Rational design of peptides for biomimetic palladium nanoparticle catalysis with Suzuki and Heck coupling in ethanol

IF 4.7 3区材料科学 Q2 CHEMISTRY, PHYSICAL

Colloid and Interface Science Communications Pub Date : 2023-05-01 DOI:10.1016/j.colcom.2023.100708

Charles J. Corulli , Emily A. Groover, John D. Attelah, Carley B. Miller, Beverly B. Penland

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引用次数: 1

Abstract

Peptide-mediated nanoparticle synthesis has been shown as an environmentally friendly way to synthesize highly reactive nanocatalysts. Previous studies have shown that peptides are capable of controlling the size and shape of metal nanoparticles made from Pd, Au, Pt, and Ag. These studies revealed that the sequence of the amino acids is critically important to optimize the performance as nanocatalysts. However, these peptide-mediated formations of nanoparticles are limited to aqueous solvents. There is a need for such optimized catalysts in organic solvents. For this, a palladium-binding peptide was modified to contain hydrophobic sequences to improve the stability and reactivity in organic solvents. Palladium nanoparticles were synthesized using the modified peptides in ethanol and used as catalysts in Suzuki and Heck coupling at a catalytic loading of 0.05 mol% at room temperature or 80 °C. The location of the hydrophobic region was found to be pivotal for increased reactivity.

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仿生钯纳米颗粒催化乙醇中Suzuki和Heck偶联肽的合理设计

肽介导的纳米颗粒合成已被证明是合成高活性纳米催化剂的一种环境友好的方法。先前的研究表明，肽能够控制由Pd、Au、Pt和Ag制成的金属纳米颗粒的大小和形状。这些研究表明，氨基酸的序列对于优化纳米催化剂的性能至关重要。然而，这些肽介导的纳米颗粒的形成仅限于水性溶剂。需要在有机溶剂中这样优化的催化剂。为此，将钯结合肽修饰为含有疏水序列，以提高其在有机溶剂中的稳定性和反应性。在乙醇中使用修饰的肽合成钯纳米颗粒，并在室温或80°C下以0.05 mol%的催化负载用作Suzuki和Heck偶联的催化剂。疏水区域的位置被发现是提高反应性的关键。

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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来源期刊

Colloid and Interface Science Communications Materials Science-Materials Chemistry

CiteScore

9.40

自引率

6.70%

发文量

125

审稿时长

43 days

期刊介绍： Colloid and Interface Science Communications provides a forum for the highest visibility and rapid publication of short initial reports on new fundamental concepts, research findings, and topical applications at the forefront of the increasingly interdisciplinary area of colloid and interface science.