Publications by authors named "Thomas C Rossi"
Article Synopsis
- Ferrocene is an important electron donor, and understanding its excited states is crucial for creating effective donor-acceptor (D-A) molecules with stable charge transfer states.
- Research using femtosecond optical transient absorption spectroscopy has identified two electronic excited states in a bimetallic D-A compound, with lifetimes of 30 ps and 500 ps, revealing a high-spin (d-d) state that is typically underrepresented in discussions about ferrocene.
- X-ray transient absorption spectroscopy further confirmed the high-spin character of the state with a 500 ps lifetime, indicating notable structural changes that are significant for improving the design of ferrocene-based materials in photocatalysis and photovoltaics.
Photoassisted catalysis using Ni complexes is an emerging field for cross-coupling reactions in organic synthesis. However, the mechanism by which light enables and enhances the reactivity of these complexes often remains elusive. Although optical techniques have been widely used to study the ground and excited states of photocatalysts, they lack the specificity to interrogate the electronic and structural changes at specific atoms.
View Article and Find Full Text PDFDisentangling electronic and thermal effects in photoexcited perovskite materials is crucial for photovoltaic and optoelectronic applications but remains a challenge due to their intertwined nature in both the time and energy domains. In this study, we employed temperature-dependent variable-angle spectroscopic ellipsometry, density functional theory calculations, and broadband transient absorption spectroscopy spanning the visible to mid-to-deep-ultraviolet (UV) ranges on MAPbBr thin films. The use of deep-UV detection opens a new spectral window that enables the exploration of high-energy excitations at various symmetry points within the Brillouin zone, facilitating an understanding of the ultrafast responses of the UV bands and the underlying mechanisms governing them.
View Article and Find Full Text PDFUnderstanding the electronic structure and dynamics of semiconducting nanomaterials at the atomic level is crucial for the realization and optimization of devices in solar energy, catalysis, and optoelectronic applications. We report here on the use of ultrafast X-ray linear dichroism spectroscopy to monitor the carrier dynamics in epitaxial ZnO nanorods after band gap photoexcitation. By rigorously subtracting out thermal contributions and conducting calculations, we reveal an overall depletion of absorption cross sections in the transient X-ray spectra caused by photogenerated charge carriers screening the core-hole potential of the X-ray absorbing atom.
View Article and Find Full Text PDFArticle Synopsis
- The study focuses on understanding how charge carriers interact with the polar lattice in CsPbBr perovskites under nonequilibrium conditions, essential for developing advanced optoelectronic devices.
- Researchers identify a specific polaronic distortion caused by electron-phonon coupling, leading to significant lattice changes when exposed to light, which they quantify with high precision.
- By combining time-resolved and temperature-dependent X-ray studies, the researchers demonstrate that structural deformations at Br and Pb sites are linked to carrier recombination, rather than just thermal effects.