Highly Durable Janus Fabrics Based on Transfer Prints for Personal Moisture Management

Janus fabrics with moisture management ability have great potential for improving both physiological and psychological comfort of human body. However, current methods for creating Janus fabrics are typically complex, environmentally unfriendly, and costly. More importantly, the prepared Janus fabrics have demonstrated insufficient mechanical properties and poor fastness, rendering them unsuitable for practical applications. Here, this work proposes a method for constructing Janus fabrics through thermal transfer printing of hydrophobic transfer prints onto a superhydrophilic cotton fabric, followed by creation of a conical micropore array on the fabric surface. The as-prepared Janus fabrics exhibit excellent unidirectional liquid transport capacity, capable of transporting 50 mu L water completely in 11.6 s in the positive direction. Attributed to the durable property of the transfer prints, the Janus fabrics are capable of withstanding over 900 friction cycles and 250 home laundry cycles, which is a great advance in this research field. Additionally, the fabrication process has no detrimental effect on the fabric's breathability, elasticity, and flexibility. Furthermore, the Janus fabric can maintain human body temperature 3.6 degrees C cooler than that worn with cotton fabric. The fabrication method can provide useful insights for the design and creation of durable Janus fabrics to maximize personal comfort.

Automated summary

This work proposes a simple, environmentally friendly, and cost-effective method for constructing Janus fabrics by thermal transfer printing and creation of a conical micropore array on cotton fabric. The as-prepared Janus fabrics demonstrate excellent unidirectional liquid transport capacity and durability. The fabrication process has no detrimental effect on the fabric's breathability, elasticity, and flexibility, and the Janus fabric can maintain human body temperature 3.6 degrees C cooler than cotton fabric.