Composite nanowires for room-temperature mechanical and electrical bonding

TL;DR

This paper reviews recent advances in composite nanowires, such as Cu/parylene, Cu/polystyrene, and CNT-Cu/parylene, for enabling room-temperature mechanical and electrical bonding in electronic assemblies, overcoming limitations of traditional methods.

Contribution

It summarizes fabrication techniques and performance evaluations of composite nanowires as innovative room-temperature bonding solutions.

Findings

Composite nanowires enable effective room-temperature bonding.

Fabrication methods include using AAO and PC membranes.

Performance tests show promising mechanical and electrical properties.

Abstract

At millimeter dimension or less, the conventional bonding technology in electronic assembly relies heavily on reflow soldering and suffers from severe performance and reliability degradation. Meanwhile, the traditional high temperature bonding process (easily reach 220 oC) tends to result in undesired thermal damage and residual stress at the bonding interface. It is therefore a major challenge to find a means to preparing room-temperature connectors or fasteners with good mechanical and electrical bonding. Very recently, composite nanowire have been used to fabricate room-temperature fasteners. In this chapter, we summarize the state-of-the-art progress on the use of composite nanowires for room-temperature mechanical and electrical bonding. Using anodic aluminum oxide (AAO) and polycarbonate (PC) membrane as template, the fabrication of Cu/parylene and Cu/polystyrene nanowires were described. Meanwhile, the fabrication of carbon nanotube (CNTs) array was summarized. Then, the performances of the composite nanowires (Cu/parylene, Cu/polystyrene and CNT-Cu/parylene) used as surface fastener for room-temperature mechanical and electrical bonding were demonstrated.