Probing the validity of classical macroscopic physical laws at the nanoscale is important for nanoscience research. Herein, we report on experimental evidence that electron emission from individual hot carbon nanotubes (CNTs) heated by self-Joule-heating does not obey Richardson's law of thermionic emission. By using an in-situ multi-probe measurement technique, electron emission density (J) and temperature (T) of individual self-Joule-heated CNTs are simultaneously determined. Experimental ln(J/T2) − 1/T plots are found to exhibit an upward bending feature deviating from the straight lines in Richardson plots, and the measured electron emission density is more than one order of magnitude higher than that predicted by Richardson's law. The breakdown of Richardson's law implies a much better electron emission performance of individual CNTs as compared to their macroscopic allotropes and clusters, and the need of new theoretical descriptions of electron emission from individual low-dimensional nanostructures.
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机译:在纳米尺度上探究经典宏观物理定律的有效性对纳米科学研究至关重要。在这里,我们报告的实验证据表明,通过自焦耳加热加热的单个热碳纳米管(CNT)的电子发射不符合理查森热电子发射定律。通过使用原位多探针测量技术,可以同时确定各个自焦耳加热的CNT的电子发射密度(J)和温度(T)。发现实验ln(J / T 2 )− 1 / T图显示出向上弯曲的特征,与Richardson图中的直线有所偏离,并且测得的电子发射密度大于一个数量级。比理查森定律所预测的要高。理查森定律的破裂意味着与它们的宏观同素异形体和簇相比,单个CNT的电子发射性能要好得多,并且需要对单个低维纳米结构的电子发射进行新的理论描述。
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