In the present era, self-powered technology and smart materials have paved the way for the
design of numerous implantable energy harvesting and biomedical applications …

As artificial intelligence (AI) advances, it is critical to give conventional electronics the
capacity to “think,”“analyze,” and “advise.” The need for intelligent, self-powered devices has …

Recent substantial advancements in computational techniques, particularly in artificial
intelligence (AI) and machine learning (ML), have raised the demand for smart self-powered …

The µW‐level power density of flexible piezoelectric energy harvesters (FPEHs) restricts
their potential in applications related to high‐power multifunctional wearable devices. To …

To cater to the extensive body movements and deformations necessitated by biomedical
equipment flexible piezoelectrics emerge as a promising solution for energy harvesting. This …

This paper proposes a novel piezoelectric energy harvester with rotating-DOF to efficiently
achieve multimodal vibration energy harvesting in low-frequency environments. The …

The worldwide energy and environmental pollution crisis is caused partly by the rising
usage of non-renewable energy sources. Researchers try to find alternative energy systems …

Lead-free piezoelectric ceramic is a promising material for energy harvesters, as they have
superior electromechanical, ferroelectric, and piezoelectric properties. In addition …

This study explores an innovative energy harvesting technique for biomedical implants in
alignment with the United Nations Sustainable Development Goals, focusing on good health …

The popularity of smart electronic products has facilitated their incorporation into various
fields related to the Human-body, such as portable tools, wearable electronics …