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1. Label-free imaging of fibroblast membrane interfaces and protein signatures with vibrational infrared photothermal and phase signals

   https://doi.org/10.1364/BOE.411888  

   Samolis, Panagis_D; Langley, Daniel; O’Reilly, Breanna_M; Oo, Zay; Hilzenrat, Geva; Erramilli, Shyamsunder; Sgro, Allyson_E; McArthur, Sally; Sander, Michelle_Y (December 2020, Biomedical Optics Express)

   Label-free vibrational imaging of biological samples has attracted significant interest due to its integration of structural and chemical information. Vibrational infrared photothermal amplitude and phase signal (VIPPS) imaging provide label-free chemical identification by targeting the characteristic resonances of biological compounds that are present in the mid-infrared fingerprint region (3 µm - 12 µm). High contrast imaging of subcellular features and chemical identification of protein secondary structures in unlabeled and labeled fibroblast cells embedded in a collagen-rich extracellular matrix is demonstrated by combining contrast from absorption signatures (amplitude signals) with sensitive detection of different heat properties (lock-in phase signals). We present that the detectability of nano-sized cell membranes is enhanced to well below the optical diffraction limit since the membranes are found to act as thermal barriers. VIPPS offers a novel combination of chemical imaging and thermal diffusion characterization that paves the way towards label-free imaging of cell models and tissues as well as the study of intracellular heat dynamics. 

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2. Visualizing ultrafast photothermal dynamics with decoupled optical force nanoscopy

   https://doi.org/10.1038/s41467-023-42666-9  

   Wang, Hanwei; Meyer, Sean M.; Murphy, Catherine J.; Chen, Yun-Sheng; Zhao, Yang (November 2023, Nature Communications)

   Abstract The photothermal effect in nanomaterials, resulting from resonant optical absorption, finds wide applications in biomedicine, cancer therapy, and microscopy. Despite its prevalence, the photothermal effect in light-absorbing nanoparticles has typically been assessed using bulk measurements, neglecting near-field effects. Beyond standard imaging and therapeutic uses, nanosecond-transient photothermal effects have been harnessed for bacterial inactivation, neural stimulation, drug delivery, and chemical synthesis. While scanning probe microscopy and electron microscopy offer single-particle imaging of photothermal fields, their slow speed limits observations to milliseconds or seconds, preventing nanoscale dynamic investigations. Here, we introduce decoupled optical force nanoscopy (Dofn), enabling nanometer-scale mapping of photothermal forces by exploiting unique phase responses to temporal modulation. We employ the photothermal effect’s back-action to distinguish various time frames within a modulation period. This allows us to capture the dynamic photothermal process of a single gold nanorod in the nanosecond range, providing insights into non-stationary thermal diffusion at the nanoscale. 

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3. Investigation of Thermal Properties of β-Ga ₂ O ₃ Nanomembranes on Diamond Heterostructure Using Raman Thermometry

   https://doi.org/10.1149/2162-8777/ab981e  

   Zheng, Yixiong; Swinnich, Edward; Seo, Jung-Hun (June 2020, ECS Journal of Solid State Science and Technology)

   Theβ-Ga₂O₃nanomembrane (NM)/diamond heterostructure is one of the promising ultra-wide bandgap heterostructures that offers numerous complementary advantages from both materials. In this work, we have investigated the thermal properties of theβ-Ga₂O₃NM/diamond heterostructure with three different thicknesses ofβ-Ga₂O₃nanomembranes (NMs), namely 100 nm, 1000 nm, and 4000 nm thickβ-Ga₂O₃NMs using Raman thermometry. The thermal property—temperature relationships of theseβ-Ga₂O₃NM/diamond heterostructures, such as thermal conductivity and interfacial thermal boundary conductance were determined under different temperature conditions (from 100 K to 500 K with a 40 K interval). The result provides benchmark knowledge about the thermal conductivity ofβ-Ga₂O₃NMs over a wide temperature range for the design of novelβ-Ga₂O₃-based power electronics and optoelectronics. 

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4. Low-dimensional heat conduction in surface phonon polariton waveguide

   https://doi.org/10.1038/s41467-023-43736-8  

   Pei, Yu; Chen, Li; Jeon, Wonjae; Liu, Zhaowei; Chen, Renkun (December 2023, Nature Communications)

   Abstract Heat conduction in solids is typically governed by the Fourier’s law describing a diffusion process due to the short wavelength and mean free path for phonons and electrons. Surface phonon polaritons couple thermal photons and optical phonons at the surface of polar dielectrics, possessing much longer wavelength and propagation length, representing an excellent candidate to support extraordinary heat transfer. Here, we realize clear observation of thermal conductivity mediated by surface phonon polaritons in SiO₂nanoribbon waveguides of 20-50 nm thick and 1-10 μm wide and also show non-Fourier behavior in over 50-100 μm distance at room and high temperature. This is enabled by rational design of the waveguide to control the mode size of the surface phonon polaritons and its efficient coupling to thermal reservoirs. Our work laid the foundation for manipulating heat conduction beyond the traditional limit via surface phonon polaritons waves in solids. 

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5. Label-free imaging of subcellular features with mid-infrared photothermal microscopy

   https://doi.org/10.1117/12.2568744  

   Sander, Michelle Y.; Samolis, Panagis (January 2020, SPIE Optical Engineering + Applications, Ultrafast Nonlinear Imaging and Spectroscopy VIII)

   Liu, Zhiwen; Psaltis, Demetri; Shi, Kebin (Ed.)

   Mid-infrared photothermal imaging is a novel chemical imaging modality that combines high sensitivity with enhanced spatial resolution. Subcellular features in fibroblast cells and tissues are imaged and analyzed with regards to their molecular structures without the need of exogenous fluorophores at a resolution that overcomes the diffraction limited spot size of the mid-infrared excitation beam. With a phase-sensitive lock-in detection scheme, changes in the thermal diffusion properties can be detected and can provide a complementary sample characterization. 

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