Characterization of Mechanochemical Modification of Porous Silicon with Arginine

Surfaces Pub Date : 2022-02-01 DOI:10.3390/surfaces5010007

Jacklyn A. DiPietro, K. Kolasinski

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Abstract

Mechanochemistry initiated the reaction of hydrogen-terminated porous silicon (H/por-Si) powder with arginine. Samples were analyzed using Fourier-transform infrared spectroscopy (FTIR), dynamic light scattering (DLS), zeta potential, scanning electron microscopy (SEM), and photoluminescence (PL) spectroscopy. Arginine, which was physisorbed onto the surface of por-Si, blue-shifted the peak PL intensity from ~630 nm for the H/por-Si to ~565 nm for arginine-coated por-Si. Grinding for 4 h reduced >80% of the initially 2–45 µm particles to <500 nm, but was observed to quench the PL. With appropriate rinsing and centrifugation, particles in the 100 nm range were isolated. Rinsing ground powder with water was required to remove the unreacted arginine. Without rinsing, excess arginine induced the aggregation of passivated particles. However, water reacted with the freshly ground por-Si powder producing H2. A zeta potential of +42 mV was measured for arginine-terminated por-Si particles dispersed in deionized water. This positive value was consistent with termination such that NH2 groups extended away from the surface. Furthermore, this result was confirmed by FTIR spectra, which suggested that arginine was bound to silicon through the formation of a covalent Si–O bond.

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精氨酸对多孔硅的机械化学改性研究

机械化学引发了端氢多孔硅(H/por-Si)粉末与精氨酸的反应。采用傅里叶变换红外光谱(FTIR)、动态光散射(DLS)、ζ电位(zeta potential)、扫描电子显微镜(SEM)和光致发光(PL)光谱对样品进行分析。精氨酸被物理吸附到孔硅表面后，其峰值PL强度从H/孔硅的~630 nm蓝移到精氨酸包覆孔硅的~565 nm。研磨4小时后，初始2-45µm的颗粒中有>80%的颗粒降至<500 nm，但观察到其淬灭了PL。通过适当的冲洗和离心，分离出了100 nm范围内的颗粒。需要用水冲洗磨碎的粉末以去除未反应的精氨酸。没有冲洗，过量的精氨酸诱导了钝化颗粒的聚集。然而，水与新研磨的多孔硅粉反应产生H2。在去离子水中分散的精氨酸端孔硅颗粒的zeta电位为+42 mV。这个正值与NH2基团从表面向外延伸的终止一致。此外，FTIR光谱证实了这一结果，表明精氨酸通过形成共价Si-O键与硅结合。

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Surfaces

CiteScore

4.40

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0.00%

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