Colloidal suspension of photoluminescent amorphous porous silicon, methods of making colloidal suspension of photoluminescent amorphous porous silicon, and methods of using colloidal suspension of photomimunescent amorphous porous silicon

We claim at least the following: 1. A method of making a colloidal suspension of photoluminescent porous silicon particles, comprising: removing a layer of porous silicon from a substrate using a first ultrasound energy to form a first plurality of porous silicon particles as a colloidal suspension; and exposing the colloidal suspension of the first plurality of porous silicon particles to a second ultrasound energy to reduce the size of the first plurality of porous silicon particles, thereby forming a second plurality of porous silicon particles as a colloidal suspension, wherein the second plurality of porous silicon particles are in the amorphous phase. 2. The method of claim 1 , wherein the second plurality of porous silicon particles have a longest dimension of about 100 nanometers to 10 micrometers. 3. The method of claim 1 , wherein the second plurality of porous silicon particles are irregularly shaped. 4. The method of claim 1 , wherein the second plurality of porous silicon particles are suspended in a solvent selected from the group consisting of: ethanol, toluene, hydrogen peroxide, water, THF, isopropylene, octane, an alkane solvent, and a combination thereof. 5. The method of claim 1 , wherein the second plurality of porous silicon particles is suspended in ethanol and has an emission of about 523 nm just after formation of the suspension. 6. The method of claim 1 , wherein the second plurality of porous silicon particles is suspended in ethanol and has an emission of about 622 nm after about one month. 7. The method of claim 1 , wherein the second plurality of porous silicon particles is suspended in toluene and has an emission of about 598 nm just after formation of the suspension. 8. A method of making a colloidal suspension of photoluminescent porous silicon particles, comprising: removing a layer of porous silicon from a substrate using a first ultrasound energy to form a first plurality of porous silicon particles as a colloidal suspension; and exposing the first plurality of porous silicon particles as the colloidal suspension to a second ultrasound energy to reduce the size of the first plurality of porous silicon particles as the colloidal suspension, thereby forming a second plurality of porous silicon particles as a colloidal suspension, wherein the second plurality of porous silicon particles are in the amorphous phase, wherein the second plurality of porous silicon particles is suspended in hydrogen peroxide and has an emission of about 595 nm to 566 nm. 9. A colloidal suspension of photoluminescent porous silicon particle suspension comprising: a plurality of porous silicon particles in a solvent as a colloidal suspension, and wherein the plurality of porous silicon particles is in the amorphous phase, wherein the plurality of porous silicon particles is suspended in hydrogen peroxide and has an emission of about 595 nm to 566 nm. 10. A colloidal suspension of photoluminescent porous silicon particle suspension comprising: a plurality of porous silicon particles in a solvent as a colloidal suspension, and wherein the plurality of porous silicon particles is in the amorphous phase, wherein the porous silicon particles have a ratio of OH to H on the surface of the colloidal porous silicon particles of about 0:1 to about 1:0. 11. The method of claim 1 , further comprising: tuning an emission wavelength of the second plurality of porous silicon particles as the colloidal suspension by a solvent used in the colloidal suspension, a ratio of OH to H on a surface the second plurality of porous silicon particles by adjusting a concentration of the solvent used in the colloidal suspension, combining two solvents used in the colloidal suspension, modifying a surface of the second plurality of porous silicon particles, or doping of the second plurality of porous silicon particles.