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Optical Properties and Excited-State Dynamics of Atomically Precise Gold Nanoclusters (2021)

Zhou, Meng ; Jin, Rongchao

Annual Reviews

In: Annual Review of Physical Chemistry. 2021; 72(1): 121-142. Published 2021 Apr 20. doi: 10.1146/annurev-physchem-090419-104921.

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Publication Date: 2021-04-20

Description: Understanding the excited-state dynamics of nanomaterials is essential to their applications in photoenergy storage and conversion. This review summarizes recent progress in the excited-state dynamics of atomically precise gold (Au) nanoclusters (NCs). We first discuss the electronic structure and typical relaxation pathways of Au NCs from subpicoseconds to microseconds. Unlike plasmonic Au nanoparticles, in which collective electron excitation dominates, Au NCs show single-electron transitions and molecule-like exciton dynamics. The size-, shape-, structure-, and composition-dependent dynamics in Au NCs are further discussed in detail. For small-sized Au NCs, strong quantum confinement effects give rise to relaxation dynamics that is significantly dependent on atomic packing, shape, and heteroatom doping. For relatively larger-sized Au NCs, strong size dependence can be observed in exciton and electron dynamics. We also discuss the origin of coherent oscillations and their roles in excited-state relaxation. Finally, we provide our perspective on future directions in this area.

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Electronic ISSN: 1545-1593

Topics: Chemistry and Pharmacology , Physics

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α-Crystallins in the Vertebrate Eye Lens: Complex Oligomers and Molecular Chaperones (2021)

Sprague-Piercy, Marc A. ; Rocha, Megan A. ; Kwok, Ashley O. ; [et al.]

Annual Reviews

In: Annual Review of Physical Chemistry. 2021; 72(1): 143-163. Published 2021 Apr 20. doi: 10.1146/annurev-physchem-090419-121428.

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Publication Date: 2021-04-20

Description: α-Crystallins are small heat-shock proteins that act as holdase chaperones. In humans, αA-crystallin is expressed only in the eye lens, while αB-crystallin is found in many tissues. α-Crystallins have a central domain flanked by flexible extensions and form dynamic, heterogeneous oligomers. Structural models show that both the C- and N-terminal extensions are important for controlling oligomerization through domain swapping. α-Crystallin prevents aggregation of damaged β- and γ-crystallins by binding to the client protein using a variety of binding modes. α-Crystallin chaperone activity can be compromised by mutation or posttranslational modifications, leading to protein aggregation and cataract. Because of their high solubility and their ability to form large, functional oligomers, α-crystallins are particularly amenable to structure determination by solid-state nuclear magnetic resonance (NMR) and solution NMR, as well as cryo-electron microscopy.

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My Trajectory in Molecular Reaction Dynamics and Spectroscopy (2021)

Gerber, Robert Benny

Annual Reviews

In: Annual Review of Physical Chemistry. 2021; 72(1): 1-34. Published 2021 Apr 20. doi: 10.1146/annurev-physchem-090519-124238.

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Publication Date: 2021-04-20

Description: This is the story of a career in theoretical chemistry during a time of dramatic changes in the field due to phenomenal growth in the availability of computational power. It is likewise the story of the highly gifted graduate students and postdoctoral fellows that I was fortunate to mentor throughout my career. It includes reminiscences of the great mentors that I had and of the exciting collaborations with both experimentalists and theorists on which I built much of my research. This is an account of the developments of exciting scientific disciplines in which I was involved: vibrational spectroscopy, molecular reaction mechanisms and dynamics, e.g., in atmospheric chemistry, and the prediction of new, exotic molecules, in particular noble gas molecules. From my very first project to my current work, my career in science has brought me the excitement and fascination of research. What a wonderful pursuit!

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Topics: Chemistry and Pharmacology , Physics

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Critical Phenomena in Plasma Membrane Organization and Function (2021)

Shaw, Thomas R. ; Ghosh, Subhadip ; Veatch, Sarah L.

Annual Reviews

In: Annual Review of Physical Chemistry. 2021; 72(1): 51-72. Published 2021 Apr 20. doi: 10.1146/annurev-physchem-090419-115951.

