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Monitoring humidity and temperature is critical for many applications, including enhancing food production in greenhouses and open farms. This demands for environmentally friendly, cost-effective, and biocompatible sensors. Paper-based sensors meet these requirements as they are cost-effective, eco-friendly, and adaptable to varying agricultural conditions due to their affordability, biodegradability, and flexibility. This research developed printed capacitance-based humidity and resistance-based temperature sensors using a dry additive nanomanufacturing technique on four distinct types of commercially available uncoated paper substrates. Based on the principles of a capacitor and resistor, humidity and temperature sensors were fabricated by printing silver interdigitated electrodes on papers with varying solubility and thicknesses to measure the humidity absorption capability and the printed silver electrode’s response to temperature change. The sensors successfully detected the changes in relative humidity levels from 20 to 90% and temperature variations from 25 to 50 °C. The humidity and temperature sensors developed in this study have strong implications for use in smart agricultural applications, food supply, food storage, and preservation. Since these sensors are affordable, biodegradable, and environmentally friendly, they can be intended for one- or two-time applications and safely disposed of after use. 

Additively manufactured electronics (AMEs), also known as printed electronics, are becoming increasingly important for the anticipated Internet of Things (IoT). This requires manufacturing technologies that allow the integration of various pure functional materials and devices onto different flexible and rigid surfaces. However, the current ink-based technologies suffer from complex and expensive ink formulation, ink-associated contaminations (additives/solvents), and limited sources of printing materials. Thus, printing contamination-free and multimaterial structures and devices is challenging. Here, a multimaterial additive nanomanufacturing (M-ANM) technique utilizing directed laser deposition at the nano and microscale is demonstrated, allowing the printing of lateral and vertical hybrid structures and devices. This M-ANM technique involves pulsed laser ablation of solid targets placed on a target carousel inside the printer head for in-situ generation of contamination-free nanoparticles, which are then guided via a carrier gas toward the nozzle and onto the surface of the substrate, where they are sintered and printed in real-time by a second laser. The target carousel brings a particular target in engagement with the ablation laser beam in predetermined sequences to print multiple materials, including metals, semiconductors, and insulators, in a single process. Using this M-ANM technique, various multimaterial devices such as silver/zinc oxide (Ag/ZnO) photodetector and hybrid silver/aluminum oxide (Ag/Al2O3) circuits are printed and characterized. The quality and versatility of our M-ANM technique offer a potential manufacturing option for emerging IoT.