Abstract: A product includes a metallogel material having metal ions dispersed in an assembly having an organic compound. A method includes combining a metal salt, an organic compound precursor, and a glyme for forming a metallogel material having metal ions dispersed in an assembly having an organic compound.

Abstract: The present disclosure relates to a system for optimizing an additive manufacturing (AM) process. The system may use a printing component for using a material to form a component in a layer-by-layer process. An electronic controller may control movement of one of the printing component or a substrate on which the component is being formed, in a manner to optimize a toolpath for the printing component as each layer of the component is formed. Optimization operations are performed using an optimization subsystem which enables manufacturability constraints, as well as optimized toolpaths for each layer of the component, to be defined using contours of a level-set function. The level-set function may be used to define the optimized toolpaths within a fixed, predetermined grid, and the optimized toolpaths then used to generate suitable code for controlling movement of the printing component relative to the substrate to create the part or structure in a layer-by-layer process, using the optimized toolpaths.

Abstract: In accordance with one embodiment, a metal part includes a geometric three-dimensional printed structure consisting essentially of pure metal. In accordance with another embodiment, a metallic precursor resin includes a metallopolymer material including a metal-thiolate polymer. The metallopolymer material is a metallogel. The metallogel is substantially transparent and has a viscosity for enabling three-dimensional printing thereof.

Abstract: A product includes a metallogel material having metal ions dispersed in an assembly having an organic compound. A method includes combining a metal salt, an organic compound precursor, and a glyme for forming a metallogel material having metal ions dispersed in an assembly having an organic compound.

Abstract: The present disclosure relates to a system for optimizing an additive manufacturing (AM) process. The system may use a printing component for using a material to form a component in a layer-by-layer process. An electronic controller may control movement of one of the printing component or a substrate on which the component is being formed, in a manner to optimize a toolpath for the printing component as each layer of the component is formed. Optimization operations are performed using an optimization subsystem which enables manufacturability constraints, as well as optimized toolpaths for each layer of the component, to be defined using contours of a level-set function. The level-set function may be used to define the optimized toolpaths within a fixed, predetermined grid, and the optimized toolpaths then used to generate suitable code for controlling movement of the printing component relative to the substrate to create the part or structure in a layer-by-layer process, using the optimized toolpaths.

Abstract: According to one inventive concept, a metallopolymer material includes a plurality of nanoparticles, a base, and water. Each of the nanoparticles includes a plurality of oligomer segments, where oligomer segments are coordinated to adjacent oligomer segments. Each of the oligomer segments includes a thiol and a metal.

Abstract: According to one embodiment, a method of forming a metal foam with substantially uniform density includes forming a metallopolymer network including metallopolymer material with pre-defined ionic conductivity and pre-defined polymeric chain length, adding a reductant to the metallopolymer network during formation thereof for creating metal nanoparticles in the metallopolymer network, where the metal nanoparticles have substantially uniform size, and heating the reduced metallopolymer network for sintering the metal nanoparticles into a network.