The recent increase in the use of graphene and its derivatives is due to their exceptional physicochemical, electrical, mechanical, and thermal properties as the industrial materials developed by involving graphene structures can fulfill future needs. In that view, the potential use of these graphene-containing nanomaterials in electronics applications has encouraged in-depth exploration of the electronic, conducting, and other functional properties. The protecting undifferentiated form of graphene has similarly been proposed for various applications, for example, as supercapacitors, photovoltaic and transparent conductors, touch screen points, optical limiters, optical frequency converters, and terahertz devices. The hybrid composite nanomaterials that undergo stimulus-induced optical and electrical changes are important for many new technologies based on switchable devices. As a two-dimensional smart electronic material, graphene has received widespread attention, and with that view, we aim to cover the various types of graphene oxide (GO)-based composites, linking their optical and electrical properties with their structural and morphological ones. We believe that the topics covered in this review can shed light on the development of high-yield GO-containing electronic materials, which can be fabricated as the field moves forward and makes more significant advances in smart optoelectronic devices.

中文翻译：

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用于智能光电应用的功能化石墨烯纳米复合材料

最近石墨烯及其衍生物使用量的增加是由于其优异的物理化学、电学、机械和热性能，因为通过涉及石墨烯结构开发的工业材料可以满足未来的需求。从这个角度来看，这些含石墨烯的纳米材料在电子应用中的潜在用途鼓励了对电子、导电和其他功能特性的深入探索。石墨烯的保护未分化形式同样被提议用于各种应用，例如，作为超级电容器、光伏和透明导体、触摸屏点、光学限幅器、光学频率转换器和太赫兹设备。经历刺激引起的光和电变化的混合复合纳米材料对于许多基于可切换设备的新技术很重要。作为一种二维智能电子材料，石墨烯受到了广泛关注，因此，我们的目标是涵盖各种类型的基于氧化石墨烯 (GO) 的复合材料，将它们的光学和电学特性与其结构和形态联系起来。我们相信，本综述所涵盖的主题可以阐明高产量含 GO 电子材料的发展，随着该领域的发展和在智能光电设备方面取得更大进展，可以制造这些材料。我们的目标是涵盖各种类型的基于氧化石墨烯 (GO) 的复合材料，将它们的光学和电学特性与其结构和形态学特性联系起来。我们相信，本综述所涵盖的主题可以阐明高产量含 GO 电子材料的发展，随着该领域的发展和在智能光电设备方面取得更大进展，可以制造这些材料。我们的目标是涵盖各种类型的基于氧化石墨烯 (GO) 的复合材料，将它们的光学和电学特性与其结构和形态学特性联系起来。我们相信，本综述所涵盖的主题可以阐明高产量含 GO 电子材料的发展，随着该领域的发展和在智能光电设备方面取得更大进展，可以制造这些材料。