Architected materials for enhanced energy absorption

What is claimed is: 1. A three-dimensional lattice architecture with a thickness hierarchy, comprising: a first surface and a second surface separated from each other with a distance therebetween defining a thickness and a thickness direction of the lattice architecture; and a plurality of lattice structures stacked on one another in the thickness direction forming an interface in between, wherein a set of unit cell parameters of a lattice structure of the plurality of lattice structures is different from a set of unit cell parameters of a neighboring lattice structure, wherein the plurality of lattice structures comprises a first lattice structure and a second lattice structure bond through a first interface to the first lattice structure, and wherein a portion of ends of the first lattice structure that are on the first interface and a portion of ends of the second lattice structure that are on the first interface do not contact each other. 2. The three-dimensional lattice architecture of claim 1 , further comprising a facesheet located at the interface between two neighboring lattice structures. 3. The three-dimensional lattice architecture of claim 1 , wherein the first surface and/or the second surface is free of any facesheets. 4. The three-dimensional lattice architecture of claim 1 , further comprising a first facesheet bonded to one of the first surface and the second surface. 5. The three-dimensional lattice architecture of claim 4 , wherein the first facesheet comprises a facesheet material selected from the group consisting of metallic materials, polymeric materials, ceramic materials and composite materials. 6. The three-dimensional lattice architecture of claim 4 , further comprising a second facesheet bonded to the remaining one of the first surface and the second surface. 7. The three-dimensional lattice architecture of claim 6 , wherein the second facesheet comprises a facesheet material selected from the group consisting of metallic materials, polymeric materials, ceramic materials and composite materials. 8. The three-dimensional lattice architecture of claim 1 , wherein each of the lattice structures comprises a lattice structure material selected from the group consisting of solid metallic materials, solid polymeric materials, solid ceramic and solid composite materials. 9. The three-dimensional lattice architecture of claim 1 , wherein each of the lattice structures comprises a lattice structure material selected from the group consisting of hollow metallic materials, hollow polymeric materials, hollow ceramic materials and hollow composite materials. 10. A method of manufacturing a three-dimensional lattice architecture with a thickness hierarchy, the method comprising: providing a first volume of photo-monomer in a first container; exposing the first volume of photo-monomer to collimated light through a first mask, the collimated light passing through a plurality of first apertures of the first mask at a first non-perpendicular angle with respect to the mask to form a first plurality of angled polymer struts in the photo-monomer at the non-perpendicular angle to form a first three-dimensional lattice structure having a first set of unit cell parameters, a first top surface and a first bottom surface; providing a second volume of photo-monomer in a second container; exposing the second volume of photo-monomer to collimated light through a second mask, the collimated light passing through a plurality of second apertures of the second mask at a second non-perpendicular angle with respect to the mask to form a second plurality of angled polymer struts in the photo-monomer at the non-perpendicular angle to form a second three-dimensional lattice structure having a second set of unit cell parameters, a second top surface and a second bottom surface; and connecting the first top surface with the second bottom surface; wherein the first set of unit cell parameters and the second set of unit cell parameters are different, and wherein a portion of ends of the first plurality of angled polymer struts of the first three-dimensional lattice structure that are on the first top surface and a portion of ends of the second plurality of angled polymer struts of the second lattice structure that are on the second bottom surface do not contact each other. 11. The method of claim 10 , wherein the first container and the second container are the same container, and the connection between the first top surface and the second bottom surface is controlled through the exposure intensity. 12. The method of claim 10 , wherein the first container and the second container are different containers, and the connecting of the first top surface with the second bottom surface is through adhesive, UV flash-weld, welding under pressure at elevated temperature, thermal post-cure, heat bonding, and/or solvent bonding. 13. The method of claim 10 , wherein the second container comprises the first container, and the connecting of the first top surface with the second bottom surface is through controlling the exposure intensity.