Improvement of the electromagnetic properties of blended electromagnetic shielding fabric of cotton/stainless steel/polyester based on multi-layer MXenes

Blended electromagnetic shielding (EMS) fabrics of cotton/stainless steel/polyester have been widely applied. The porous structure of the fabric is the guarantee of its good comfort performance, but it also hinders the improvement of shielding efficiency and the endowing of wave absorption performance. To solve the above problems, this paper proposes a mixed resistance field based on fabric pores by the construction of multi-layer MXenes. Ti3AlC2 is etched by hydrochloric acid and lithium fluoride to generate hydrofluoric acid in situ to prepare multi-layer Ti3C2T (x) . The finishing experiments are designed to finish the fabric around the pores with Ti3C2T (x) impregnation. The enhancement effect and mechanism of the mixed resistance field on the shielding effectiveness and wave absorbing properties of the fabric are analyzed. The result shows that the multi-layer Ti3C2T (x) for textile finishing is prepared quickly and effectively using the proposed method. The micro media of the Ti3C2T (x) in the dispersion are adsorbed on the surface of various fibers, most of which are cotton fibers. The shielding effectiveness of the finished EMS fabric is improved significantly in the frequency ranges of 6.57-14 GHz and 11.97-18 GHz. The wave absorbing performances in the frequency range of 11.97-18 GHz are excellent. It is proved that the effect of the mixed resistance field of the pores was satisfactory. This paper provides a new way for the application of Ti3C2T (x) in EMS fabric, solves the disadvantages caused by pores, and can provide a reference for the design and production of wave absorbing EMS fabric.

Automated summary

This study proposes a new finishing method for EMS fabric by constructing multi-layer MXenes to improve the shielding efficiency and wave absorbing properties. The application of multi-layer Ti3C2T (x) has significantly enhanced the fabric's shielding effectiveness and wave absorbing performance according to the experimental results.