Metal nanofibrils embedded in long free-standing carbon nanotube fibers with a high critical current density

With the growth of nanoelectronics, the importance of thermal management in device packaging and the improvement of high-current-carrying interconnects/wires for avoiding the premature failure of devices have been emphasized. The heat and electrical transport properties of the bulk may not be valid...

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Bibliographic Details
Published in:NPG Asia materials 2018-04, Vol.10 (4), p.146-155
Main Authors: Rho, Hokyun, Park, Min, Park, Mina, Park, Junbeom, Han, Jiyoon, Lee, Aram, Bae, Sukang, Kim, Tae-Wook, Ha, Jun-Seok, Kim, Seung Min, Lee, Dong Su, Lee, Sang Hyun
Format: Article
Language:English
Subjects:
140/133
639/301/357/73
639/301/357/995
Biomaterials
Carbon fiber reinforced plastics
Carbon nanotubes
Carrying capacity
Chemistry and Materials Science
Continuous fiber composites
Critical current density
Current carriers
Electrical properties
Electromigration
Electroplating
Energy Systems
Failure mechanisms
Grain boundaries
High current
Interconnections
Magnetic properties
Materials Science
Microfibers
Morphology
Nanoelectronics
Nanotubes
Optical and Electronic Materials
Structural Materials
Surface and Interface Science
Temperature dependence
Thermal management
Thin Films
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Summary:With the growth of nanoelectronics, the importance of thermal management in device packaging and the improvement of high-current-carrying interconnects/wires for avoiding the premature failure of devices have been emphasized. The heat and electrical transport properties of the bulk may not be valid in the characterization of a material at the nanometer level, because the phenomena that occur at the interfaces and grain boundaries become dominant. The failure mechanism of bulk metal interconnects has been understood in the context of electromigration; however, in nanoscale materials, the effect of the heat dissipation that occurs at the nanointerfaces may play an important role. Here, we report the preparation of continuous carbon nanotube (CNT)–Cu composite fibers that possess Cu nanofibrillar structures with a high current-carrying capacity. Various-shaped CNT–Cu microfibers with different Cu grain morphologies were produced via Cu electroplating on continuous CNT fibers. Cu fibril structures were embedded in the voids inside the CNT fiber during the early stage of electrodeposition. The temperature-dependent and magnetic field-dependent electrical properties and the ampacity of the produced CNT–Cu microfibers were measured, and the failure mechanism of the fiber was discussed. The interconnection of Cu nanograins on the surface of the individual CNTs contributed to the enhancement in the charge-carrying ability of the fiber. The effective ampacity of the Cu nanofibrils was estimated to be ~1 × 10 7  A/cm 2 , which is approximately 50 times larger than the ampacity measured for a bulk Cu microwire. Nanoelectronics: A hybrid approach to higher currents Nanoscale metal fibrils increase the maximum current a spun carbon nanotube fiber can carry before failing, researchers in South Korea demonstrate. Ensuring that components don’t overheat is a crucial consideration when designing electronic devices. High electrical currents can heat and thus damage the wires, or interconnects, that link different parts of the circuit. This is particularly important in nanoelectronics, where the interconnects are narrow. Sang Hyun Lee from the Korea Institute of Science and Technology, Jeonbuk, and colleagues addressed this problem by embedding copper fibrils within continuous carbon nanotube fiber. They compared various fibril shapes to systematically study the electrical and thermal properties at the interface between the copper and the carbon nanotube. The maximum current
ISSN:1884-4049
1884-4057
DOI:10.1038/s41427-018-0028-3