A Breathable and Strain‐Insensitive Multi‐Layered E‐Skin Patch for Digital Healthcare Wearables

Author:

Pradhan Gagan Bahadur12ORCID,Jeong Seonghoon12,Sharma Sudeep12,Lim SeungJae12,Shrestha Kumar12,Lee YeYoung12,Park Jae Yeong123ORCID

Affiliation:

1. Advanced Sensor and Energy Research Laboratory Department of Electronic Engineering Kwangwoon University 447‐1 Wolgye‐dong Nowon‐gu Seoul 01897 Republic of Korea

2. Human IoT Focused Research Center Kwangwoon University 447‐1 Wolgye‐dong Nowon‐gu Seoul 01897 Republic of Korea

3. SnE Solutions Co. Ltd. 447‐1 Wolgye‐dong Nowon‐gu Seoul 01897 Republic of Korea

Abstract

AbstractIn this study, a breathable and strain‐insensitive multi‐layered electronic skin (e‐skin) capable of real‐time detection and distinction of electrocardiogram (ECG) signals, temperature, and skin hydration is developed. Leveraging a scalable benchtop method, sensing elements are transferred onto porous and hydrophobic substrates, followed by multi‐layer stacking to enable multimodal sensing. The sensing elements, a combination of carbon nanotube and nanoporous carbon (CNT@NPC) ink, are applied using strain‐insensitive patterned masks, then spray‐coated with styrene–ethylene–butylene–styrene (SEBS) to create a hierarchical porous network through phase separation. The CNT@NPC networks exhibit an improvement in strain insensitivity with active sensing capabilities due to their adaptable molecular tuning capacity and exceptional electrical conductivity. The porous SEBS substrate offers strong bonding with CNT@NPC attributed to the π–π interactions and high kinetic energy dispersion from spray coating allowing effective transfer. This unique design facilitates breathability, and miniaturization that minimizes the interference between different sensing modalities, ensuring accurate and reliable data acquisition. The breathability (3.49 mg cm−2 h−1) and the non‐smearing nature of the multi‐layered e‐skin enables simultaneous monitoring of temperature (0.198% °C−1), skin hydration (relative humidity = 0.77% %−1), and ECG (26 ± 1 dB) with continuous data transmission to a remote smartphone interface.

Funder

National Research Foundation of Korea

Ministry of Science and ICT, South Korea

Ministry of Trade, Industry and Energy

Publisher

Wiley

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