▎ 摘　　要

NOVELTY - The method involves applying nanowires (36) and graphene nanoribbons (34) onto a surface to form a network layer (32). The applying occurs by a method selected from the group consisting of filtration, ultrafiltration, coating, spin coating, spraying, spray coating, patterning, mixing, blending, thermal activation, electrochemical deposition, doctor-blade coating, screen printing, gravure printing, direct write printing, inkjet printing, and their combinations. The surface is a porous membrane. The nanowires and nanoribbons interconnect in the network layer. USE - Method for making electrically conductive material used as electrode for electronic device (all claimed). Uses include but are not limited to capacitors, lithium-ion capacitors, super capacitors, micro super capacitors, pseudo capacitors, batteries, lithium-ion batteries, electrodes, conductive electrodes, sensors, photovoltaic devices, photovoltaic cells, electronic circuits, fuel cell devices, thermal management devices, biomedical devices, transistors, water splitting devices, current collectors, and their combinations, as well as energy storage devices, while the battery is selected from the group consisting of micro batteries, lithium-ion batteries, lithium-sulfur batteries, sodium-ion batteries, magnesium-ion batteries, aluminum-ion batteries, and their combinations (all claimed). ADVANTAGE - The improved interfacial contact can in turn provide enhanced electrical properties, such as enhanced capacities. Due to the high capacities of the electrically conductive material, the energy storage devices provide faster charging times and longer discharging times. As in the case of random nanowire networks, higher aspect ratio materials enable more contact points, thus minimizing the overall resistance of the paper and also enabling formation of stable conductive path across the electrode. The facile and scalable filtration-based method to prepare entangled wire-ribbon films forms a stable anode with superior capabilities in areal and volumetric energy storage capacity and mechanical flexibility. DETAILED DESCRIPTION - INDEPENDENT CLAIMS are also included for the following: (1) an electrically conductive material; and (2) an electronic device. DESCRIPTION OF DRAWING(S) - The drawing shows the schematic view of an electrically conductive material. Electrically conductive material (30) Network layer (32) Graphene nanoribbons (34) Nanowires (36)