摘要
Wearable bioelectronics,capable of detecting and quantifying physiological data generated by human movement and activity,have garnered global research and commercial attention.Traditional designs employing inflexible electrodes typically adhere to the skin or organs through tapes,clips,or comparable means,resulting in incongruent bodily contact and the generation of distorted or exceedingly noisy physical signals[1–5].Emerging flexible electronic textiles(e-textiles)integrating advanced digital components and electronic devices exhibit tremendous application potential in human motion detection,personal protection,human–machine interfaces,real-time and long-term monitoring.However,numerous flexible bioelectronics were fabricated by impermeable polymer films or gels,which hindered the gas or moisture exchange between human skin and surrounding environment.Prolonged contact causes sweat accumulation,leading to discomfort wearing experiences and signal distortion.Hence,achieving simultaneous optimization of thermal and moisture comfort for individuals,while upholding electrical performance integrity,continues to pose a severe challenge.