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1. A quantum dynamical study of the rotation of the dihydrogen ligand in the Fe(H) ₂ (H ₂ )(PEtPh ₂ ) ₃ coordination complex

   https://doi.org/10.1063/1.5026637  

   Gonzalez, Megan E.; Eckert, Juergen; Aquino, Adelia J.; Poirier, Bill (April 2018, The Journal of Chemical Physics)
2. The Dissolution Rate of CaCO ₃ in the Ocean

   https://doi.org/10.1146/annurev-marine-041720-092514  

   Adkins, Jess F.; Naviaux, John D.; Subhas, Adam V.; Dong, Sijia; Berelson, William M. (January 2021, Annual Review of Marine Science)

   null (Ed.)

   The dissolution of CaCO 3 minerals in the ocean is a fundamental part of the marine alkalinity and carbon cycles. While there have been decades of work aimed at deriving the relationship between dissolution rate and mineral saturation state (a so-called rate law), no real consensus has been reached. There are disagreements between laboratory- and field-based studies and differences in rates for inorganic and biogenic materials. Rates based on measurements on suspended particles do not always agree with rates inferred from measurements made near the sediment–water interface of the actual ocean. By contrast, the freshwater dissolution rate of calcite has been well described by bulk rate measurements from a number of different laboratories, fit by basic kinetic theory, and well studied by atomic force microscopy and vertical scanning interferometry to document the processes at the atomic scale. In this review, we try to better unify our understanding of carbonate dissolution in the ocean via a relatively new, highly sensitive method we have developed combined with a theoretical framework guided by the success of the freshwater studies. We show that empirical curve fits of seawater data as a function of saturation state do not agree, largely because the curvature is itself a function of the thermodynamics. Instead, we show that models that consider both surface energetic theory and the complicated speciation of seawater and calcite surfaces in seawater are able to explain most of the most recent data.This new framework can also explain features of the historical data that have not been previously explained. The existence of a kink in the relationship between rate and saturation state, reflecting a change in dissolution mechanism, may be playing an important role in accelerating CaCO 3 dissolution in key sedimentary environments. 

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3. The role of Co valence in charge transport in the entropy‐stabilized oxide (Mg _0.2 Co _0.2 Ni _0.2 Cu _0.2 Zn _0.2 )O

   https://doi.org/10.1111/jace.18820  

   Jacobson, V.; Huang, J.; Titus, C. J.; Smaha, R. W.; Papac, M.; Lee, S. J.; Zakutayev, A.; Brennecka, G. L. (October 2022, Journal of the American Ceramic Society)

   Abstract Many of the studies on the entropy‐stabilized oxide (Mg_0.2Co_0.2Ni_0.2Cu_0.2Zn_0.2)O have been heavily application‐based. Previous works have studied effects of cation stoichiometry on the entropy‐driven reaction to form a single phase, but a fundamental exploration of the effects of anion stoichiometry and/or redox chemistry on electrical properties is lacking. Using near‐edge X‐ray absorption fine structure (NEXAFS) and electrical measurements, we show that oxidizing thin film samples of (Mg_0.2Co_0.2Ni_0.2Cu_0.2Zn_0.2)O affects primarily the valence of Co, leaving the other cations in this high‐entropy system unchanged. This oxidation increases electrical conduction in these thin films, which occurs via small polaron hopping mediated by the Co valence shift from 2+ to a mixed 2+/3+ state. In parallel, we show that bulk samples sintered in an oxygen‐rich atmosphere have a lower activation energy for electrical conduction than those equilibrated in a nitrogen (reducing) atmosphere. Combining feasible defect compensation scenarios with electrical impedance measurements and NEXAFS data, we propose a self‐consistent interpretation of Co redox‐mediated small polaron conduction as the dominant method of charge transfer in this system. 

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4. Electronic Control of the Position of the Pb Atom on the Surface of B ₈ Borozene in the PbB ₈ Cluster

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   Chen, Wei-Jia; Choi, Hyun Wook; Cavanagh, Joseph; Yuan, Dao-Fu; Wang, Lai-Sheng (May 2024, The Journal of Physical Chemistry A)
5. Identification of a Stable B ₂ H ₂ Intermediate in the Decomposition of Zr(BH ₄ ) ₄ on the Pd(111) Surface

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   Ranjan, Ravi; Redington, Morgan; Ologun, Ayoyele; Zurek, Eva; Miller, Daniel P; Trenary, Michael (August 2024, The Journal of Physical Chemistry C)