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Publication Date: 2021-04-20

Description: Lateral organization in the plane of the plasma membrane is an important driver of biological processes. The past dozen years have seen increasing experimental support for the notion that lipid organization plays an important role in modulating this heterogeneity. Various biophysical mechanisms rooted in the concept of liquid–liquid phase separation have been proposed to explain diverse experimental observations of heterogeneity in model and cell membranes with distinct but overlapping applicability. In this review, we focus on the evidence for and the consequences of the hypothesis that the plasma membrane is poised near an equilibrium miscibility critical point. Critical phenomena explain certain features of the heterogeneity observed in cells and model systems but also go beyond heterogeneity to predict other interesting phenomena, including responses to perturbations in membrane composition.

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First-Principles Insights into Plasmon-Induced Catalysis (2021)

Martirez, John Mark P. ; Bao, Junwei Lucas ; Carter, Emily A.

Annual Reviews

In: Annual Review of Physical Chemistry. 2021; 72(1): 99-119. Published 2021 Apr 20. doi: 10.1146/annurev-physchem-061020-053501.

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Publication Date: 2021-04-20

Description: The size- and shape-controlled enhanced optical response of metal nanoparticles (NPs) is referred to as a localized surface plasmon resonance (LSPR). LSPRs result in amplified surface and interparticle electric fields, which then enhance light absorption of the molecules or other materials coupled to the metallic NPs and/or generate hot carriers within the NPs themselves. When mediated by metallic NPs, photocatalysis can take advantage of this unique optical phenomenon. This review highlights the contributions of quantum mechanical modeling in understanding and guiding current attempts to incorporate plasmonic excitations to improve the kinetics of heterogeneously catalyzed reactions. A range of first-principles quantum mechanics techniques has offered insights, from ground-state density functional theory (DFT) to excited-state theories such as multireference correlated wavefunction methods. Here we discuss the advantages and limitations of these methods in the context of accurately capturing plasmonic effects, with accompanying examples.

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Demystifying the Diffuse Vibrational Spectrum of Aqueous Protons Through Cold Cluster Spectroscopy (2021)

Zeng, Helen J. ; Johnson, Mark A.

Annual Reviews

In: Annual Review of Physical Chemistry. 2021; 72(1): 667-691. Published 2021 Apr 20. doi: 10.1146/annurev-physchem-061020-053456.

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Publication Date: 2021-04-20

Description: The ease with which the pH is routinely determined for aqueous solutions masks the fact that the cationic product of Arrhenius acid dissolution, the hydrated proton, or H+(aq), is a remarkably complex species. Here, we review how results obtained over the past 30 years in the study of H+⋅(H2O) n cluster ions isolated in the gas phase shed light on the chemical nature of H+(aq). This effort has also revealed molecular-level aspects of the Grotthuss relay mechanism for positive-charge translocation in water. Recently developed methods involving cryogenic cooling in radiofrequency ion traps and the application of two-color, infrared–infrared (IR–IR) double-resonance spectroscopy have established a clear picture of how local hydrogen-bond topology drives the diverse spectral signatures of the excess proton. This information now enables a new generation of cluster studies designed to unravel the microscopic mechanics underlying the ultrafast relaxation dynamics displayed by H+(aq).

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First-Principles Simulations of Biological Molecules Subjected to Ionizing Radiation (2021)

Omar, Karwan Ali ; Hasnaoui, Karim ; de la Lande, Aurélien

Annual Reviews

In: Annual Review of Physical Chemistry. 2021; 72(1): 445-465. Published 2021 Apr 20. doi: 10.1146/annurev-physchem-101419-013639.

