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Wilson College of Textiles 
Fang Research Group

Research


Fang Research Group has focused on the development of textile-based soft robotics, radiative cooling textiles, and functional textiles to enhance sustainability. These cutting-edge research areas have great potential to revolutionize the current textile technologies used in biomedical devices, textiles against extreme climates, and sustainable solutions to address high global carbon emissions and water pollution. Hence, the overarching research interest of Fang Research Group is the application of fibers and textiles to solve many of the quality of life issues including health and well-being in an ethical and sustainable manner. This group is a diverse research team of leaders who embrace diversity, equity and inclusion. To enable all levels of students in this group to be career-ready after the training in this laboratory, Dr. Fang has tailored mentoring opportunities for each individual student. The first two Ph.D. students, as PIs, both were awarded graduate student research funding from the Comparative Medical Institutes (CMI). Besides independent research skills, they are also fully trained to take leadership in teaching and mentoring undergrad students in research, publications and scholarly communications. They have mentored 15 undergrad research assistants working in this group, and helped them pursue research funding through the NCSU Office of Undergraduate Research (7 awards) and the Research Experiences for Undergraduates programs hosted by the college, and eventually published papers (all journal articles, conference presentations and proceedings include undergrad Research Assistants as authors). 

  • Fiber actuator/sensor

Wearable electronic devices are increasingly becoming a part of our daily lives. As the field of flexible electronics progresses, there is significant research underway to integrate wearable and other electronic capabilities into textiles. The motivation is obvious since smart textiles can be potentially employed in a wide range of applications. The unique and desirable properties of textiles are mostly derived from their hierarchical structure with fibers as building blocks. Fiber-based electrical devices are inherently advantageous because they combine breathability, conformability, strength and stability of textiles with electrical functionalities.

Fiber actuators and sensors, possessing excellent flexibility and inherent small scale. Obviously, they can be integrated into textiles, such as woven, knitting and nonwovens, to develop wearable smart systems for human health, protection or rehabilitation. These devices are also crucial components in smart systems that can monitor signals and generate responses in very confined space.

  • Integrating fiber electronics into textiles

To integrate fiber electronics into fabrics, textile technology provides variety of possibilities. Woven fabrics consist of two systems of orthogonal interlaced yarns that is ideal structure to assemble electrical circuits, such as tic-tac-toe logical controlled smart textiles; Knit fabrics consist of yarn loops are generally more flexible/deformable structures. Some of these are suitable for fabric actuators with large deformation capability.

  • Responsive Materials

Electroactive polymers (EAPs) exhibit shape change when subjected to an electric field. They are lightweight, soft, and inexpensive, while they are easy to process, shape, and tune to offer a broad range of mechanical and electrical properties. Dielectric electroactive polymers (D-EAP) constitute a class of EAPs with great potential. D-EAPs consist of physically or chemically cross-linked macromolecular networks and are mechanically isotopic. Therefore, in most actuator applications that require directional electromechanical response, it is necessary to use other complex means to direct the stress/strain in the preferred direction.