Red and Green Laser Powder Bed Fusion of Pure Copper in Combination with Chemical Post-Processing for RF Cavity Fabrication

Q3 Physics and Astronomy Instruments Pub Date : 2024-07-26 DOI:10.3390/instruments8030039
Michael Mayerhofer, Stefan Brenner, M. Dickmann, Michael Doppler, S. Gruber, R. Helm, Elena Lopez, Verena Maier, J. Mitteneder, Carsten Neukirchen, V. Nedeljkovic-Groha, Bernd Reinarz, Michael Schuch, L. Stepien, Günther Dollinger
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Abstract

Linear particle accelerators (Linacs) are primarily composed of radio frequency cavities (cavities). Compared to traditional manufacturing, Laser Powder Bed Fusion (L-PBF) holds the potential to fabricate cavities in a single piece, enhancing Linac performance and significantly reducing investment costs. However, the question of whether red or green laser PBF yields superior results for pure copper remains a subject of ongoing debate. Eight 4.2 GHz single-cell cavities (SCs) were manufactured from pure copper using both red and green PBF (SCs R and SCs G). Subsequently, the surface roughness of the SCs was reduced through a chemical post-processing method (Hirtisation) and annealed at 460 ∘C to maximize their quality factor (Q0). The geometric accuracy of the printed SCs was evaluated using optical methods and resonant frequency (fR) measurements. Surface conductivity was determined by measuring the quality factor (Q0) of the SCs. Laser scanning microscopy was utilized for surface roughness characterization. The impact of annealing was quantified using Energy-Dispersive X-ray Spectroscopy and Electron Backscatter Diffraction to evaluate chemical surface properties and grain size. Both the SCs R and SCs G achieved the necessary geometric accuracy and thus fR precision. The SCs R achieved a 95% Q0 after a material removal of 40 µm. The SCs G achieved an approximately 80% Q0 after maximum material removal of 160 µm. Annealing increased the Q0 by an average of about 5%. The additive manufacturing process is at least equivalent to conventional manufacturing for producing cavities in the low-gradient range. The presented cavities justify the first high-gradient tests.
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纯铜的红绿激光粉末床融合与射频腔制造的化学后处理相结合
直线粒子加速器(Linacs)主要由射频腔体(空腔)组成。与传统制造方法相比,激光粉末床熔融技术(L-PBF)具有单件制造空腔的潜力,可提高直线加速器的性能并显著降低投资成本。然而,对于纯铜而言,红激光还是绿激光 PBF 能产生更好的效果,仍然是一个争论不休的问题。我们使用红光和绿光 PBF(SCs R 和 SCs G)在纯铜上制造了 8 个 4.2 GHz 单腔 (SCs)。随后,通过化学后处理方法(Hirtisation)降低了 SC 的表面粗糙度,并在 460 ∘C 下退火,以最大限度地提高其品质因数(Q0)。使用光学方法和谐振频率 (fR) 测量法评估了印刷 SC 的几何精度。通过测量 SC 的品质因数(Q0),确定了表面电导率。激光扫描显微镜用于表征表面粗糙度。利用能量色散 X 射线光谱法和电子背散射衍射法对退火的影响进行量化,以评估化学表面特性和晶粒尺寸。SCs R 和 SCs G 都达到了所需的几何精度,从而实现了 fR 精度。在去除 40 µm 的材料后,SCs R 达到了 95% 的 Q0。SCs G 在最大材料去除 160 微米后达到了约 80% 的 Q0。退火使 Q0 平均提高了约 5%。在生产低梯度范围内的空腔时,增材制造工艺至少与传统制造工艺相当。所展示的空腔证明了首次高梯度测试的正确性。
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来源期刊
Instruments
Instruments Physics and Astronomy-Instrumentation
CiteScore
2.60
自引率
0.00%
发文量
70
审稿时长
11 weeks
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