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Publication Date: 2021-04-20

Description: Ionizing rays cause damage to genomes, proteins, and signaling pathways that normally regulate cell activity, with harmful consequences such as accelerated aging, tumors, and cancers but also with beneficial effects in the context of radiotherapies. While the great pace of research in the twentieth century led to the identification of the molecular mechanisms for chemical lesions on the building blocks of biomacromolecules, the last two decades have brought renewed questions, for example, regarding the formation of clustered damage or the rich chemistry involving the secondary electrons produced by radiolysis. Radiation chemistry is now meeting attosecond science, providing extraordinary opportunities to unravel the very first stages of biological matter radiolysis. This review provides an overview of the recent progress made in this direction, focusing mainly on the atto- to femto- to picosecond timescales. We review promising applications of time-dependent density functional theory in this context.

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Multiscale Models for Light-Driven Processes (2021)

Nottoli, Michele ; Cupellini, Lorenzo ; Lipparini, Filippo ; [et al.]

Annual Reviews

In: Annual Review of Physical Chemistry. 2021; 72(1): 489-513. Published 2021 Apr 20. doi: 10.1146/annurev-physchem-090419-104031.

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Publication Date: 2021-04-20

Description: Multiscale models combining quantum mechanical and classical descriptions are a very popular strategy to simulate properties and processes of complex systems. Many alternative formulations have been developed, and they are now available in all of the most widely used quantum chemistry packages. Their application to the study of light-driven processes, however, is more recent, and some methodological and numerical problems have yet to be solved. This is especially the case for the polarizable formulation of these models, the recent advances in which we review here. Specifically, we identify and describe the most important specificities that the polarizable formulation introduces into both the simulation of excited-state dynamics and the modeling of excitation energy and electron transfer processes.

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Optical Force-Induced Chemistry at Solution Surfaces (2021)

Masuhara, Hiroshi ; Yuyama, Ken-ichi

Annual Reviews

In: Annual Review of Physical Chemistry. 2021; 72(1): 565-589. Published 2021 Apr 20. doi: 10.1146/annurev-physchem-090419-044828.

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Publication Date: 2021-04-20

Description: When an intense 1,064-nm continuous-wave laser is tightly focused at solution surfaces, it exerts an optical force on molecules, polymers, and nanoparticles (NPs). Initially, molecules and NPs are gathered into a single assembly inside the focus, and the laser is scattered and propagated through the assembly. The expanded laser further traps them at the edge of the assembly, producing a single assembly much larger than the focus along the surface. Amino acids and inorganic ionic compounds undergo crystallization and crystal growth, polystyrene NPs form periodic arrays and disklike structures with concentric circles or hexagonal packing, and Au NPs demonstrate assembling and swarming, in which the NPs fluctuate like a group of bees. These phenomena that depend on laser polarization are called optically evolved assembling at solution surfaces, and their dynamics and mechanisms are elucidated in this review. As a promising application in materials science, the optical trapping assembly of lead halide perovskites, supramolecules, and aggregation-induced emission enhancement–active molecules is demonstrated and future directions for fundamental study are discussed.

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Control of Chemical Reaction Pathways by Light–Matter Coupling (2021)

Devasia, Dinumol ; Das, Ankita ; Mohan, Varun ; [et al.]

Annual Reviews

In: Annual Review of Physical Chemistry. 2021; 72(1): 423-443. Published 2021 Apr 20. doi: 10.1146/annurev-physchem-090519-045502.

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Publication Date: 2021-04-20

Description: Because plasmonic metal nanostructures combine strong light absorption with catalytically active surfaces, they have become platforms for the light-assisted catalysis of chemical reactions. The enhancement of reaction rates by plasmonic excitation has been extensively discussed. This review focuses on a less discussed aspect: the induction of new reaction pathways by light excitation. Through commentary on seminal reports, we describe the principles behind the optical modulation of chemical reactivity and selectivity on plasmonic metal nanostructures. Central to these phenomena are excited charge carriers generated by plasmonic excitation, which modify the energy landscape available to surface reactive species and unlock pathways not conventionally available in thermal catalysis. Photogenerated carriers can trigger bond dissociation or desorption in an adsorbate-selective manner, drive charge transfer and multielectron redox reactions, and generate radical intermediates. Through one or more of these mechanisms, a specific pathway becomes favored under light. By improved control over these mechanisms, light-assisted catalysis can be transformational for chemical synthesis and energy conversion.

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