Your search keyword '"perovskite quantum wells"' showing total 3 results

1. Vibrational relaxation dynamics in layered perovskite quantum wells

Author

Quan, Li Na, Park, Yoonjae, Guo, Peijun, Gao, Mengyu, Jin, Jianbo, Huang, Jianmei, Copper, Jason K, Schwartzberg, Adam, Schaller, Richard, Limmer, David T, and Yang, Peidong

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry, layered perovskites, coherent phonon, dynamic disorder, perovskite quantum wells, &nbsp, Ruddlesden-Popper perovskites, Ruddlesden–Popper perovskites

Abstract

Organic-inorganic layered perovskites, or Ruddlesden-Popper perovskites, are two-dimensional quantum wells with layers of lead-halide octahedra stacked between organic ligand barriers. The combination of their dielectric confinement and ionic sublattice results in excitonic excitations with substantial binding energies that are strongly coupled to the surrounding soft, polar lattice. However, the ligand environment in layered perovskites can significantly alter their optical properties due to the complex dynamic disorder of the soft perovskite lattice. Here, we infer dynamic disorder through phonon dephasing lifetimes initiated by resonant impulsive stimulated Raman photoexcitation followed by transient absorption probing for a variety of ligand substitutions. We demonstrate that vibrational relaxation in layered perovskite formed from flexible alkyl-amines as organic barriers is fast and relatively independent of the lattice temperature. Relaxation in layered perovskites spaced by aromatic amines is slower, although still fast relative to bulk inorganic lead bromide lattices, with a rate that is temperature dependent. Using molecular dynamics simulations, we explain the fast rates of relaxation by quantifying the large anharmonic coupling of the optical modes with the ligand layers and rationalize the temperature independence due to their amorphous packing. This work provides a molecular and time-domain depiction of the relaxation of nascent optical excitations and opens opportunities to understand how they couple to the complex layered perovskite lattice, elucidating design principles for optoelectronic devices.

Published

2021

2. Perovskite Quantum Wells Formation Mechanism for Stable Efficient Perovskite Photovoltaics—A Real‐Time Phase‐Transition Study

Author

Hu, Hanlin, Qin, Minchao, Fong, Patrick WK, Ren, Zhiwei, Wan, Xuejuan, Singh, Mriganka, Su, Chun‐Jen, Jeng, U‐Ser, Li, Liang, Zhu, Jiajie, Yuan, Mingjian, Lu, Xinhui, Chu, Chih‐Wei, and Li, Gang

Subjects

perovskite photovoltaics, perovskite quantum wells, phase&#8208, transitions, phase-transitions, Physical Sciences, Chemical Sciences, Engineering, Nanoscience & Nanotechnology

Abstract

The combination of a bulk 3D perovskite layer and a reduced dimensional perovskite layer (perovskite quantum wells (PQWs)) is demonstrated to enhance the performance of perovskite solar cells (PSCs) significantly in terms of stability and efficiency. This perovskite hierarchy has attracted intensive research interest; however, the in-depth formation mechanism of perovskite quantum wells on top of a 3D perovskite layer is not clearly understood and is therefore the focus of this study. Along with ex situ morphology and photophysical characterization, the time-resolved grazing-incidence wide-angle X-ray scattering (TS-GIWAXS) technique performed in this study provides real-time insights on the phase-transition during the organic cation (HTAB ligand molecule) coating and PQWs/3D architecture formation process. A strikingly strong ionic reaction between the 3D perovskite and the long-chain organic cation leads to the quick formation of an ordered intermediate phase within only a few seconds. The optimal PQWs/3D architecture is achieved by controlling the HTAB casting, which is assisted by time-of-flight SIMS characterization. By controlling the second ionic reaction during the long-chain cation coating process, along with the fluorinated poly(triarylamine) (PTAA) as a hole-transport layer, the perovskite solar cells demonstrate efficiencies exceeding 22% along with drastically improved device stability.

Published

2021

3. Perovskite Quantum Wells Formation Mechanism for Stable Efficient Perovskite Photovoltaics-A Real-Time Phase-Transition Study.

Author

Hu, Hanlin, Qin, Minchao, Fong, Patrick WK, Ren, Zhiwei, Wan, Xuejuan, Singh, Mriganka, Su, Chun-Jen, Jeng, U-Ser, Li, Liang, Zhu, Jiajie, Yuan, Mingjian, Lu, Xinhui, Chu, Chih-Wei, and Li, Gang

Subjects

perovskite photovoltaics, perovskite quantum wells, phase-transitions, phase&#8208, transitions, Nanoscience & Nanotechnology, Physical Sciences, Chemical Sciences, Engineering

Abstract

The combination of a bulk 3D perovskite layer and a reduced dimensional perovskite layer (perovskite quantum wells (PQWs)) is demonstrated to enhance the performance of perovskite solar cells (PSCs) significantly in terms of stability and efficiency. This perovskite hierarchy has attracted intensive research interest; however, the in-depth formation mechanism of perovskite quantum wells on top of a 3D perovskite layer is not clearly understood and is therefore the focus of this study. Along with ex situ morphology and photophysical characterization, the time-resolved grazing-incidence wide-angle X-ray scattering (TS-GIWAXS) technique performed in this study provides real-time insights on the phase-transition during the organic cation (HTAB ligand molecule) coating and PQWs/3D architecture formation process. A strikingly strong ionic reaction between the 3D perovskite and the long-chain organic cation leads to the quick formation of an ordered intermediate phase within only a few seconds. The optimal PQWs/3D architecture is achieved by controlling the HTAB casting, which is assisted by time-of-flight SIMS characterization. By controlling the second ionic reaction during the long-chain cation coating process, along with the fluorinated poly(triarylamine) (PTAA) as a hole-transport layer, the perovskite solar cells demonstrate efficiencies exceeding 22% along with drastically improved device stability.

Published

2021