Unprecedented developed composite polishing system to achieve atomic surface integrating rough and fine polishing using a novel hyper-conjugated pad through controlling the temperature of a proposed green slurry

IF 23.2 2区材料科学 Q1 MATERIALS SCIENCE, COMPOSITES

Advanced Composites and Hybrid Materials Pub Date : 2025-04-23 DOI:10.1007/s42114-025-01306-0

Feng Zhao, Zhenyu Zhang, Hongxiu Zhou, Leilei Chen, Kuo Hai, Liwei Wu, Jiahao Yu, Zefang Zhang, Cheng Fan

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引用次数: 0

Abstract

Efficiency and quality are a pair of everlasting contradictions in manufacturing industry. To achieve atomic surface, it usually consists of rough, precision, and ultra-precision polishing. These processes contain generally several to tens of polishing pads, slurries, and setups, which is time-consuming and expensive. These diverse pads, slurries, and setups are strictly separated, avoiding contamination, damage, and corrosion. To solve these challenges, a novel composite polishing system was developed, using a developed hyper-conjugated polishing pad and custom-made green slurry, through adjusting the temperature of slurry to control the material removal rate (MRR). The MRR was controlled between 40.99 and 133.91 nm/min, by adjusting the temperature between 40 and 80 ℃ via splitting of fibers. After pre-polishing by rare earth cerium oxide abrasive and atomic level polishing by proposed composite system, atomic surface is garnered on fused silica with surface roughness Sa of 0.117 nm at a scanning area of 50 × 50 μm². It is unprecedented that the developed polishing system realized atomic surface integrating rough and fine polishing on a setup by a composite fiber polishing pad and a new green chemical mechanical polishing (CMP) slurry. The CMP slurry included silica, hydrogen peroxide, sodium hydroxy cellulose, and sodium carbonate. Transmission electron spectroscopy confirms that the thickness of damaged layer is 1.89 nm. Prior to and after splitting of fibers, diameter, bending length, and Shore hardness decreased from 18.33 to 2.48 μm, 13.7 to 4.6 cm, and 52.7 to 20.5 HC, respectively, reducing 86.5%, 66.4%, and 61.1% correspondingly. However, wicking height and specific surface area increased from 7.5 to 14.1 cm, and 0.028 to 1.926 m²/g, separately, enhancing 88% and 6779%, accordingly. An interactive model was built among a single fiber, abrasive, and workpiece. After splitting of fibers, the maximum stress exerted on axial and radial directions of fiber are 2.45 and 1.36 MPa, respectively, reducing 59% and 73% compared with those of prior to splitting correspondingly. A model of repeated unit cell was constructed between polishing pad and slurry. It is calculated that the stress of 51.15% units is in the range between 0.1 and 0.5 MPa, while that of 92.83% fibers varies from 0.05 to 1 MPa after splitting. A macroscale model of polishing pad was established. Peak stress of an unsplit pad is high up to 13.19 MPa, while that of split one decreases to 2.42 MPa, reducing 81.65%. At an actual polishing pressure of 30 kPa, contact area of a split polishing pad between fibers and workpiece reaches 15.38%, promoting 44.09% compared with that of an unsplit one. Our developed composite polishing system paves a new way to fabricate atomic surface using a hyper-conjugated polishing pad and a green slurry on a setup, saving several and tens of various pads, slurries, and setups, which are both time and cost-effective and has broad prospects in manufacturing industry.

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采用一种新型的超共轭衬垫，通过控制绿色浆料的温度，实现了原子表面粗、精抛光的一体化

效率和质量是制造业永恒的一对矛盾。要达到原子表面，通常包括粗抛光、精密抛光和超精密抛光。这些过程通常包含几个到几十个抛光垫，浆液和设置，这是耗时和昂贵的。这些不同的垫料、浆料和装置是严格分开的，避免污染、损坏和腐蚀。为了解决这些问题，研究人员开发了一种新型的复合抛光系统，使用开发的超共轭抛光垫和定制的绿色浆液，通过调节浆液的温度来控制材料去除率（MRR）。通过纤维分裂调节温度在40 ~ 80℃之间，MRR控制在40.99 ~ 133.91 nm/min之间。经稀土氧化铈磨料预抛光和复合体系原子级抛光后，在50 × 50 μm2的扫描区域内，熔凝二氧化硅表面获得了表面粗糙度Sa为0.117 nm的原子表面。该抛光系统采用复合纤维抛光垫和新型绿色化学机械抛光浆，在一个装置上实现了原子表面粗、精抛光一体化，这是前所未有的。CMP浆料包括二氧化硅、过氧化氢、羟基纤维素钠和碳酸钠。透射电子能谱证实，损伤层厚度为1.89 nm。劈裂前后，纤维直径、弯曲长度和邵氏硬度分别从18.33 μm降至2.48 μm、13.7 cm降至4.6 cm、52.7 HC降至20.5 HC，分别降低86.5%、66.4%和61.1%。吸干高度和比表面积分别从7.5 cm和0.028 m2/g增加到14.1 cm和1.926 m2/g，分别提高了88%和6779%。建立了单纤维、磨料和工件之间的交互模型。纤维劈裂后，纤维轴向和径向的最大应力分别为2.45 MPa和1.36 MPa，比劈裂前分别降低59%和73%。建立了抛光垫与抛光浆之间的重复单元胞模型。经计算，51.15%的单位纤维劈裂后的应力在0.1 ~ 0.5 MPa之间，92.83%的单位纤维劈裂后的应力在0.05 ~ 1 MPa之间。建立了抛光垫的宏观模型。未劈裂焊盘峰值应力较高，达13.19 MPa，劈裂焊盘峰值应力降至2.42 MPa，降低81.65%。在实际抛光压力为30 kPa时，劈裂抛光垫的纤维与工件接触面积达到15.38%，比未劈裂抛光垫的接触面积提高了44.09%。我们开发的复合抛光系统开辟了一种利用超共轭抛光垫和绿色浆液在一个装置上加工原子表面的新途径，节省了几十种不同的衬垫、浆液和装置，既省时又经济，在制造业中具有广阔的前景。

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来源期刊

Advanced Composites and Hybrid Materials Multiple-

CiteScore

26.00

自引率

21.40%

发文量

185

期刊介绍： Advanced Composites and Hybrid Materials is a leading international journal that promotes interdisciplinary collaboration among materials scientists, engineers, chemists, biologists, and physicists working on composites, including nanocomposites. Our aim is to facilitate rapid scientific communication in this field. The journal publishes high-quality research on various aspects of composite materials, including materials design, surface and interface science/engineering, manufacturing, structure control, property design, device fabrication, and other applications. We also welcome simulation and modeling studies that are relevant to composites. Additionally, papers focusing on the relationship between fillers and the matrix are of particular interest. Our scope includes polymer, metal, and ceramic matrices, with a special emphasis on reviews and meta-analyses related to materials selection. We cover a wide range of topics, including transport properties, strategies for controlling interfaces and composition distribution, bottom-up assembly of nanocomposites, highly porous and high-density composites, electronic structure design, materials synergisms, and thermoelectric materials. Advanced Composites and Hybrid Materials follows a rigorous single-blind peer-review process to ensure the quality and integrity of the published work.