Abstract:
Flexible electronics made from carbon nanotubes have become a viable technique for future oriented
electronic devices because of their remarkable electrical, mechanical, and thermal
characteristics. With regard to flexible electronics based on CNTs, this study aims to
investigate prospective applications, problems, and their preferable solutions. An overview of
CNT's special qualities, including their high conductivity, electrical flexibility, and resilience,
which make them the perfect material for flexible electronics, is presented at the beginning of
the paper. In order to create outstanding CNT circuits on flexible substrates, proper analysis
has been done on alternative manufacturing procedures, comprising CNT advancement and
alignment. The article explores their applications in biomedical implants, wearable sensors,
flexible screens, and energy storage systems. The presentation of significant accomplishments,
such as efficient transistors, transparent sensors, and flexible batteries, illustrates the potential
influence of CNT-based technology in various areas. It also outlines the remaining difficulties
and possible solutions for the development of flexible electronics based on CNT. Along with
the necessity of standardization and process optimization, the concerns of CNT purity,
consistency, and device stability are examined. The most significant role of additional studies
is to promote long-term stability, explore fresh applications, and improve device performance.
For academics, engineers, and business professionals involved in the area of flexible
electronics, this study offers an in-depth overview of the state of the sector today. The information gathered from this paper will help CNT-based technologies to continue to improve
and be adopted, enabling the development of revolutionary applications across multiple fields
of study.
KEYWORDS: Carbon Nanotube, Flexible Electronics, Nanotechnology, 2D materials,
High-Performance Device
