Two-dimensional
organic–inorganic lead halide perovskites
are generating great interest due to their optoelectronic characteristics
such as high solar energy conversion efficiency and a tunable direct
band gap in the visible regime. However, the presence of defect states
within the two-dimensional crystal structure can affect these properties,
resulting in changes to their band gap emission as well as the emergence
of nonlinear optical phenomena. Here, we have investigated the effects
of the presence of defect states on the nonlinear optical phenomena
of the 2D hybrid perovskite (BA)2(MA)2Pb3Br10. When two pulses, one narrowband pump pulse
centered at 800 nm and one supercontinuum pulse with bandwidth from
800–1100 nm, are incident on a perovskite flake, degenerate
four-wave mixing (FWM) occurs, with peaks corresponding to the energy
levels of the defect states present within the crystal. The longer
carrier lifetime of the defect state, in comparison to that of virtual
transitions that take place in nonresonant FWM processes, allows for
a larger population of electrons to be excited by the second pump
photon, resulting in increased FWM signal at the defect energy levels.
The quenching of the two-photon luminescence as flake thickness increases
is also observed and attributed to the increased presence of defects
within the flake at larger thicknesses. This technique shows the potential
of detecting defect energy levels in crystals using FWM for a variety
of optoelectronic applications.
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