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1. Decoupling of temperature and thermal radiation

   https://doi.org/10.1364/NOMA.2019.NoW3B.3  

   Shahsafi, Alireza; Roney, Patrick; Zhou, You; Zhang, Zhen; Huang, Chengzi; Xiao, Yuzhe; Wan, Chenghao; Wambold, Raymond; Salman, Jad; Yu, Zhaoning; et al (January 2019, OSA Advanced Photonics Congress (IPR, Networks, NOMA, SPPCom, PVLED))

   We show that the well-known relationship between temperature and thermal radiation can be decoupled in a fully passive and reversible way using the phase transition of samarium nickelate. Our sample features temperature-independent thermally emitted power in the long-wave infrared from 90 to 120 °C, making it promising for camouflage applications. 

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2. Lowering insulator-to-metal transition temperature of vanadium dioxide thin films via co-sputtering, furnace oxidation, and thermal annealing

   https://doi.org/10.1063/5.0269526  

   Rajan, Vishwa Krishna; Chao, Jeremy; Taylor, Sydney; Wang, Liping (May 2025, Journal of Applied Physics)

   Thermochromic vanadium dioxide thin films have attracted much attention recently for constructing variable-emittance coatings upon their insulator-metal phase transition for dynamic thermal control. However, fabrication of high-quality vanadium dioxide thin films in a cost-effective way is still a challenge. In addition, the phase transition temperature of vanadium dioxide is around 68 °C, which is higher than most of terrestrial and extraterrestrial applications. In this study, we report the fabrication and characterization of tungsten-doped vanadium dioxide thin films with lowered phase transition temperatures via co-sputtering, furnace oxidation, and thermal annealing processes for wider application needs. Doping is achieved by co-sputtering of tungsten and vanadium targets while the doping level is varied by carefully controlling the sputtering power for tungsten. Doped thin film samples of 30 nm thick with different tungsten atomic concentrations are prepared by co-sputtering onto undoped silicon wafers. Optimal oxidation time of 4 h is determined to reach full oxidation in an oxygen-rich furnace environment at 300 °C. A systematic thermal annealing study is carried out to find the optimal annealing temperature and time. By using an optical cryostat coupled to an infrared spectrometer, the temperature-dependent infrared transmittance of fully annealed tungsten-doped vanadium dioxide thin films is measured in a wide temperature range from −60 to 100 °C. The phase transition temperature is found to decrease at 24.5 °C per at. % of tungsten doping, and the thermal hysteresis between heating and cooling shrinks at 5.5 °C per at. % from the fabricated vanadium dioxide thin films with tungsten doping up to 4.1 at. %. 

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3. A reaction network approach to the convergence to equilibrium of quantum Boltzmann equations for Bose gases

   https://doi.org/10.1051/cocv/2021079  

   Craciun, Gheorghe; Tran, Minh-Binh (January 2021, ESAIM: Control, Optimisation and Calculus of Variations)

   Buttazzo, G.; Casas, E.; de Teresa, L.; Glowinski, R.; Leugering, G.; Trélat, E.; Zhang, X. (Ed.)

   When the temperature of a trapped Bose gas is below the Bose-Einstein transition temperature and above absolute zero, the gas is composed of two distinct components: the Bose-Einstein condensate and the cloud of thermal excitations. The dynamics of the excitations can be described by quantum Boltzmann models. We establish a connection between quantum Boltzmann models and chemical reaction networks. We prove that the discrete differential equations for these quantum Boltzmann models converge to an equilibrium point. Moreover, this point is unique for all initial conditions that satisfy the same conservation laws. In the proof, we then employ a toric dynamical system approach, similar to the one used to prove the global attractor conjecture, to study the convergence to equilibrium of quantum kinetic equations. 

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4. Metasurfaces with Phase-Change Materials for Mid-Wave Infrared Thermal Management

   https://doi.org/10.3390/mi17010017  

   Babicheva, Viktoriia E; Kim, Heungsoo; Piqué, Alberto (January 2026, Micromachines)

   Applying coatings that suppress the radiance changes related to temperature-dependent blackbody emission enables temperature-independent optical and sensing systems. Phase-change materials can significantly modify their optical properties within their transition window, but compensating for the large mid-wave infrared (MWIR, 3–5 µm) variation is demanding: blackbody radiance at 3 µm increases nearly 10-fold as the temperature rises from 30 °C to 80 °C. Vanadium dioxide VO2, whose insulator–metal transition offers a sharp contrast and a low-loss insulating state, is attractive for applications in thermal management, but simple thin-film designs cannot provide full compensation. We demonstrate metasurface coatings that provide this compensation by constructing an array of metal–VO2–metal antennas tuned to maintain constant thermal emission at a target wavelength over a temperature range of 30 °C to 80 °C. Antennas of several lateral sizes are combined, so their individual resonances collectively track the Planck change. This design provides both optical contrast and the correct temperature derivative, which are unattainable with homogeneous layers. Our approach results in a negligible apparent temperature change of the metasurface across the 30–80 °C range, effectively masking thermal signatures from MWIR detectors stemming from the low losses of VO2. 

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5. Analytical and Numerical Solutions to the Three-Phase Stefan Problem With Simultaneous Occurrences of Melting, Solidification, Boiling, and Condensation Phenomena

   https://doi.org/10.1115/1.4069329  

   Soleimani, Mehran; Koponen, Kimmo; Tilton, Nils; Bhalla, Amneet_Pal Singh (January 2026, ASME Journal of Heat and Mass Transfer)

   Abstract The one-dimensional (1D) Stefan problem is a prototypical heat and mass transfer problem that analyzes the temperature distribution in a material undergoing phase change. In addition, it describes the evolution of the phase change front within the phase change material (PCM). Analytical solutions to the two-phase Stefan problem which describes the melting of a solid or boiling of a liquid have been extensively discussed in the literature. Density change effects and associated fluid flow phenomena during phase change are typically ignored to simplify the analysis. As the PCM boils or condenses, it undergoes a density change of 1000 or more. The effects of density changes and convection cannot be ignored when dealing with such problems. In our recent work (Thirumalaisamy and Bhalla, 2023, “A Low Mach Enthalpy Method to Model Non-Isothermal Gas–Liquid–Solid Flows With Melting and Solidification,” Int. J. Multiphase Flow, 169, p. 104605), we found analytical solutions to the two-phase Stefan problem that account for a jump in the thermophysical properties of the two phases, including density. In this work, we extend our prior analyses to obtain analytical solutions to the three-phase Stefan problem in which an initially solid PCM melts and boils under imposed temperature conditions. This scenario is typical of metal additive manufacturing and welding processes, wherein a high-power laser melts and boils the metal powder or substrate. Each phase of the PCM (solid, liquid, and vapor) has distinct thermophysical properties, including density, thermal conductivity, and heat capacity. While deriving the analytical solution, all relevant jump conditions, including density and kinetic energy, are accounted for. It is shown that the three-phase Stefan problem admits similarity transformations and similarity solutions. Similarity solutions to the three-phase Stefan problem require solving two coupled transcendental equations. To our knowledge, this is the first work that presents an analytical solution to the three-phase Stefan problem with simultaneous melting, solidification, boiling, and condensation (MSNBC). Furthermore, we describe a numerical method for solving the three-phase Stefan problem with second-order accuracy. Numerical solutions for vapor–liquid and liquid–solid interface positions and temperature distributions are compared to analytical solutions. It is demonstrated that the proposed sharp–interface technique can simulate phase change phenomena in moving domains with second-order spatiotemporal accuracy. 

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