Theory of triboelectric nanogenerators for self-powered systems

Niu, Simiao

27 May 2016

Energy science is becoming an increasingly important multi-disciplinary area, for not only addressing the worldwide energy crisis, but also realizing desired power sources with advanced features for portable electronic devices and sensor networks. Very recently, based on triboelectric effect and electrostatic induction, a fundamentally new technology, triboelectric nanogenerator, has been demonstrated which shows unique merits. But so far, the main limitation for continuing optimizing their output performance is a lack of fundamental understanding of their core working mechanism. In this thesis research, we first unveil the fundamental theory and output characteristics of triboelectric nanogenerators. Then, we apply the developed theory to the TENG-based self-powered system design. We have developed the first genuine self-powered system to meet mW requirement of personal electronics. The system includes a multilayered TENG, a power management circuit with 60% total efficiency, and a low leakage energy storage device. Our power management circuit provides the total efficiency that is about two magnitudes higher than the traditional direct charging. And the total system performance is 330 times higher than the state-of-art designs. Driven by palm tapping, this power unit can provide a continuous DC electricity of 1.044 mW on average power in a regulated and managed manner that can be universally applied as a standard power source for continuously driving numerous conventional electronics, such as a thermometer, a heart rate monitor (electrocardiograph/ECG system), a pedometer, a wearable electronic watch, a scientific calculator, and a wireless radio-frequency communication system. Our study demonstrates the first power unit that utilizes widely accessible biomechanical energy source to sustainably drive a broad range of commercial mobile and wearable electronic devices. This self-charging unit is a paradigm shift towards infinite-lifetime energy sources that can never be achieved solely by batteries.

Triboelectric nanogenerators

Self-powered systems

Simulation

Nanomanufacturing of Wearable Electronics for Energy Conversion and Human-integrated Monitoring

Min Wu (9745856)

14 December 2020

<div>Recently, energy crisis and environment pollution has become global issues and there is a great demand for developing green and renewable energy system. At the same time, advancements in materials production, device fabrication, and flexible circuit has led to the huge prosperity of wearable devices, which also requires facile and efficient approaches to power these ubiquitous electronics. Piezoelectric nanogenerators and triboelectric nanogenerators have attracted enormous interest in recent years due to their capacity of transferring the ambient mechanical energy into desired electricity, and also the potential of working as self-powered sensors. However, there still exists some obstacles in the aspect of materials synthesis, device fabrication, and also the sensor performance optimization as well as their application exploration.</div><div>Here in this research, several different materials possessing the piezoelectric and triboelectric properties (selenium nanowires, tellurium nanowires, natural polymer hydrogel) have been successfully synthesized, and also a few novel manufacturing techniques (additive manufacturing) have been implemented for the fabrication of wearable sensors. The piezoelectric and triboelectric nanogenerators developed could effectively convert the mechanical energy into electricity for an energy conversion purpose, and also their application as self-powered human-integrated sensors have also been demonstrated, like achieving a real-time monitoring of radial artery pulses. Other applications of the developed sensors, such as serving as electric heaters and infrared cloaking devices are also presented here. This research is expected to have a positive impact and immediate relevance to many societally pervasive areas, e.g. energy and environment, biomedical electronics, and human-machine interface.</div><div><br></div>

Functional Materials

Additive Manufacturing

Wearable Electronics

Energy Harvesting

Energy Conversion

Human-integrated Monitoring