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1. Hydrogen bond network modes in liquid water

   https://doi.org/10.1103/PhysRevb.108.174203  

   Shelton, David P. (November 2023, Physical Review B)

   Collective modes and dynamics of dense disordered materials such as water are not well understood, but nonlinear optics provides a sensitive probe to study polar modes in these materials. Here we report the hyper- Raman (HRS) light scattering spectrum measured for liquid D2O decomposed into contributions from transverse and longitudinal dipolar modes and octupolar modes, using the polarization dependence of HRS. Transverse HRS is observed for orientation and stretching modes, while longitudinal HRS is observed for translation, libration, and bending modes. The HRS observations indicate molecular correlation at distances >200 nm for all modes of orientation, libration, and vibration. The rocking/wagging, twisting, and translation modes for D2O molecules in the hydrogen bonded network are distinguished. The LO-TO splitting is 28 cm−1 for the libration mode and 16 cm−1 for the translation mode, and the relaxation time for libration modes is about 80 fs. The long-range correlation of the orientation and stretching modes is explained as the result of the dipole-dipole orientation correlation in a dipolar fluid. The long-range correlation of the longitudinal polarized libration and bending modes needs further study. 

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2. Long range correlation of molecular orientation and vibration in liquid CDCl3

   https://doi.org/10.1063/5.0107226  

   Shelton, David_P (October 2022, AIP Advances)

   The polarization dependence of hyper-Rayleigh second harmonic light scattering (SHS) and hyper-Raman light scattering (HRS) measured for liquid CDCl3 show the effect of long-range correlation of molecular orientation and vibration. HRS from the ν1, ν4, and ν5 vibration modes is polarized transverse to the scattering wavevector, whereas HRS from the ν2, ν3, and ν6 vibration modes and SHS from the ν0 orientation mode all show longitudinal polarization. The transverse polarized HRS is accounted for by long range vibration correlation due to dipole–dipole interaction for molecules at 20–400 nm separation. Longitudinal SHS and HRS are due to the combined effect of long range dipole–dipole orientation correlation and the increment in the molecular first hyperpolarizability induced by short range intermolecular interactions. 

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3. Ultraviolet absorption spectra of acrylic acid and its conjugate base, acrylate, in aqueous solution

   https://doi.org/10.1016/j.jphotochem.2023.115371  

   Xue, Lei; Kieber, David J. (April 2024, Journal of Photochemistry and Photobiology A: Chemistry)

   Acrylic acid is an important compound widely used in industry with multiple commercial applications, and it is also a key intermediate in the marine organosulfur cycle. However, the fundamental ultraviolet (UV) absorption spectrum of acrylic acid or its conjugate base, acrylate (pKa = 4.25 at 20 oC) have not been determined in water. In this paper, we determined the absorption spectrum of acrylate in aqueous solution at pH 7.2 and 20 oC between 207 and 400 nm. The molar absorptivity decreased rapidly from 3958 M‒1 cm‒1 at 207 nm to a non-detectable value at wavelengths greater than 330 nm, with weak absorption at wavelengths greater than 290 nm (e.g., ɛ290nm 2.7 M‒1 cm‒1). No discernable absorption bands were observed in the absorption spectrum. Excellent agreement was observed when comparing absorption spectra obtained (1) with two different spectrophotometers and (2) with standards prepared from either newly purchased sodium acrylate or from the base hydrolysis of dimethylsulfoniopropionate. Wavelength-dependent molar absorptivities were constant at pH 7.2 over a range of acrylate concentrations from 25 to 135 μM. The absorption spectrum red shifted when the solution pH increased from 2.8 to 8.2, with an isosbestic point observed at 214 nm indicating two exchangeable species in solution. Our study provides the first detailed UV absorption spectra of acrylic acid and acrylate in aqueous solution, with important implications regarding the detection and study of these compounds in environmental settings and commercial applications. 

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4. A new semiconductor: Ti0.5Mg0.5N(001)

   https://doi.org/10.1109/NANOTECH.2018.8653564  

   Wang, Baiwei; Gall, Daniel (November 2018, 2018 IEEE Nanotechnology Symposium (ANTS), Albany, NY, 2018)

   Ti0.5Mg0.5N has recently been predicted to be a semiconductor with a 1.3 eV band gap and promising properties for thermoelectric and plasmonic devices. As a first step towards experimental validation, epitaxial Ti0.5Mg0.5N(001) layers are deposited on MgO(001) by reactive magnetron co-sputtering from titanium and magnesium targets at 600 °C in pure N2 atmospheres. X-ray diffraction ω-2θ scans, ω-rocking curves, φ-scans, and high resolution reciprocal space maps show that Ti0.5Mg0.5N alloys form a pseudobinary rocksalt structure and are single crystals with a cube-on-cube epitaxial relationship with the substrate: (001)TiMgN║(001)MgO and [100]TiMgN║[100]MgO. A 275-nm-thick Ti0.5Mg0.5N layer is fully relaxed and exhibits a 002 ω-rocking curve width ω = 0.73°, while a 36-nm-thick layer is fully strained and has a ω = 0.49°. These results indicate a thickness-dependent strain state which suggests a critical thickness for misfit dislocation nucleation and glide which is between 36 and 275 nm. A measured negative temperature coefficient of resistivity in combination with a low optical absorption coefficient of 0.25 × 105 cm 1 for λ = 740 nm, and a vanishing density of states at the Fermi level measured by x-ray photoelectron spectroscopy support the prediction that Ti0.5Mg0.5N is a semiconductor. 

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5. The Simons Observatory: Galactic Science Goals and Forecasts

   https://doi.org/10.3847/1538-4357/ac5e36  

   Hensley, Brandon S.; Clark, Susan E.; Fanfani, Valentina; Krachmalnicoff, Nicoletta; Fabbian, Giulio; Poletti, Davide; Puglisi, Giuseppe; Coppi, Gabriele; Nibauer, Jacob; Gerasimov, Roman; et al (April 2022, The Astrophysical Journal)

   Abstract Observing in six frequency bands from 27 to 280 GHz over a large sky area, the Simons Observatory (SO) is poised to address many questions in Galactic astrophysics in addition to its principal cosmological goals. In this work, we provide quantitative forecasts on astrophysical parameters of interest for a range of Galactic science cases. We find that SO can: constrain the frequency spectrum of polarized dust emission at a level of Δβ_d≲ 0.01 and thus test models of dust composition that predict thatβ_din polarization differs from that measured in total intensity; measure the correlation coefficient between polarized dust and synchrotron emission with a factor of two greater precision than current constraints; exclude the nonexistence of exo-Oort clouds at roughly 2.9σif the true fraction is similar to the detection rate of giant planets; map more than 850 molecular clouds with at least 50 independent polarization measurements at 1 pc resolution; detect or place upper limits on the polarization fractions of CO(2–1) emission and anomalous microwave emission at the 0.1% level in select regions; and measure the correlation coefficient between optical starlight polarization and microwave polarized dust emission in 1° patches for all lines of sight withN_H≳ 2 × 10²⁰cm⁻². The goals and forecasts outlined here provide a roadmap for other microwave polarization experiments to expand their scientific scope via Milky Way astrophysics.³⁷³⁷A supplement describing author contributions to this paper can be found athttps://simonsobservatory.org/wp-content/uploads/2022/02/SO_GS_Contributions.pdf. 

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