Nd-Fe-B permanent magnets from two different manufacturers were irradiated in the Omega West reactor at Los Alamos National Laboratory, with fast neutrons at temperatures of 426 K (153 degrees C) and 350 K (77 degrees C) to fluences of 5.0*10/sup 16/ N/cm/sup 2/ and 6.1*10/sup 16/ N/cm/sup 2/, respectively. At intervals during the irradiation the samples were removed from the reactor and the remanence measured at room temperature. The initial loss of remanence for irradiation at 426 K was 10% for a fluence of 10/sup 15/ N/cm/sup 2/. At 350 K the initial loss rate was roughly half this value. The loss rates were nearly the same for samples from the two different manufacturers. These losses are due to the irradiation since the remanence does not decay with annealing at 426 K. Remagnetization after irradiation results in full recovery of the remanence and roughly a 20% increase in the coercivity. Evidence from this experiment suggests that the primary mechanism for loss of remanence is nucleation of reverse domains by the collision cascade and subsequent growth into the original domain.
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机译:来自两个不同制造商的Nd-Fe-B永磁体在Los Alamos国家实验室的Omega West反应堆中辐照,在426 K(153摄氏度)和350 K(77摄氏度)的温度下,中子的快速中子通量为5.0 * 10 / sup 16 / N / cm / sup 2 /和6.1 * 10 / sup 16 / N / cm / sup 2 /。在辐照期间的间隔内,将样品从反应器中取出,并在室温下测量剩磁。能量密度为10 / sup 15 / N / cm / sup 2 /时,在426 K辐照的剩磁率的初始损失为10%。在350 K时,初始损耗率大约是该值的一半。来自两个不同制造商的样品的损失率几乎相同。这些损失是由于辐照造成的,因为剩磁不会随在426 K退火而衰减。辐照后再磁化会完全恢复剩磁,矫顽力大约增加20%。该实验的证据表明,剩磁丢失的主要机制是通过碰撞级联反应使反向域成核并随后生长成原始域。
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