more attention due to their low resistance and relatively high ductility. One of the main methods used previously to fabricate transparent and stretchable conductors with metal nanomaterials is to create buckling confi gurations of metal nanowires on stretchable polymers, which can be classifi ed as in-plane or out-of-plane buckling (wavy) confi gurations. [ 25,26 ] For example, Ho et al. reported the fabrication of transparent and stretchable conductors based on buckled Ag nanowire fi lms with in-plane or out-of-plane buckling confi gurations. [ 25 ] In a similar approach, it was also demonstrated that the prestrain mode (e.g., uniaxial or biaxial prestrain), extent of prestrain ( ε pre ), and adhesion between metal nanowires and a stretchable substrate are important factors that affect the stretchability of such conductors. [ 26 ] Another approach is to obtain fl exibility or stretchability by making nanowire-based networks or one-body mesh structures. [23][24][25][26][27][28][30][31][32][33][34][35] Most studies concerning one-body mesh structures have reported their applications for fl exible conductors, rather than stretchable ones, with only a few exceptions. [ 30,34 ] For example, Jang et al. reported stretchable conductors made from one-body Pt nanomesh. [ 30 ] Although their Pt nanomesh maintained its conductive properties at as much as 16% strain, its stretchability does not seem to be high enough for it to be used in true wearable electronic devices. This limited stretchability is probably due to the rigid nature of its tightly connected one-body confi guration. On the other hand, networks of metallic nanowires are rather promising for future use as transparent and stretchable electrodes. [25][26][27][28] In these cases, the sheet resistance of percolated networks of metallic nanowires is critically governed by the aspect ratio, areal density, and size dispersity of nanowires. [ 36 ] Recently, extremely long metal nanofi bers generated via electrospinning techniques have been in the limelight as an alternative to metal nanowires, due to their extremely high aspect ratios as well as the simple and cost-effective fabrication process used to produce them. [37][38][39] In particular, metal nanofi ber networks in the form of nanotroughs [ 37,38 ] and metal/polymer core-shell structures [ 39 ] generated using electrospinning techniques have low strain sensitivities under tensile strains up to 70% due to the high aspect ratio of the nanofi bers and the network structures into which they are arranged. However, combining the above-mentioned buckled and network confi gurations with metallized electrospun nanofi bers has not been investigated for the fabrication of transparent and stretchable conductors.Herein, a novel strategy for obtaining transparent and stretchable conductors is presented, one that employs these two main approaches simultaneously. To the best of our knowledge, this proposed confi guration of a buckled long nanofi ber In the past decade, the fi eld of stretchable electronics has gained importa...
