Formation of a Biopolymer Nano Layer by Electrolysis

American Journal of Modern Physics Pub Date : 2021-10-30 DOI:10.11648/J.AJMP.20211005.13

J. Khakkulov, A. Kholmuminov, Temirov Zokirjon

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Abstract

Composite nanocoatings on the surface of a titanium electrode are obtained by electrochemical reduction of macroions and fibroin nanoparticles in the presence of tricalcium phosphate. Based on the measurements, the dependence of the reduced viscosity (hуд/C) on C was constructed according to the Huggins formula hуд/C = [h] + k[h]2C (where k is a constant). For FB1 and [h] = 75 ml/g the intrinsic viscosity value [h] = 118 ml/g was found by means of С ® 0 extrazolation. The molecular masses М = 295000 for FB1 and M = 175000 for FB2 was calculated, respectively, as stated by Mark-Kuhn-Houwink equation М » ([h]/1,23*10-3)1/0,91. The studies were carried out on a specially assembled electrolysis unit using as a solvent HCOOH: Н2О (50: 50) under the influence of a direct current of 2-8 mA in a temperature range of 25-50°C. within 0.5 - 10 hours. The thickness of the nanocoatings in the range of 50 - 350 nm was controlled by changing the electrolysis time in the range of 0.5 - 10 hours. Furthermore, we have shown that the obtained samples of composite nanocoating FB are characterized by stability in the process of sterilization in ethanol at 60°C, as well as in salt-containing.

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电解法制备生物聚合物纳米层

在磷酸三钙的存在下，通过电化学还原巨离子和丝素纳米粒子，在钛电极表面获得复合纳米涂层。根据测量结果，根据哈金斯公式hуд/C = [h] + k[h]2C(其中k为常数)，构建了还原粘度(hуд/C)对C的依赖关系。对于FB1和[h] = 75 ml/g，通过С®0外显法得到特性粘度值[h] = 118 ml/g。根据Mark-Kuhn-Houwink方程М»([h]/1,23*10-3)1/0,91，计算出FB1的分子质量М = 295000, FB2的分子质量M = 175000。研究是在一个特殊组装的电解装置上进行的，溶剂为HCOOH: Н2О(50:50)，温度范围为25-50°C，直流电为2-8 mA。0.5 - 10小时内。通过改变电解时间0.5 ~ 10 h，可以控制纳米涂层的厚度在50 ~ 350 nm范围内。此外，我们已经证明，所获得的复合纳米涂层FB样品在60°C乙醇灭菌过程中具有稳定性，并且在含盐条件下也具有稳定性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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American Journal of Modern Physics

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