In the past decade, the development of fabrication processes for aligning and pattering of silver nanowires (AgNWs) has accelerated dramatically, owing to their unique structures and various potential applications. Silver nanowires have many excellent features that bring forth the potentiality for sensing and optics applications, such as low resistivity, flexible properties, high scattering efficiency and high surface area ratio of metal nanowires. When materials are assembled to an unconventional substrate, they could be extended to much more applications, such as strain sensor with stretchable substrates. There are two parts in this study, “Patterning and Arranging Silver Nanowires on Polydimethylsiloxane (PDMS) for Strain Sensor” and “Alignment and Transfer Printing of Silver Nanowires Arrays for Solar Cell Application”. As far as strain sensor is concerned, various methods to pattern and print AgNWs on PDMS for strain sensor have been demonstrated in previous work, however, the complicated structures and sophisticated fabrication processes presented were expensive and time consuming. Therefore, a novel strategy “room-temperature surface treatment stencil patterning method” to print AgNWs electrode patterns on PDMS substrate is presented in this study with AgNWs aligned in the patterns by strain-release assembly method in the meanwhile, whose design is simple, low cost, fast, and overcomes mechanical and thermal restrictions of traditional microfabrication technologies. In detail, AgNWs serpentine electrodes with 250 µm wide (be able to 100 µm) are fabricated by utilizing shadow mask and oxygen plasma treatment, followed by aligning AgNWs in the same direction via strain release assembly methods. The bending test results of the strain sensor show that the fractional change in electrical current is close to linear with the strains, and the gauge factor is 6.4. As for AgNWs arrays for solar cell applications, our goal is to deposit AgNWs arrays on solar cell for enhancing photovoltaic conversion efficiency. The resulting alignment is ideal when AgNWs arrays are aligned on interdigitated electrodes by dielectrophoresis force in previous experiments, but not for aligning AgNWs arrays directly on silicon solar cell with pyramidal structure texture. In order to solve the limitations, integrating the alignment with transfer printing technique is adopted, and the fabrication approach is low-cost, fast, and scalable to large area NW arrays, which offers flexible applications for developing NW-based devices with unconventional substrates.