Your search keyword '"Climent, Clàudia"' showing total 4 results

1. Influence of Quadrupolar Molecular Transitions within Plasmonic Cavities

Author

Huang, Junyang, Ojambati, Oluwafemi S., Climent, Clàudia, Cuartero-Gonzalez, Alvaro, Elliott, Eoin, Feist, Johannes, Fernández-Domínguez, Antonio I., and Baumberg, Jeremy J.

Abstract

Optical nanocavities have revolutionized the manipulation of radiative properties of molecular and semiconductor emitters. Here, we investigate the amplified photoluminescence arising from exciting a dark transition of β-carotene molecules embedded within plasmonic nanocavities. Integrating a molecular monolayer into nanoparticle-on-mirror nanostructures unveils enhancements surpassing 4 orders of magnitude in the initially light-forbidden excitation. Such pronounced enhancements transcend conventional dipolar mechanisms, underscoring the presence of alternative enhancement pathways. Notably, Fourier-plane scattering spectroscopy shows that the photoluminescence excitation resonance aligns with a higher-order plasmonic cavity mode, which supports strong field gradients. Combining quantum chemistry calculations with electromagnetic simulations reveals an important interplay between the Franck–Condon quadrupole and Herzberg–Teller dipole contributions in governing the absorption characteristics of this dark transition. In contrast to free space, the quadrupole moment plays a significant role in photoluminescence enhancement within nanoparticle-on-mirror cavities. These findings provide an approach to access optically inactive transitions, promising advancements in spectroscopy and sensing applications.

Published

2024

2. Correction to “A Practical Approach to Wave Function Propagation, Hopping Probabilities, and Time Steps in Surface Hopping Calculations”

Author

Qiu, Tian, Climent, Clàudia, and Subotnik, Joseph E.

Published

2023

3. A Practical Approach to Wave Function Propagation, Hopping Probabilities, and Time Steps in Surface Hopping Calculations

Author

Qiu, Tian, Climent, Clàudia, and Subtonik, Joseph E.

Abstract

We compare several established approaches for propagating wave functions and calculating hopping probabilities within the fewest switches surface hopping (FSSH) algorithm for difficult cases with many electronic states and many trivial crossings. If only a single time step (Δtc) is employed, we find that no published approach can accurately capture the dynamics correctly unless Δtc→ 0 (which is not computationally feasible). If multiple time steps are employed, for a fixed classical time step (Δtc), a robust scheme can be found for dynamically choosing quantum time steps (δtq1and δtq2) and calculating hopping probabilities so that one can systematically reduce all errors and achieve maximally efficient accuracy; scattering calculations confirm that one can choose a fairly large classical time step. The robust scheme presented here uses both the “local diabatic” and adiabatic interpolation and thus borrows elements from both the Granucci/Persico and Meek/Levine algorithms. Our findings should be broadly applicable in the future.

Published

2023

4. Spin–Orbit versus Hyperfine Coupling-Mediated Intersystem Crossing in a Radical Pair

Author

May, Sam R., Climent, Clàudia, Tao, Zhen, Vinogradov, Sergei A., and Subotnik, Joseph E.

Abstract

While spin–orbit coupling (SOC) is typically the dominant interaction that couples singlet and triplet states within individual chromophores, hyperfine coupling (HFC) becomes important in multichromophoric systems, particularly in relation to the radical pair mechanism. Here, we use TD-DFT to calculate the spin–orbit coupling and hyperfine coupling between the first singlet and triplet charge transfer states of the radical pair 2Pyrene–and 2N,N-dimethylaniline+. We show that, as the intermolecular donor–acceptor distance grows, SOC decays to zero (as one would expect) because singlet and triplet states are characterized by identical orbitals in space, while the HFC remains comparatively constant. The switching region occurs around 4 Å, beyond which HFC dominates over SOC as far as defining the rate of intersystem crossing (ISC).

Published

2023