Recently, ionic conductive organohydrogels (ICOs) have received widespread attention in wearable electronics. However, it remains challenging to combine reliable ionic conduction with good mechanical strength well, especially under extreme conditions. Herein, a novel ICO is produced by assembling polyvinyl alcohol with functionalized cellulose nanofibrils (CNFs) via a DMSO/H2O sol-gel process. A comprehensive study of the quaternized and carboxylated CNFs on ICOs is made. It is found that embedding of the latter can help ICOs to present excellent mechanical properties (tensile/compressive stress of 2.10/7.61 MPa), freezing tolerance (- 78 degrees C), and the highest electrical conductivity (3.23 S center dot m(-1)). Since all the primary alcohol carbons in the carboxylated CNFs have been thoroughly carboxylated, it is undoubted that their intermolecular attraction is sharply decreased to increase the counterion Na+ attraction, thus providing more hopping sites to enhance the ion transfer. Moreover, benefiting from these advantages, a human-interactive sensor based on the novel ICO is constructed to discern multiple human motions, including finger bending, wrist flexing, elbow bending, and walking. Overall, a facile yet versatile strategy is introduced that is expected to shed light on fabricating ICOs with all-around performance applicable in wearable electronics.

• 单位
  y