Significant interest exists in lead trihalides that present the perovskite structure owing to their demonstrated potential in photovoltaic, lasing, and display applications. These materials are also notable for their unusual phase behavior often displaying easily accessible phase transitions. In this work, time-resolved X-ray diffraction, performed on perovskite cesium lead bromide nanocrystals, maps the lattice response to controlled excitation fluence. These nanocrystals undergo a reversible, photoinduced orthorhombic-to-cubic phase transition which is discernible at fluences greater than 0.34 mJ cm−2 through the loss of orthorhombic features and shifting of high-symmetry peaks. This transition recovers on the timescale of 510 ± 100 ps. A reversible crystalline-to-amorphous transition, observable through loss of Bragg diffraction intensity, occurs at higher fluences (greater than 2.5 mJ cm−2). These results demonstrate that light-driven phase transitions occur in perovskite materials, which will impact optoelectronic applications and enable the manipulation of non-equilibrium phase characteristics of the broad perovskite material class.
Metal nitrides are a promising non-toxic, inexpensive, and durable material for photothermal applications. The photothermal properties of titanium nitride are measured using time-resolved X-ray diffraction following optical excitation.
CuInSe2 nanocrystals offer promise for optoelectronics
including thin-film photovoltaics and printed electronics. Additive
manufacturing methods such as photonic curing controllably sinter
particles into quasi-continuous films and offer improved device performance.
To gain understanding of nanocrystal response under such processing
conditions, we investigate impacts of photoexcitation on colloidal
nanocrystal lattices via time-resolved X-ray diffraction. We probe
three sizes of particles and two capping ligands (oleylamine and inorganic
S2–) to evaluate resultant crystal lattice temperature,
phase stability, and thermal dissipation. Elevated fluences produce
heating and loss of crystallinity, the onset of which exhibits particle
size dependence. We find size-dependent recrystallization and cooling
lifetimes ranging from 90 to 200 ps with additional slower cooling
on the nanosecond time scale. Sulfide-capped nanocrystals show faster
recrystallization and cooling compared to oleylamine-capped nanocrystals.
Using these lifetimes, we find interfacial thermal conductivities
from 3 to 28 MW/(m2 K), demonstrating that ligand identity
strongly influences thermal dissipation.
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