氧化石墨烯-M13噬菌体纳米复合材料的热变形力学--面向石墨烯基纳米器件

IF 3.1 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Kate Stokes , Yiwei Sun , Haowei Zhang , Paolo Passaretti , Henry White , Pola Goldberg Oppeneheimer
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引用次数: 0

摘要

氧化石墨烯(GO)和 M13 噬菌体的自组装形成了微孔结构,即 GraPhage13 气凝胶(GPA)。由于气凝胶的纳米力学性能,以及之前观察到的石墨烯基纳米复合材料随温度变化的特性,气凝胶在工业中的应用非常有限,因此对 GPA 的热敏纳米力学性能进行深入探讨至关重要。在此,我们对 GPA 在一定温度范围内的形态、组成和光谱分析进行了综合表征,并将其与纳米力学性能联系起来。研究发现,温度升高会导致 GPA 中的含氧官能团(OCFGs)逐渐去除,从而导致结构缺陷增加和刚度降低。值得注意的是,还进一步发现了 GPA 独特的纳米力学行为,其中 sp3 键的热膨胀超过了晶体 sp3 结构,而 GPA 中 sp2 键的热收缩介于石墨和 GO 之间。这强调了 GO 功能化对 GPA 热膨胀行为的影响。所获得的见解增强了对温度退火对 GPA 影响的整体理解,突出了其纳米力学性能的可调性,展示了这种新型纳米复合材料在各种应用领域的广泛潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Thermonanomechanics of graphene oxide-M13 bacteriophage nanocomposites -towards graphene-based nanodevices

Thermonanomechanics of graphene oxide-M13 bacteriophage nanocomposites -towards graphene-based nanodevices

The self-assembly of graphene oxide (GO) and M13 bacteriophage results in the formation of micro-porous structures, known as GraPhage13 aerogels (GPA). Given the limited applications of aerogels in industry due to their nanomechanical properties, along with the previously observed temperature-dependent characteristics in graphene-based nanocomposites, a thorough exploration of the thermosensitive nanomechanical properties of GPA is essential. Herein, a comprehensive characterisation of the morphology, composition, and spectroscopic analysis of the GPA for a range of temperatures has been conducted and correlated with its nanomechanical properties. Elevated temperatures have been found to lead to gradual removal of oxygen-containing functional groups (OCFGs) from GPA, resulting in increased structural defects and reduced stiffness. Notably, unique nanomechanical behaviours of GPA have been further identified, where the thermal expansion of sp3 bonds exceeds that of a crystalline sp3 structure, while the thermal contraction of sp2 bonds in GPA is found to be between graphite and GO. This underscores the impact of GO functionalisation on the thermal expansion behaviour of GPA. The obtained insights enhance the overall comprehension of the temperature annealing impact on GPA and highlight the tunability of its nanomechanical properties, showcasing a broad potential of this novel nanocomposite across a diverse range of applications.

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来源期刊
Carbon Trends
Carbon Trends Materials Science-Materials Science (miscellaneous)
CiteScore
4.60
自引率
0.00%
发文量
88
审稿时长
77 days
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