Bio-derived graphitic carbon microspheres: A green approach for high-frequency microwave absorption

IF 4.3 3区材料科学 Q2 MATERIALS SCIENCE, COATINGS & FILMS

Diamond and Related Materials Pub Date : 2024-11-30 DOI:10.1016/j.diamond.2024.111836

Rohit B. Sutar , Gopal K. Kulkarni , Rohit R. Koli , Suprimkumar D. Dhas , Ninad B. Velhal , Keshav Y. Rajpure , Vijaya R. Puri , Jyotiprakash B. Yadav

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Abstract

Bio-derived carbon materials have emerged as a sustainable alternative to non-renewable petroleum-based carbon sources, thanks to their reproducibility and environmental benefits. There is a strong demand for developing and efficiently utilizing carbon-based microwave absorbing materials (MAMs) that are lightweight, require low filler loading, and offer broadband absorption for electromagnetic wave (EM) applications. In this context, we successfully synthesized uniform carbon microspheres from the natural precursor turpentine oil using the chemical vapor deposition (CVD) technique at various temperatures. The sample prepared at 1000 °C (GC-1000) exhibited a uniform carbon microsphere morphology, as confirmed by XRD and Raman spectroscopy, and demonstrated extremely good microwave absorption properties. With a low filler loading of just 5 wt%, the GC-1000 sample achieved a minimum reflection loss (RL) of −39.77 dB at 10.21 GHz and an effective absorption bandwidth of 2.51 GHz at a matching thickness of only 2.8 mm. Additionally, this sample showed a total shielding effectiveness (SE_T) of −44.74 dB, surpassing the threshold required for commercial applications. The graphitic phase formation, confirmed by XRD and Raman analysis, acts as a conductive trap for electromagnetic radiation, and the high surface area of the uniform carbon microspheres facilitates multiple internal reflections, enhancing overall microwave absorption performance in the X-band region. Our lightweight, durable, bioderived carbon microspheres, synthesized through a cost-effective and scalable process, show significant potential for EM wave absorption in military and electromagnetic compatibility (EMC) devices.

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生物衍生石墨碳微球：高频微波吸收的绿色途径

生物衍生碳材料由于其可重复性和环境效益，已成为不可再生的石油基碳源的可持续替代品。开发和有效利用碳基微波吸收材料（MAMs）的需求非常强烈，这些材料重量轻，需要低填充物负荷，并为电磁波（EM）应用提供宽带吸收。在此背景下，我们利用化学气相沉积（CVD）技术在不同温度下成功地以天然前体松节油为原料合成了均匀的碳微球。在1000℃（GC-1000）下制备的样品具有均匀的碳微球形貌，通过XRD和拉曼光谱证实，并具有极好的微波吸收性能。在填充量仅为5 wt%的情况下，GC-1000样品在10.21 GHz时的最小反射损耗（RL）为- 39.77 dB，在匹配厚度仅为2.8 mm时的有效吸收带宽为2.51 GHz。此外，该样品的总屏蔽效能（SET）为−44.74 dB，超过了商业应用所需的阈值。XRD和拉曼分析证实，石墨相的形成是电磁辐射的导电陷阱，均匀碳微球的高表面积有利于多次内部反射，增强了x波段区域的整体微波吸收性能。我们的轻质，耐用，生物衍生碳微球，通过经济高效和可扩展的工艺合成，在军事和电磁兼容性（EMC）设备中显示出巨大的电磁波吸收潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Diamond and Related Materials 工程技术-材料科学：综合

CiteScore

6.00

自引率

14.60%

发文量

702

审稿时长

2.1 months

期刊介绍： DRM is a leading international journal that publishes new fundamental and applied research on all forms of diamond, the integration of diamond with other advanced materials and development of technologies exploiting diamond. The synthesis, characterization and processing of single crystal diamond, polycrystalline films, nanodiamond powders and heterostructures with other advanced materials are encouraged topics for technical and review articles. In addition to diamond, the journal publishes manuscripts on the synthesis, characterization and application of other related materials including diamond-like carbons, carbon nanotubes, graphene, and boron and carbon nitrides. Articles are sought on the chemical functionalization of diamond and related materials as well as their use in electrochemistry, energy storage and conversion, chemical and biological sensing, imaging, thermal management, photonic and quantum applications, electron emission and electronic devices. The International Conference on Diamond and Carbon Materials has evolved into the largest and most well attended forum in the field of diamond, providing a forum to showcase the latest results in the science and technology of diamond and other carbon materials such as carbon nanotubes, graphene, and diamond-like carbon. Run annually in association with Diamond and Related Materials the conference provides junior and established researchers the opportunity to exchange the latest results ranging from fundamental physical and chemical concepts to applied research focusing on the next generation carbon-based devices.