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1. Dynamic permittivity of confined water under a static background field

   https://doi.org/10.1063/5.0233894  

   Bratko, D; Mulpuri, N (October 2024, The Journal of Chemical Physics)

   Molecular and collective reorientations in interfacial water are by-and-large decelerated near surfaces subjected to outgoing electric fields (pointing from surface to liquid, i.e., when the surface carries positive charge). In incoming fields at negatively charged surfaces, these rates show a nonmonotonic dependence on field strength where fastest reorientations are observed when the field alignment barely offsets the polarizing effects due to interfacial hydrogen bonding. This extremum coincides with a peak of local static permittivity. We use molecular dynamics simulations to explore the impact of background static field on high frequency AC permittivity in hydration water under an electric field mimicking the conditions inside a capacitor where one of the confinement walls is subject to an outgoing field and the other one to an incoming field. At strong static fields, the absorption peak undergoes a monotonic blue shift upon increasing field strength in both hydration layers. At intermediate fields, however, the hydration region at the wall under an incoming field (the negative capacitor plate) features a red shift coinciding with maximal static-permittivity and reorientation-rate. The shift is mostly determined by the variation of the inverse static dielectric constant as proposed for mono-exponentially decaying polarization correlations. Conversely, hydration water at the opposite (positively charged) surface features a monotonic blue shift consistent with conventional saturation. The sensitivity of absorption peaks on the field suggests that surface charge densities could be deduced from sub-THz dielectric spectroscopy experiments in porous materials when interfaces accommodate a major fraction of water contained in the system. 

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2. Polarity-dependence of the nonlinear dielectric response in interfacial water

   https://doi.org/10.1063/5.0142483  

   Mulpuri, Nagaraju; Bratko, Dusan (March 2023, The Journal of Chemical Physics)

   Molecular dynamics simulations are used to study nonlinear dielectric responses of a confined aqueous film in a planar nanopore under perpendicular electric fields at varied voltages between confining graphene sheets. Dielectric saturation reminiscent of the bulk phase behavior is prevalent at very strong fields, whereas we observe a nonmonotonic permittivity dependence on electric field at intermediate strengths where field-alignment and spontaneous polarization of interfacial water are of comparable magnitudes. The coupling between the two effects results in distinct dielectric responses at opposite confinement walls. The normal component of both the differential dielectric constant and dielectric difference constant tensors averaged over the region closer to the wall under incoming electric field (field pointing from the liquid to the solid phase) initially increases with the strength of the imposed field. The differential permittivity peaks at a field strength previously shown to offset the surface-induced orientation bias of hydration molecules at this wall. Further strengthening of the field results in conventional saturation behavior. At the opposite wall (subject to outgoing field) and in the central region of water slab, the nonlinear dielectric response resembles bulklike saturation. The conditions at the permittivity extremum coincide with the window of accelerated reorientation rates of interfacial water molecules under incoming field uncovered in earlier molecular dynamics analyses. 

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3. Ultrahigh Capacitive Energy Density in Stratified 2D Nanofiller-Based Polymer Dielectric Films

   https://doi.org/10.1021/acsnano.3c06249  

   Singh, Maninderjeet; Das, Priyanka; Samanta, Pabitra Narayan; Bera, Sumit; Thantirige, Rukshan; Shook, Brian; Nejat, Roushanak; Behera, Banarji; Zhang, Qiqi; Dai, Qilin; et al (October 2023, ACS Nano)

   Dielectric capacitors are critical components in electronics and energy storage devices. The polymer-based dielectric capacitors have the advantages of device flexibility, fast charge–discharge rates, low loss, and graceful failure. Elevating the use of polymeric dielectric capacitors for advanced energy applications such as electric vehicles (EVs), however, requires significant enhancement of their energy densities. Here, we report a polymer thin film heterostructure-based capacitor of poly(vinylidene fluoride)/poly(methyl methacrylate) with stratified 2D nanofillers (Mica or h-BN nanosheets) (PVDF/PMMA-2D fillers/PVDF), that shows enhanced permittivity, high dielectric strength, and an ultrahigh energy density of ≈75 J/cm3 with efficiency over 79%. Density functional theory calculations verify the observed permittivity enhancement. This approach of using oriented 2D nanofillers-based polymer heterostructure composites is expected to be versatile for designing high energy density thin film polymeric dielectric capacitors for myriads of applications. 

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4. Anisotropic quasi-static permittivity of rare-earth scandate single crystals measured by terahertz spectroscopy

   https://doi.org/10.1063/5.0207198  

   Taherian, Afrouz; Cooke, Jacqueline; Schubert, Mathias; Sensale-Rodriguez, Berardi (May 2024, Journal of Applied Physics)

   We report the real-valued static and complex-valued quasi-static anisotropic permittivity parameters of rare-earth scandate orthorhombic single crystal GdScO3 (GSO), TbScO3 (TSO), and DyScO3 (DSO). Employing continuous-wave terahertz spectroscopy (0.2–1 THz), the complex permittivity was extracted using an anisotropic ambient-film-ambient model. Data obtained from multiple samples of the same oxides and different surface cuts were analyzed simultaneously. The zero-frequency limit of the modeled data indicates that at room temperature the real part of the dielectric tensor components for GSO are ɛa = 22.7, ɛb = 19.3, and ɛc = 28.1; for DSO, ɛa = 20.3, ɛb = 17.4, and ɛc = 31.1; and for TSO, ɛa = 21.6, ɛb = 18.1, and ɛc = 30.3, with a, b, and c crystallographic axes constituting the principal directions for the permittivity tensor. These results are in excellent agreement with expectations from theoretical computations and with scarcely available data from previous experimental studies. Furthermore, our results evidence a noticeable attenuation, which increases with frequency, and are very significant especially at the higher frequency end of the measurement and along the c-direction in all samples. We suggest the attenuation is most likely caused by the onset of absorption due to long-wavelength active optical phonon modes. These results are important for electronic and potential sub-terahertz applications (e.g., quarter-wave plate) benefiting from the large index contrast along different directions in these materials. 

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5. Second harmonic generation observed by dielectric relaxation at high electric fields: SHG without optics

   https://doi.org/10.1063/5.0309351  

   Thoms, Erik; Richert, Ranko (December 2025, The Journal of Chemical Physics)

   We have measured second harmonic generation via the nonlinear dielectric permittivity of a polar glass-forming liquid, propylene glycol, with the inversion symmetry of the liquid broken by applying a dc bias field. For a given combined peak field, EB + E0, the highest second harmonic signals are obtained when the dc bias field and peak ac-field have the same amplitude, i.e., EB = E0. Second harmonic results measured in the static limit agree well with the theoretical prediction based upon the third-order nonlinear susceptibility term that connects polarization P with the static field E. Second harmonic signals are detectable at all frequencies at which dipole orientation contributes to permittivity, possibly occurring the instant a dc bias field is applied. The results imply that second harmonic generation as a signature of anisotropy, e.g., at interfaces, can be assessed by impedance spectroscopy at twice the fundamental frequency, not only by optical techniques. 

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