Nanoporous tin powder for energy applications

What is claimed is: 1. An active material for use in an energy storage device, comprising: a population of micrometer sized metal, semi metal or semiconducting particles; wherein the each of the particles comprise a hierarchically porous structure comprising a network of interconnected ligament-shaped structures and pores; said pores being defined by adjacent interconnected ligament-shaped structures; wherein each of said interconnected ligament-shaped structures comprises a granular structure comprising a population of sub-pores; and wherein said hierarchically porous structure is configured to allow for cycling induced volume expansion upon being electrochemically alloyed within the energy storage device. 2. The material of claim 1 , wherein said pores comprise nanopores and wherein said sub-pores comprise mesopores. 3. The material of claim 2 , wherein the mesopores comprise pores approximately 5 nm in size. 4. The material of claim 2 , wherein said particles are composed of a metal or semiconductor selected from the group of metals and semiconductors consisting essentially of Ge, Sb, As, Bi, Si, Sn, SnC, SnSb, SnSi, SnGe, SnAs, SnAl, SnBi, SnCo, SnNi, and SnPb. 5. The material of claim 2 , wherein said particles comprise nanoporous tin. 6. The material of claim 2 , wherein said particles have a diameter between approximately 1-100 μm. 7. The material of claim 2 , wherein the material is configured to be coupled to a charge collector as an electrode. 8. The material of claim 7 , wherein the material is configured to allow for cycling induced volume expansion upon being electrochemically alloyed with LI Na or Mg. 9. An electrode for use with an energy storage device, comprising: (a) a macroporous conductor; (b) an active material configured to be disposed within macropores of the macroporous conductor, the active material comprising: (i) a population of micrometer sized metal, semi metal or semiconducting particles; (ii) wherein the each of the particles comprise a hierarchically porous structure comprising a network of interconnected ligament-shaped structures and pores; (iii) said pores being defined by adjacent interconnected ligament-shaped structures; (iv) wherein each of said interconnected ligament-shaped structures comprises a granular structure comprising a population of sub-pores; and (c) a charge collector electrically coupled with the active material; (d) wherein said hierarchically porous structure is configured to allow for cycling induced volume expansion upon being electrochemically alloyed within the energy storage device. 10. The electrode of claim 9 : wherein said pores comprise nanopores; and wherein said sub-pores comprise mesopores. 11. The electrode of claim 10 , wherein the mesopores comprise pores approximately 5 nm in size. 12. The electrode of claim 10 , wherein said particles are composed of a metal or semiconductor selected from the group of metals and semiconductors consisting essentially of Ge, Sb, As, Bi, Si, Sn, SnC, SnSb, SnSi, SnGe, SnAs, SnAl, SnBi, SnCo, SnNi, and SnPb. 13. The electrode of claim 10 , wherein said particles comprise nanoporous tin. 14. The electrode of claim 10 , wherein said particles have a diameter between approximately 1-100 μm. 15. The electrode of claim 10 , wherein the material is configured to allow for cycling induced volume expansion upon being electrochemically alloyed with LI Na or Mg. 16. The electrode of claim 10 , wherein said macroporous conductor comprises an additive selected from the group of additives consisting essentially of: vapor grown carbon fibers (VGCF), graphite, carbon nanotubes, fullerenes, graphene flakes, carbon black, and conductive polymer nanoparticles. 17. The electrode of claim 10 , further comprising: a binder; wherein said binder comprises a carboxymethyl cellulose (CMC) or, polyacrylic acid or, styrene-butadiene rubber or, polyvinylidene fluoride binder and combinations thereof.