Electrically Conductive Polymer Blends Enhanced by Graphene-Based Additives

Graphene oxide and reduced graphene oxide were introduced into polymer blends to impart electrical conductivity. The resulting materials demonstrated suitability for flexible electronics and antistatic packaging. The implications of these findings extend across various industrial applications including packaging, biomedical devices, automotive parts, and construction materials. Future work will focus on scaling synthesis methods, evaluating environmental stability, and conducting long-term performance tests. The results contribute to the growing body of research on additive-enhanced polymers and open avenues for optimizing their use under practical service conditions. The implications of these findings extend across various industrial applications including packaging, biomedical devices, automotive parts, and construction materials. Future work will focus on scaling synthesis methods, evaluating environmental stability, and conducting long-term performance tests. The results contribute to the growing body of research on additive-enhanced polymers and open avenues for optimizing their use under practical service conditions. The implications of these findings extend across various industrial applications including packaging, biomedical devices, automotive parts, and construction materials. Future work will focus on scaling synthesis methods, evaluating environmental stability, and conducting long-term performance tests. The results contribute to the growing body of research on additive-enhanced polymers and open avenues for optimizing their use under practical service conditions.