 01-12-2023
Springer Nature B.V
Subjects:
all-inorganic RP-phase halide perovskite alloys
Alloying
Anisotropy
Astronomy
Astrophysics and Cosmology
Atomic
Boltzmann transport
Condensed Matter Physics
First principles
first-principles lattice dynamics calculations
Heat conductivity
Heat transfer
Lattice vibration
Molecular
Optical and Plasma Physics
Optoelectronic devices
Particle and Nuclear Physics
Perovskites
Phonons
Physics
Physics and Astronomy
Research Article
Special Topic: Surface and Interface of Two-dimensional Materials
Thermal conductivity
Transport phenomena
Transport properties
Boltzmann transport
all-inorganic RP-phase halide perovskite alloys
first-principles lattice dynamics calculations
thermal conductivity
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Summary:The effective modulation of the thermal conductivity of halide perovskites is of great importance in optimizing their optoelectronic device performance. Based on first-principles lattice dynamics calculations, we found that alloying at the B and X sites can significantly modulate the thermal transport properties of 2D Ruddlesden−Popper (RP) phase halide perovskites, achieving a range of lattice thermal conductivity values from the lowest ( κ c = 0.05 W·m −1·K −1@Cs 4AgBiI 8) to the highest ( κ a / b = 0.95 W·m −1·K −1@Cs 4NaBiCl 4I 4). Compared with the pure RP-phase halide perovskites and three-dimensional halide perovskite alloys, the two-dimensional halide perovskite introduces more phonon branches through alloying, resulting in stronger phonon branch coupling, which effectively scatters phonons and reduces thermal conductivity. Alloying can also dramatically regulate the thermal transport anisotropy of RP-phase halide perovskites, with the anisotropy ratio ranging from 1.22 to 4.13. Subsequently, analysis of the phonon transport modes in these structures revealed that the lower phonon velocity and shorter phonon lifetime were the main reasons for their low thermal conductivity. This work further reduces the lattice thermal conductivity of 2D pure RP-phase halide perovskites by alloying methods and provides a strong support for theoretical guidance by gaining insight into the interesting phonon transport phenomena in these compounds.
Bibliography:Boltzmann transport
all-inorganic RP-phase halide perovskite alloys
Document received on :2023-04-19
first-principles lattice dynamics calculations
thermal conductivity
Document accepted on :2023-05-19
ISSN:2095-0462
2095-0470
DOI:10.1007/s11467-023-1315-1