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for the chemical characterization of surfaces and interfaces found in heterogeneous thin film and nanoparticle systems. Of particular interest are species distributions on patterned surfaces, nucleation and film
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orientations in most engineering materials have some preferential distribution due to processing conditions and deformation history, referred to as crystallographic texture. This texture affects the initial
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) absorption and coherent Raman microscopy. We have demonstrated that both IR- and Raman-based microscopy can map the distribution of biomolecules and unravel the cellular response to external stimuli
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on the presence and distribution of such strains. Many other high-impact studies are possible using techniques (both in situ and ex situ ) such as TEM, AFM, SEM, and X-ray diffraction on single crystals
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landscapes for promoter activity based on steady state population distributions and measures of fluctuations in individual cells. We have previously applied Langevin/Fokker Planck equations to predict rates
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colonies with heterogeneous shapes, sizes, and levels of gene expression. This project focuses on systematically controlling inputs such as shape, size, and spatial distribution of colonies using cell