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   https://doi.org/10.1103/PhysRevA.111.052817  

   Wilde, R_S; Gribakin, G_F; Fabrikant, I_I (May 2025, Physical Review A)
2. Low-energy dissociative recombination of OH+

   https://doi.org/10.1063/5.0261887  

   Forer, J; Hvizdoš, D; Greene, C H; Kokoouline, V (May 2025, The Journal of Chemical Physics)

   Dissociative recombination of the OH+ ion with free electrons is modeled theoretically using a recently developed approach that is based on first-principles calculations and multichannel quantum defect theory. The coupling between the incident electron and the rovibrational motion of the ion is accounted for. The cross section of the process at collision energies 10−6–1 eV and the thermally averaged rate coefficient at 10–1000 K are evaluated. The obtained anisotropic rate coefficients agree well with the data from a recent experiment carried out at the Cryogenic Storage Ring, especially when compared to previous theoretical values, which are smaller than the experimental results by about a factor of about 30. 

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3. Semiclassical theory of laser-assisted dissociative recombination

   https://doi.org/10.1103/PhysRevA.103.053115  

   Fabrikant, I. I.; Ambalampitiya, H. B.; Schneider, I. F. (May 2021, Physical Review A)

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4. Dissociative Carbamate Exchange Anneals 3D Printed Acrylates

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   Hamachi, Leslie S.; Rau, Daniel A.; Arrington, Clay B.; Sheppard, Daylan T.; Fortman, David J.; Long, Timothy E.; Williams, Christopher B.; Dichtel, William R. (August 2021, ACS Applied Materials & Interfaces)

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5. Thermophilic Behavior of Heat-Dissociative Coacervate Droplets

   https://doi.org/10.1021/acs.nanolett.4c03058  

   Kim, Youngsun; Zheng, Yuebing (November 2024, Nano Letters)

   In exploring the genesis of life, liquid–liquid phase-separated coacervate droplets have been proposed as primitive protocells. Within the hydrothermal hypothesis, these droplets would emerge from molecule-rich hot fluids and thus be subjected to temperature gradients. Investigating their thermophoretic behavior can provide insights into protocell footprints in thermal landscapes, advancing our understanding of life’s origins. Here, we report the thermophilic behavior of heat-dissociative droplets, contrary to the intuition that heat-associative condensates would prefer hotter areas. This aspect implies the preferential presence of heat-dissociative primordial condensates near hydrothermal environments, facilitating molecular incorporation and biochemical syntheses. Additionally, our investigations reveal similarities between thermophoretic and electrophoretic motions, dictated by molecular redistribution within droplets due to their fluid nature, which necessitates revising current electrophoresis frameworks for surface charge characterization. Our study elucidates how coacervate droplets navigate thermal and electric fields, reveals their thermal-landscape-dependent molecular characteristics, and bridges foundational theories of early life: the hydrothermal and condensate-as-protocell hypotheses. 

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