Saha Dipanjan, Yu Xiaoxiao, Du Yanhao, Guo Zhitao, Xiong Feng, Gellman Andrew J, Malen Jonathan A
Department of Mechanical Engineering, Carnegie Mellon University, Pittsburgh, Pennsylvania 15213, United States.
Department of Chemical Engineering, Carnegie Mellon University, Pittsburgh, Pennsylvania 15213, United States.
ACS Appl Mater Interfaces. 2020 Jul 29;12(30):34317-34322. doi: 10.1021/acsami.0c06953. Epub 2020 Jul 16.
To identify superior thermal contacts to graphene, we implement a high-throughput methodology that systematically explores the Ni-Pd alloy composition spectrum and the effect of Cr adhesion layer thickness on thermal interface conductance with monolayer graphene. Frequency domain thermoreflectance measurements of two independently prepared Ni-Pd/Cr/graphene/SiO samples identify a maximum metal/graphene/SiO junction thermal interface conductance of 114 ± (39, 25) MW/m K and 113 ± (33, 22) MW/m K at ∼10 at. % Pd in Ni-nearly double the highest reported value for pure metals and 3 times that of pure Ni or Pd. The presence of Cr, at any thickness, suppresses this maximum. Although the origin of the peak is unresolved, we find that it correlates with a region of the Ni-Pd phase diagram that exhibits a miscibility gap. Cross-sectional imaging by high-resolution transmission electron microscopy identifies striations in the alloy at this particular composition, consistent with separation into multiple phases. Through this work, we draw attention to alloys in the search for better contacts to two-dimensional materials for next-generation devices.
为了识别与石墨烯具有更好热接触的材料,我们采用了一种高通量方法,系统地探索了镍 - 钯合金成分范围以及铬粘附层厚度对与单层石墨烯热界面电导的影响。对两个独立制备的镍 - 钯/铬/石墨烯/二氧化硅样品进行频域热反射测量,发现在镍中钯含量约为10原子百分比时,金属/石墨烯/二氧化硅结的最大热界面电导为114 ± (39, 25) MW/m²K和113 ± (33, 22) MW/m²K,几乎是已报道的纯金属最高值的两倍,是纯镍或钯的三倍。任何厚度的铬的存在都会抑制这一最大值。尽管峰值的起源尚未明确,但我们发现它与镍 - 钯相图中出现混溶间隙的区域相关。通过高分辨率透射电子显微镜进行的横截面成像确定了该特定成分合金中的条纹,这与分离成多个相是一致的。通过这项工作,我们提请人们关注合金在为下一代器件寻找与二维材料更好接触方面的作用。
