Facilely constructed two-sided microstructure interfaces between electrodes and cellulose paper active layer: eco-friendly, low-cost and high-performance piezoresistive sensor

• Published in: Cellulose (London) Vol. 28; no. 10; pp. 6389 - 6402
• Main Authors: Duan, Zaihua, Jiang, Yadong, Huang, Qi, Wang, Si, Zhao, Qiuni, Zhang, Yajie, Liu, Bohao, Yuan, Zhen, Wang, Yang, Tai, Huiling
• Format: Journal Article
• Language: English
• Published: Dordrecht Springer Netherlands 01.07.2021; Springer Nature B.V
• Subjects: Bioorganic Chemistry; carbon; Carbon nanotubes; Cellulose; Ceramics; Chemistry; Chemistry and Materials Science; Composites; durability; Electrodes; finite element analysis; Finite element method; Glass; Low cost; Microstructure; Natural Materials; Organic Chemistry; Original Research; Physical Chemistry; polyesters; Polymer Sciences; Pressure distribution; Pressure sensors; Raw materials; Sensors; speech; Speech recognition; Stress concentration; Sustainable Development; Wrist; Microstructure interface; Piezoresistive sensor; Carbon ink; Polyester conductive tape; Cellulose paper; Wearable applications
• ISSN: 0969-0239; 1572-882X
• DOI: 10.1007/s10570-021-03913-8

The microstructure plays an important role in improving the sensing performance of pressure sensor. However, the design of microstructural active layer of pressure sensor usually involves complex process and expensive raw materials. Herein, the common polyester conductive electrodes and cellulose paper that both have inherent microstructure surface are combined to form two-sided microstructure interfaces for low-cost, eco-friendly and high-performance flexible piezoresistive pressure sensor. In order to obtain conductive and low-cost active layer paper, daily carbon ink, which is usually used for writing, is preferred as a conductive material. Meanwhile, we experimentally confirm that the proposed structure is also suitable for other conductive materials, such as carbon nanotubes. The results show that as-fabricated piezoresistive sensor has high pressure sensitivities of 5.54 and 1.61 kPa −1 in the wide linear ranges of 0.5 − 5 and 5 − 60 kPa, respectively, and good durability (5000 cycles under 2 kPa). The sensing mechanism of the piezoresistive sensor is analyzed by combining the characterization results and finite element simulation. Benefitting from the high sensing performance and good flexibility, the piezoresistive sensor is demonstrated for multiple wearable applications (e.g., wrist pulse, speech recognition, finger bending, abdominal respiration, counting steps, and pressure distribution). This work provides a simple and effective strategy for the design of piezoresistive sensor from the microstructure interfaces between electrodes and active layer. Graphic abstract