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1. Why is the Energy of the Singly Occupied Orbital in Some Radicals below the Highest Occupied Orbital Energy?

   https://doi.org/10.1021/acs.chemmater.1c00683  

   Abella, Laura ; Crassous, Jeanne ; Favereau, Ludovic ; Autschbach, Jochen ( May 2021 , Chemistry of Materials)

   null (Ed.)
2. Orbital forcing of the Paleocene and Eocene carbon cycle: ORBITAL FORCING PALEOCENE-EOCENE C CYCLE

   https://doi.org/10.1002/2016PA003054  

   Zeebe, Richard E. ; Westerhold, Thomas ; Littler, Kate ; Zachos, James C. ( May 2017 , Paleoceanography)
3. Unraveling the Orbital Physics in a Canonical Orbital System KCuF3

   Li, Jiemin ; Xu, Lei ; Garcia-Fernandez, Mirian ; Nag, Abhishek ; Robarts, H. C. ; Walters, A. C. ; Liu, X. ; Zhou, Jianshi ; Wohlfeld, Krzysztof ; van den Brink, Jeroen ; et al ( March 2021 , Physical review letters)

   null (Ed.)

   We explore the existence of the collective orbital excitations, orbitons, in the canonical orbital system KCuF3 using the Cu L3-edge resonant inelastic x-ray scattering. We show that the nondispersive highenergy peaks result from the Cu2þ dd orbital excitations. These high-energy modes display good agreement with the ab initio quantum chemistry calculation, indicating that the dd excitations are highly localized. At the same time, the low-energy excitations present clear dispersion. They match extremely well with the two-spinon continuum following the comparison with Müller ansatz calculations. The localized dd excitations and the observation of the strongly dispersive magnetic excitations suggest that the orbiton dispersion is below the resolution detection limit. Our results can reconcile with the strong local Jahn-Teller effect in KCuF3, which predominantly drives orbital ordering. 

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4. In silico simulations of tunneling barrier measurements for molecular orbital-mediated junctions: A molecular orbital theory approach to scanning tunneling microscopy

   https://doi.org/10.1116/1.4959826  

   Terryn, III, Raymond J. ; Sriraman, Krishnan ; Olson, Joel A. ; Baum, J. Clayton ; Novak, Mark J. ( September 2016 , Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films)
5. Orbital Decay in an Accreting and Eclipsing 13.7 Minute Orbital Period Binary with a Luminous Donor

   https://doi.org/10.3847/2041-8213/ace7cf  

   Burdge, Kevin B. ; El-Badry, Kareem ; Rappaport, Saul ; Sunny Wong, Tin Long ; Bauer, Evan B. ; Bildsten, Lars ; Caiazzo, Ilaria ; Chakrabarty, Deepto ; Chickles, Emma ; Graham, Matthew J. ; et al ( August 2023 , The Astrophysical Journal Letters)

   We report the discovery of ZTF J0127+5258, a compact mass-transferring binary with an orbital period of 13.7 minutes. The system contains a white dwarf accretor, which likely originated as a post–common envelope carbon–oxygen (CO) white dwarf, and a warm donor (T_eff,donor= 16,400 ± 1000 K). The donor probably formed during a common envelope phase between the CO white dwarf and an evolving giant that left behind a helium star or white dwarf in a close orbit with the CO white dwarf. We measure gravitational wave–driven orbital inspiral with ∼51σsignificance, which yields a joint constraint on the component masses and mass transfer rate. While the accretion disk in the system is dominated by ionized helium emission, the donor exhibits a mixture of hydrogen and helium absorption lines. Phase-resolved spectroscopy yields a donor radial velocity semiamplitude of 771 ± 27 km s⁻¹, and high-speed photometry reveals that the system is eclipsing. We detect a Chandra X-ray counterpart withL_X∼ 3 × 10³¹erg s⁻¹. Depending on the mass transfer rate, the system will likely either evolve into a stably mass-transferring helium cataclysmic variable, merge to become an R CrB star, or explode as a Type Ia supernova in the next million years. We predict that the Laser Space Interferometer Antenna (LISA) will detect the source with a signal-to-noise ratio of 24 ± 6 after 4 yr of observations. The system is the first LISA-loud mass-transferring binary with an intrinsically luminous donor, a class of sources that provide the opportunity to leverage the synergy between optical and infrared time domain surveys, X-ray facilities, and gravitational-wave observatories to probe general relativity, accretion physics, and binary evolution.

    

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