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1. Donor-acceptor pairs in wide-bandgap semiconductors for quantum technology applications

   https://doi.org/10.1038/s41524-023-01190-6  

   Bilgin, Anil; Hammock, Ian N.; Estes, Jeremy; Jin, Yu; Bernien, Hannes; High, Alexander A.; Galli, Giulia (January 2024, npj Computational Materials)

   Abstract We propose a quantum science platform utilizing the dipole-dipole coupling between donor-acceptor pairs (DAPs) in wide bandgap semiconductors to realize optically controllable, long-range interactions between defects in the solid state. We carry out calculations based on density functional theory (DFT) to investigate the electronic structure and interactions of DAPs formed by various substitutional point-defects in diamond and silicon carbide (SiC). We determine the most stable charge states and evaluate zero phonon lines using constrained DFT and compare our results with those of simple donor-acceptor pair (DAP) models. We show that polarization differences between ground and excited states lead to unusually large electric dipole moments for several DAPs in diamond and SiC. We predict photoluminescence spectra for selected substitutional atoms and show that while B-N pairs in diamond are challenging to control due to their large electron-phonon coupling, DAPs in SiC, especially Al-N pairs, are suitable candidates to realize long-range optically controllable interactions. 

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2. Two-Electron Redox Tuning of Cyclopentadienyl Cobalt Complexes Enabled by the Phenylenediamide Ligand

   https://doi.org/10.26434/chemrxiv-2023-l58hm  

   Zou, Minzhu; Emge, Thomas J; Waldie, Kate M (March 2023, ChemRxiv)

   A family of neutral cobalt complexes, [CpR'Co(Ropda)] 1-5, based on the redox-active o-phenylenediamide ligand (Ropda) undergo reversible 2e- oxidation revealed by cyclic voltammetry. This multielectron behavior is observed for all complexes regardless of the substituents on the phenylenediamide ligand, enabling redox tuning over more than 0.5 V. These diamagnetic neutral complexes are best described as delocalized systems with covalent bonding across the cobalt-opda metallocycle, consistent with the closed-shell singlet ground-state predicted by density functional theory (DFT) calculations. Two-electron oxidation using chemical oxidants affords the dicationic species, which are formulated as Co(III)-benzoquinonediimine systems with an additional coordinated acetonitrile ligand. DFT calculations also predict an ECE pathway for the 2e- oxidation, in which the first 1e- step is primarily a ligand-based process with redistribution of electron density to the metal. The associated distortion of the coordination geometry and disruption of the metallocycle bonding enable acetonitrile coordination in the intermediate oxidation state, which is critical for favoring the second electron transfer and accessing the potential inversion. 

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3. Reformulation of thermally assisted-occupation density functional theory in the Kohn–Sham framework

   https://doi.org/10.1063/5.0087012  

   Yeh, Shu-Hao; Yang, Weitao; Hsu, Chao-Ping (May 2022, The Journal of Chemical Physics)

   We reformulate the thermally assisted-occupation density functional theory (TAO-DFT) into the Kohn–Sham single-determinant framework and construct two new post-self-consistent field (post-SCF) static correlation correction schemes, named rTAO and rTAO-1. In contrast to the original TAO-DFT with the density in an ensemble form, in which each orbital density is weighted with a fractional occupation number, the ground-state density is given by a single-determinant wavefunction, a regular Kohn–Sham (KS) density, and total ground state energy is expressed in the normal KS form with a static correlation energy formulated in terms of the KS orbitals. In post-SCF calculations with rTAO functionals, an efficient energy scanning to quantitatively determine θ is also proposed. The rTAOs provide a promising method to simulate systems with strong static correlation as original TAO, but simpler and more efficient. We show that both rTAO and rTAO-1 is capable of reproducing most results from TAO-DFT without the additional functional Eθ used in TAO-DFT. Furthermore, our numerical results support that, without the functional Eθ, both rTAO and rTAO-1 can capture correct static correlation profiles in various systems. 

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4. Coupling all-electron full-potential density functional theory with grid-based continuum embeddings

   https://doi.org/10.1063/5.0288363  

   Filser, Jakob; Bainglass, Edan; Reuter, Karsten; Andreussi, Oliviero (October 2025, The Journal of Chemical Physics)

   Recent advances in continuum embedding models have enabled the incorporation of solvent and electrolyte effects into density functional theory (DFT) simulations of material surfaces, significantly benefiting electrochemistry, catalysis, and other applications. To extend the simulation of diverse systems and properties, the implementation of continuum embedding models into the Environ library adopts a modular programming paradigm, offering a flexible interface for communication with various DFT programs. The speed and scalability of the current implementation rely on a smooth definition of the key physical properties of the atomistic system, in particular, of its electronic density. This has hindered the coupling of Environ with all-electron simulation packages, as the sharp electron density peaks near atomic nuclei are difficult to represent on regular grids. In this work, we introduce a novel smoothing scheme that transforms atom-centered electron densities into a regular grid representation while preserving the accuracy of electrostatic calculations. This approach enables a minimal and generic interface, facilitating seamless interoperability between Environ and all-electron DFT programs. We demonstrate this development through the coupling of Environ with the FHI-aims package and present benchmark simulations that validate the proposed method. 

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5. An energetic absorption outflow in QSO J1402+2330: Analysis of DESI observations

   https://doi.org/10.1051/0004-6361/202453384  

   Dehghanian, M; Arav, N; Sharma, M; Walker, G; Johnston, K; Kaupin, M (March 2025, Astronomy & Astrophysics)

   Context.Quasar outflows play a significant role in the active galactic nucleus (AGN) feedback, impacting the interstellar medium and potentially influencing galaxy evolution. Characterizing these outflows is essential for understanding AGN-driven processes. Aims.We aim to analyze the physical properties of the mini-broad absorption line outflow in quasar J1402+2330 using data from the Dark Energy Spectroscopic Instrument (DESI) survey. We seek to measure the outflow’s location, energetics, and potential impact on AGN feedback processes. Methods.In the spectrum of J1402+2330, we identify multiple ionic absorption lines, including ground and excited states. We measure the ionic column densities and then use photoionization models to determine the total hydrogen column density and ionization parameter of the outflow. We utilized the population ratio of the excited state to the ground state of N IIIand S IVto determine the electron number density. Results.The derived electron number density, combined with the ionization parameter, indicates an outflow distance of approximately 2.2 kpc from the central source. Having a mass outflow rate of more than one thousand solar masses per year and a kinetic energy output exceeding 5% of the Eddington luminosity, this outflow can significantly contribute to AGN feedback. Conclusions.Our findings suggest the absorption outflow in J1402+2330 plays a potentially significant role in AGN feedback processes. This study highlights the value of DESI data in exploring AGN feedback mechanisms. 

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