Crystalline colloidal array (CCA) photonic crystals (PCs) are periodic structures formed by the self-assembly of monodisperse, highly-charged particles in low ionic strength aqueous solutions. Similar to an atomic crystal but with much larger lattice spacings, the CCA can efficiently diffract light in the UV, visible and near-IR spectral regions. ududThis thesis reports the development of new CCA materials, novel CCA Bragg diffraction devices, and utilization of CCA PC templates for new nanostructure and nanomaterial fabrication. We use CCA for development of a CCA deep UV narrow band filter that acts as a Rayleigh rejection filter for UV Raman spectroscopy and for templates for solid-state UV Raman cross section determinations. ududWe developed novel CCA PC deep UV Bragg diffraction devices. We synthesized small, monodisperse, highly surface-charged silica particles and prepared novel silica CCA through the self-assembly of these particles. The silica CCA efficiently Bragg diffract light in the deep UV. The diffracted wavelength was varied by tilting the CCA orientation to the incident beam. We demonstrated the utility of the silica CCA filter as a Rayleigh rejection filter in Teflon UV Raman measurements.ududWe conducted the first resonance Raman cross-section measurements of solids that avoids self-absorption bias by using PC templates. We fabricated complex stoichiometrically defined nanoparticles (NaNO3/Na2SO4 nanoparticles) by utilizing the defined interstitial volume of close-packed PCs. We successfully determined the solid-state NaNO3 UV resonance Raman cross-sections by using solid Na2SO4 as an internal standard. We also developed a refractive-index matching method to measure solid-state Na2SO4 UV Raman cross sections that avoids the effect of the local field and avoids interface scattering of the incident light. ududWe developed a facile method to fabricate silica shell PCs through the use of flexible poly(N-isopropylacrylamide) (PNIPAm) core templates. We synthesized monodisperse PNIPAm-silica core-shell particles and demonstrated their reversible swelling and shrinking as the temperature is cycled. We fabricated close-packed PCs of PNIPAm-silica core-shell particles and further fabricated hollow silica shell PCs by removing the PNIPAm cores by calcination. ud
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机译:晶体胶体阵列(CCA)光子晶体(PC)是由单分散,高电荷粒子在低离子强度水溶液中自组装而成的周期性结构。与原子晶体相似,但晶格间距大得多,CCA可以有效地衍射紫外,可见光和近红外光谱区域的光。 ud ud本论文报告了新型CCA材料,新型CCA Bragg衍射设备的开发以及CCA PC模板在新型纳米结构和纳米材料制造中的应用。我们使用CCA来开发CCA深紫外窄带滤光片,该滤光片可用作UV拉曼光谱学和固态UV拉曼横截面测定模板的瑞利抑制滤光片。 ud ud我们开发了新颖的CCA PC深紫外布拉格衍射装置。我们合成了小的,单分散的,高表面电荷的二氧化硅颗粒,并通过这些颗粒的自组装制备了新型的二氧化硅CCA。二氧化硅CCA有效地使布拉格光线在深紫外线中衍射。通过将CCA方向倾斜到入射光束来改变衍射波长。我们展示了二氧化硅CCA滤光片在Teflon UV拉曼测量中作为瑞利抑制滤光片的作用。 ud ud我们使用PC模板对固体进行了首次共振拉曼横截面测量,从而避免了自吸收偏差。我们通过利用密排PC的确定的间隙体积来制造复杂的化学计量定义的纳米颗粒(NaNO3 / Na2SO4纳米颗粒)。我们通过使用固态Na2SO4作为内标成功地确定了固态NaNO3紫外共振拉曼截面。我们还开发了一种折射率匹配方法来测量固态Na2SO4 UV拉曼截面,从而避免了局部场的影响并避免了入射光的界面散射。 ud ud我们开发了一种通过使用柔性聚(N-异丙基丙烯酰胺)(PNIPAm)核心模板制造二氧化硅壳PC的简便方法。我们合成了单分散的PNIPAm-二氧化硅核-壳颗粒,并证明了它们在温度循环时可逆溶胀和收缩。我们制造了PNIPAm-二氧化硅核-壳颗粒的密排PC,并通过煅烧除去了PNIPAm核来进一步制造了中空的二氧化硅壳PC。 ud
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