info:eu-repo/semantics/article
Giant and Tunable Optical Nonlinearity in Single-Crystalline 2D Perovskites due to Excitonic and Plasma Effects
Fecha
2019-07Registro en:
Abdelwahab, Ibrahim; Dichtl, Paul; Grinblat, Gustavo Sergio; Leng, Kai; Chi, Xiao; et al.; Giant and Tunable Optical Nonlinearity in Single-Crystalline 2D Perovskites due to Excitonic and Plasma Effects; Wiley VCH Verlag; Advanced Materials; 31; 29; 7-2019; 1-8
0935-9648
CONICET Digital
CONICET
Autor
Abdelwahab, Ibrahim
Dichtl, Paul
Grinblat, Gustavo Sergio
Leng, Kai
Chi, Xiao
Park, In-Hyeok
Nielsen, Michael P.
Oulton, Rupert F.
Loh, Kian Ping
Maier, Stefan A.
Resumen
Materials with large optical nonlinearity, especially in the visible spectral region, are in great demand for applications in all-optical information processing and quantum optics. 2D hybrid Ruddlesden−Popper-type halide perovskites (RPPs) with tunable ultraviolet-to-visible direct bandgaps exhibit large nonlinear optical responses due to the strong excitonic effects present in their multiple quantum wells. Using a microscopic Z-scan setup with femtosecond laser pulses tunable across the visible spectrum, it is demonstrated that single-crystalline lead halide RPP nanosheets possess unprecedentedly large nonlinear refraction and absorption coefficients near excitonic resonances. A room-temperature insulator (exciton)–metal (plasma) Mott transition is found to occur near the exciton resonance of the thinnest qunatum-well RPPs, boosting the nonlinear response. Owing to the rapidly changing refractive index near resonance, a single RPP crystal can exhibit different nonlinear functionalities across the excitation spectrum. The results suggest that RPPs are efficient nonlinear materials in the visible waveband, indicating their potential use in integrated nonlinear photonic applications such as optical modulation and switching.