Development of Manganese Nitride Resistor with Near-Zero Temperature-Coefficient of Resistance to Achieve High-Thermal-Stability ICs

H. Kino, T. Fukushima, Tetsu Tanaka
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引用次数: 1

Abstract

The resistance of the metal wirings in the integrated circuits increases due to the decrease of the mean free path of electrons with the temperature increase. This thermal instability requires redundancy circuits. On the other hand, several materials have the saturation characteristics of the mean free path around room temperature. The anti-perovskite manganese nitride compound material is one of them. The anti-perovskite manganese nitride compounds show a flat resistance-temperature curve around room temperature. However, the flat resistance-temperature curves have been obtained with only the sintered bulk materials. It has not become clear the characteristics of the manganese nitride compounds in the micro/nanoscale. In this study, we proposed manganese nitride wiring for high-thermal-stability systems. Then, we fabricated and evaluated the micro/nanoscale manganese nitride compound wiring with the complementary metal-oxide-semiconductor compatible process.
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实现高热稳定性集成电路的近零电阻系数氮化锰电阻器的研制
随着温度的升高,电子的平均自由程减小,使得集成电路中金属导线的电阻增大。这种热不稳定性需要冗余电路。另一方面,一些材料具有室温左右平均自由程的饱和特性。抗钙钛矿型氮化锰复合材料就是其中之一。抗钙钛矿型氮化锰化合物在室温附近呈现平坦的电阻-温度曲线。然而,只有烧结的块状材料才能得到平坦的电阻-温度曲线。氮化锰化合物在微/纳米尺度上的特性尚不清楚。在这项研究中,我们提出了用于高热稳定性系统的氮化锰布线。然后,我们利用互补金属-氧化物-半导体兼容工艺制备并评价了微纳米尺度的氮化锰复合布线。
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