<p>The swift proliferation of Internet of Things (IoT) have heightened the demand for autonomous sensor nodes that eliminate dependence on battery replacements and intricate power management systems. Contemporary off-grid energy solutions sometimes rely on complex construction methods and specific materials, constraining their scalability and adaptability. A self-sustaining sensing system that utilizes the exceptional flexibility and stability of carbon electrodes were provided in conjunction with the outstanding photovoltaic capabilities of perovskite materials to accomplish effective energy harvesting and storage. Supercapacitors offer robust power buffering, guaranteeing uninterrupted functionality in fluctuating conditions. The gadget features dual-mode sensing for temperature and mechanical strain, exhibiting dependable and rapid detection capabilities in indoor lighting situations. Our approach offers a viable alternative for next-generation autonomous sensing networks by obviating the necessity for intricate manufacturing procedures and metal components susceptible to corrosion. This study presents a streamlined yet resilient methodology for the creation of self-sustaining IoT nodes, applicable in smart infrastructure and environmental surveillance.</p>

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Development of a carbon–perovskite self-powered IoT sensor node with dual-mode sensing

  • A. Shanavash,
  • T. Santhi Sri,
  • Mayakannan S.,
  • Sathish Kumar Shanmugam,
  • Pankaj H. Chandankhede,
  • B. G. Sivakumar

摘要

The swift proliferation of Internet of Things (IoT) have heightened the demand for autonomous sensor nodes that eliminate dependence on battery replacements and intricate power management systems. Contemporary off-grid energy solutions sometimes rely on complex construction methods and specific materials, constraining their scalability and adaptability. A self-sustaining sensing system that utilizes the exceptional flexibility and stability of carbon electrodes were provided in conjunction with the outstanding photovoltaic capabilities of perovskite materials to accomplish effective energy harvesting and storage. Supercapacitors offer robust power buffering, guaranteeing uninterrupted functionality in fluctuating conditions. The gadget features dual-mode sensing for temperature and mechanical strain, exhibiting dependable and rapid detection capabilities in indoor lighting situations. Our approach offers a viable alternative for next-generation autonomous sensing networks by obviating the necessity for intricate manufacturing procedures and metal components susceptible to corrosion. This study presents a streamlined yet resilient methodology for the creation of self-sustaining IoT nodes, applicable in smart infrastructure and environmental surveillance.