Measurement of Mechanical Behavior of 11B-Enriched MgB2 Wire Using a Pulsed Neutron Source

IF 1.3 Q3 INSTRUMENTS & INSTRUMENTATION

Quantum Beam Science Pub Date : 2023-10-31 DOI:10.3390/qubs7040034

Shutaro Machiya, Kozo Osamura, Yoshimitsu Hishinuma, Hiroyasu Taniguchi, Stefanus Harjo, Takuro Kawasaki

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Abstract

MgB2 represents a hexagonal superconductive material renowned for its straightforward composition, which has facilitated the development of cost-effective practical wires. Its capacity to function at temperatures as low as liquid hydrogen (LH2) has made it a prominent candidate as wire material for the coils of next-generation fusion reactors. Much like other superconducting wires, a prevalent issue arises when these wires are employed in coils, wherein electromagnetic forces induce tensile stress and strain within the wire. This, in turn, diminishes the critical current, which is the maximum current capable of flowing within the generated magnetic field and strain. The techniques and methods for accurately measuring the actual strain on the filaments are of paramount importance. While strain measurements have been conducted with synchrotron radiation and neutrons for other practical wires in the past, no such measurements have been undertaken for MgB2. Presumably, this lack of measurement is attributed to its relatively greater thickness, making it less suitable for synchrotron radiation measurements. Additionally, the high absorption cross-section of the included boron-10 poses challenges in obtaining elastic scattering data for neutron measurements. In response, we fabricated a wire enriched with boron-11, an isotope with a smaller neutron absorption cross-section. We then embarked on the endeavor to measure its strain under tensile loading using pulsed neutrons. Consequently, we succeeded in obtaining changes in the lattice constant under tensile loading through Rietveld analysis. This marks the inaugural instance of strain measurement on an MgB2 filament, signifying a significant milestone in superconductivity research.

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用脉冲中子源测量富11b MgB2金属丝的力学行为

MgB2是一种六角形超导材料，以其简单的成分而闻名，这有助于开发具有成本效益的实用电线。它能在低至液态氢(LH2)的温度下工作，这使它成为下一代聚变反应堆线圈导线材料的杰出候选者。就像其他超导导线一样，当这些导线在线圈中使用时，一个普遍的问题出现了，其中电磁力在导线内引起拉伸应力和应变。这反过来又降低了临界电流，即能够在产生的磁场和应变内流动的最大电流。准确测量细丝实际应变的技术和方法是至关重要的。虽然过去已经用同步辐射和中子对其他实际导线进行了应变测量，但还没有对MgB2进行过这样的测量。据推测，这种缺乏测量是由于其相对较大的厚度，使其不太适合同步辐射测量。此外，所含硼-10的高吸收截面对获得中子测量的弹性散射数据提出了挑战。作为回应，我们制造了一种富含硼-11的金属丝，硼-11是一种中子吸收截面较小的同位素。然后我们开始尝试用脉冲中子测量它在拉伸载荷下的应变。因此，我们成功地通过Rietveld分析获得了拉伸载荷下晶格常数的变化。这标志着在MgB2灯丝上进行应变测量的首次实例，标志着超导研究的一个重要里程碑。

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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