Energy dissipative composition including a hydrogel reinforced with nanoporous particles

The invention claimed is: 1 . A composition comprising a hydrogel and particles, each of the particles including a hollow nanopore that is vacant of a liquid when in an ambient state. 2 . The composition of claim 1 , further comprising a rigid external layer attached to the hydrogel, the rigid layer having a thickness dimension less than half of a length dimension and a width dimension. 3 . The composition of claim 2 , wherein the rigid external layer is a helmet shell, the hydrogel and nanoporous particles absorbing an impact on the shell. 4 . The composition of claim 2 , wherein the rigid external layer is metallic or ceramic armor of a vehicle, the hydrogel and nanoporous particles absorbing an impact on the armor. 5 . The composition of claim 2 , wherein the rigid external layer is armor, the hydrogel acting as a buffer against thermal shock of a hot projectile. 6 . The composition of claim 1 , wherein: the nanoporous particles are vacant of the liquid and the hydrogel operably absorbs an initial impact; and the liquid enters the nanopores if the impact is greater than a threshold value such that liquid infiltration into the nanopore of the particles assists in absorbing the greater impact. 7 . The composition of claim 1 , further comprising a hydrophobic layer on the particles to deter the liquid from entering the nanopore. 8 . The composition of claim 1 , wherein: the particles have a substantially spherical shape; there are multiples of the nanopores in each of the particles; each of the particles has a linear opening dimension of 2-400 nm; and each of the particles has a linear cross-sectional dimension of 3-100 microns. 9 . The composition of claim 1 , wherein: the particles have a substantially cylindrical shape; there are multiples of the nanopores in each of the particles; each of the particles has a linear opening dimension of 2-400 nm; and each of the particles has a linear cross-sectional dimension of 3-100 microns. 10 . The composition of claim 1 , wherein the hydrogel includes at least two polymeric hydrogel sublayers with a powder or coating layer of the nanoporous particles is sandwiched therebetween. 11 . The composition of claim 1 , wherein: the particles are an additive intermixed with the hydrogel; the particles serve as cross-linkers by interacting with polymeric chains of the hydrogel so as to strengthen the hydrogel polymer chains; and the nanopores are sized to increase an energy absorption capacity and toughness of the hydrogel. 12 . The composition of claim 1 , further comprising a biological member comprising: (a) a tendon, (b) a muscle, (c) a tissue, (d) an organ, or (e) a bone, attached to the hydrogel by adhesive, a suture or staple, the liquid entering the nanoporous particles in an impact situation. 13 . A composition comprising: (a) a hydrogel including a liquid; (b) particles contacting the hydrogel; (c) a layer of a material different than the hydrogel and the particles, the layer having at least one dimension larger than the hydrogel; (d) an initial impact force against the layer being at least partially absorbed by the hydrogel; and (e) a greater impact force against the layer causing liquid from the hydrogel to enter at least some of the particles, wherein the particles at least partially absorb the greater impact force. 14 . The composition of claim 13 , wherein the layer is a rigid and external helmet shell. 15 . The composition of claim 13 , wherein the layer is metallic armor. 16 . The composition of claim 13 , wherein the layer is part of vehicular interior trim. 17 . The composition of claim 13 , wherein the layer further comprises a biological member comprising: (a) a tendon, (b) a muscle, (c) a tissue, (d) an organ, or (e) a bone, attached to the hydrogel by adhesive, a suture or staple, the liquid entering the particles in an impact situation. 18 . The composition of claim 13 wherein: the particles are an additive intermixed with the hydrogel; the particles serve as cross-linkers by interacting with polymeric chains of the hydrogel so as to strengthen the hydrogel polymer chains; and the particles include nanopores sized to increase an energy absorption capacity and toughness of the hydrogel. 19 . A method of manufacturing an energy absorbing system, the method comprising: (a) applying a hydrophobic material onto nanoporous particles, each of the nanoporous particles having a cross-sectional dimension of 3-100 microns; (b) placing the nanoporous particles in contact with a hydrogel; (c) deterring liquid from entering at least a majority of nanopores of the nanoporous particles in an ambient condition, each of the majority of the nanopores having a linear opening dimension of 2-400 nm; and (d) attaching the hydrogel to a surface made of a material different from the hydrogel. 20 . The method of claim 19 , further comprising pouring the hydrogel in a liquid state against the surface, which is rigid, the surface serving as a mold section to define a shape of the hydrogel after curing. 21 . The method of claim 19 , further comprising selecting the nanoporous particles of a desired shape and nanopore size to allow the liquid of the hydrogel to enter the majority of the nanopores when an impact force is present against the surface. 22 . The method of claim 19 , further comprising sandwiching the nanoporous particles between sub-layers of the hydrogel. 23 . The method of claim 19 , further comprising customizing a composition of the nanoporous particles and the hydrogel by varying at least one characteristic of the composition during its manufacture to vary a threshold where the liquid can enter the majority of the nanopores.