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The detection of mid-infrared (MIR) light is technologically important for applications such as night vision, imaging, sensing, and thermal metrology. Traditional MIR photodetectors either require cryogenic cooling or have sophisticated device structures involving complex nanofabrication. Here, we conceive spectrally tunable MIR detection by using two-dimensional metal halide perovskites (2D-MHPs) as the critical building block. Leveraging the ultralow cross-plane thermal conductivity and strong temperature-dependent excitonic resonances of 2D-MHPs, we demonstrate ambient-temperature, all-optical detection of MIR light with sensitivity down to 1 nanowatt per square micrometer, using plastic substrates. Through the adoption of membrane-based structures and a photonic enhancement strategy unique to our all-optical detection modality, we further improved the sensitivity to sub–10 picowatt-per-square-micrometer levels. The detection covers the mid-wave infrared regime from 2 to 4.5 micrometers and extends to the long-wave infrared wavelength at 10.6 micrometers, with wavelength-independent sensitivity response. Our work opens a pathway to alternative types of solution-processable, long-wavelength thermal detectors for molecular sensing, environmental monitoring, and thermal imaging. 

Abstract As a unique nonlinear optical material, Ba₃(ZnB₅O₁₀)PO₄(BZBP) boasts a range of distinctive properties, including low anisotropic thermal expansivity, high specific heat, minimal walk‐off effect, large acceptance angle, non‐hygroscopicity, and high conversion efficiency. These features position BZBP as a highly promising candidate for crucial components in ultraviolet (UV) laser systems. Notably, all previous studies have been conducted under ambient pressures. In this research, synchrotron X‐ray diffraction and Raman spectroscopy are employed to investigate BZBP's behavior under extreme conditions. The findings revealed that BZBP remains exceptionally stable up to 43 Gigapascals (GPa), significantly extending its application range from ambient to high‐pressure environments. This stability enhancement opens new avenues for utilizing BZBP in optical systems designed to function under extreme conditions. Additionally, the study determined BZBP's bulk modulus (110 GPa) and linear compressibility along each lattice axis. Theoretical computations are used to assign the Raman modes, characterize their corresponding lattice vibrations, validate the experimental results, and elucidate the mechanisms underlying the material's remarkable stability.