such as conducting polymers and carbon nanotubes, metal-the most conventional conductor-still outperforms significantly in terms of the electrical conductivity, device compatibility, materials stability, and cost-effectiveness. [1,[30][31][32][33][34][35][36][37][38] In particular, with the recent understanding of the nanomechanics of the metal and the soft structural design, metal conductors are indispensable for most of the flexible and wearable applications.In the literature, the fabrication of metal conductors typically consists of vacuum deposition of the metal and subsequent patterning with photolithography. Although this fabrication strategy can be directly applied on flexible polymeric substrates, it is often too costly for most flexible applications and may encounter materials instability issues of the flexible substrates at high vacuum or strong solvent. In addition, vacuum technology is not suitable for coating substrates with 3D structures such as foams, fibers, and arbitrary surfaces. This has led to extensive research on developing solution-based metal deposition and printing methods in the past three decades. The most reported solution-based strategy is the so-called "metal ink" method, in which solution-dispersed nanostructured metal particles (including nanoparticles (NPs), nanowires, nanotubes, and nanoplates) or metal precursors are cast or printed onto the flexible substrates and then thermally sintered or chemically reduced to yield the metallic conductors. [39][40][41][42][43] Nevertheless, they are still not widely used because of the following reasons. 1) The metal conductor fabricated through the "metal ink" method shows much lower electrical conductivity compared to their bulk, due to the additives of the ink (such as surfactants, binders, and stabilizers) and the large contact resistance between the NPs. [44,45] 2) The "metal ink" method works very well with noble metals such as Au and Ag, but is not compatible with more frequently used, yet less stable metals such as Cu and Ni. Even though there has been a major shift of research focus from Ag to Cu in recent years, inks for making high-quality Cu or Ni conductors at low-temperature and in the air atmosphere are yet to be developed. 3) The metal conductors made by the "metal ink" method are more suitable for interconnects but are less suitable for electrode applications due to the high roughness and impurity of the metal film. 4) Penetration of the "metal ink" into highly porous substrates or structures with small gaps is The rapid development of flexible and wearable electronics favors low-cost, solution-processing, and high-throughput techniques for fabricating metal contacts, interconnects, and electrodes on flexible substrates of different natures. Conventional top-down printing strategies with metal-nanoparticleformulated inks based on the thermal sintering mechanism often suffer from overheating, rough film surface, low adhesion, and poor metal quality, which are not desirable for most flexible electronic applications. In recent ...
