# Wireless Sensor Node Self-Powered by a Hybrid-Supercapacitor and a Multi-Junction Solar Module

**Authors:** Mara Bruzzi, Irene Cappelli, Mirko Brianzi, Carlo Cialdai, Ada Fort, Valerio Vignoli

PMC · DOI: 10.3390/s26051475 · Sensors (Basel, Switzerland) · 2026-02-26

## TL;DR

A self-powered wireless CO2 sensor uses solar energy and a supercapacitor to monitor environmental CO2 levels without maintenance.

## Contribution

A compact, self-powered wireless CO2 sensing node using a hybrid supercapacitor and multijunction solar module for long-term monitoring.

## Key findings

- The system achieves autonomous operation with reliable data transmission under low irradiance conditions.
- The CO2 sensor resolves photosynthesis–respiration cycles and their dependence on solar radiation.
- The hybrid supercapacitor maintains stable voltage over yearly cycles.

## Abstract

This work presents a compact, self-powered wireless CO2 sensing node for autonomous environmental monitoring. The system integrates a high-efficiency multijunction photovoltaic (PV) module, a 4000 F hybrid supercapacitor operating at 3.6–4.2 V, and a custom power management system in a LiPo-sized form factor. The PV module, composed of nine parallel triple-junction solar cells, achieves an average efficiency of 27% and delivers peak power at 4.26 V under 600 W/m2 irradiance. The sensing unit includes miniaturized CO2, humidity, and temperature sensors with LoRa-based wireless communication. The low-power NDIR CO2 sensor provides a resolution of 15–20 ppm and a response time of ~45 s. Week-long tests demonstrated fully autonomous operation with reliable 5 min data transmission, capturing diurnal CO2 variations associated with plant activity even under low irradiance. Energy storage occurs for irradiance levels ≥65 W/m2, and long-term simulations confirm stable supercapacitor voltage over yearly cycles. This work demonstrates a compact multijunction solar–hybrid supercapacitor platform capable of sustaining WSN for long-term, maintenance-free CO2 monitoring under real-world and low-irradiance conditions. Our results demonstrate that the sensing node can reliably monitor plant-driven CO2 dynamics, clearly resolving the expected photosynthesis–respiration cycles and their dependence on incident solar radiation, while simultaneously sustaining its energy budget under highly challenging illumination and transmission conditions.

## Full-text entities

- **Chemicals:** CO2 (MESH:D002245)

## Full text

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## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12987167/full.md

## References

31 references — full list in the complete paper: https://tomesphere.com/paper/PMC12987167/full.md

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Source: https://tomesphere.com/paper/PMC12987167