Highly conductive strain resilient electronics interconnects and traces

What is claimed is: 1. A method of making an electrically conductive, flexible product comprising: providing metal coated carbon nanotube networks with metal nanoparticles disposed on and around junctions between individual nanotubes in the metal coated carbon nanotube networks and heating the metal coated carbon nanotube networks to a temperature sufficient to melt the metal nanoparticles and form metal welds at the junctions while maintaining the temperature of the metal coated carbon nanotube networks to a sufficiently low temperature so as to avoid damaging the metal coated carbon nanotube networks; next, mixing the metal coated carbon nanotube networks with a liquid polymeric resin to produce a liquid mixture; and curing the liquid mixture to produce the electrically conductive, flexible product. 2. The method of claim 1 further comprising after the mixing step, depositing the liquid mixture on a flexible substrate and curing the liquid mixture on the flexible substrate to produce a flexible, electrically conductive, strain resilient electrical circuit on the substrate. 3. The method of claim 1 wherein the mixing step further comprises mixing the liquid polymeric resin and the metal coated carbon nanotube networks with a volatile solvent to produce a liquid mixture having a selected viscosity; after the mixing step, printing the liquid mixture onto a flexible substrate using a three-dimensional printer that is configured to print with material of the selected viscosity to produce a printed mixture on the flexible substrate; and curing the printed mixture for a curing period of time in an atmosphere that absorbs the solvent so that, after the curing period, the solvent evaporates from the printed mixture to produce a solid, flexible, strain resilient, electrically conductive, polymeric electrical circuit on the flexible substrate. 4. The method of claim 1 further comprising producing the electrically conductive, flexible product to have a selected conductivity by adjusting the amount of the metal coated carbon nanotube networks relative to the amount of liquid polymeric resin in the liquid mixture, whereby increasing the relative amount of the metal coated carbon nanotube networks increases the conductivity of the electrically conductive, flexible product. 5. The method of claim 1 further comprising producing the electrically conductive, flexible product to have a selected conductivity by adjusting the weight percentage of the metal coated carbon nanotube networks in the liquid mixture from 50% to 90%. 6. The method of claim 1 further comprising producing the electrically conductive, flexible product to have a selected storage modulus by adjusting the weight percentage of the metal coated carbon nanotube networks in the liquid mixture. 7. The method of claim 1 further comprising after the mixing step, printing the liquid mixture on a flexible, electrically insulating, substrate and curing the mixture on the flexible, electrically insulating, substrate to produce a flexible conductive electrical circuit on the flexible, electrically insulating, substrate. 8. The method of claim 1 wherein the step of mixing comprises one or more of three roll milling or mixing with a planetary centrifugal mixer. 9. The method of claim 1 wherein the step of mixing comprises degassing the liquid mixture with a vacuum.