Reversing coffee-ring effect by laser-induced differential evaporation

What is claimed is: 1. A microdroplet evaporation apparatus, comprising: a light source; a substrate to hold a microdroplet at a location; and a focusing module structured to cause an evaporative flux at an apex of the microdroplet that is greater than another evaporative flux at an edge of the microdroplet, wherein the focusing module focuses the light source on the microdroplet. 2. The microdroplet evaporation apparatus of claim 1 , wherein the focusing module causes illumination by the light source of a plurality of locations including the location at the same time or nearly the same time. 3. The microdroplet evaporation apparatus of claim 1 , further comprising: an x-y mechanical translation apparatus configured to selectively translate the substrate to one of a plurality of locations with corresponding microdroplets including the location. 4. The microdroplet evaporation apparatus of claim 1 , wherein the microdroplet evaporation apparatus causes a drying of the microdroplet leaving a deposition of solids that were previously dissolved in the microdroplet before the microdroplet was dried. 5. The microdroplet evaporation apparatus of claim 4 , wherein the deposition of solids is uniform or nearly uniform across the dried microdroplet. 6. The microdroplet evaporation apparatus of claim 4 , wherein the deposition of solids is approximately the same size as the microdroplet. 7. The microdroplet evaporation apparatus of claim 4 , wherein the deposition of solids includes deposition of water-soluble molecules including one or more of nucleic acids, proteins, inks, and other small molecules. 8. The microdroplet evaporation apparatus of claim 1 , wherein the light source is a laser. 9. The microdroplet evaporation apparatus of claim 1 , wherein the laser is a CO 2 laser. 10. The microdroplet evaporation apparatus of claim 9 , wherein the beam waist of the CO 2 laser is approximately 25-35 microns. 11. The microdroplet evaporation apparatus of claim 9 , wherein a beam of the CO 2 laser is focused on the apex of the microdroplet to generate a differential evaporation. 12. The microdroplet evaporation apparatus of claim 11 , wherein a differential evaporative flux profile has a maximum at the apex of the microdroplet. 13. The microdroplet evaporation apparatus of claim 12 , wherein the beam focused at the apex of the microdroplet causes a uniform or nearly uniform deposition of solids when the microdroplet is dried. 14. The microdroplet evaporation apparatus of claim 1 , wherein the microdroplet is an aqueous solution droplet with a droplet diameter of between 100 μm and 1.5 mm. 15. The microdroplet evaporation apparatus of claim 1 , wherein a well approximately 100 μm in diameter is positioned at the location. 16. The microdroplet evaporation apparatus of claim 1 , wherein the microdroplet has a volume between 1-10 microliters. 17. A method of evaporating a microdroplet, comprising: holding, by a substrate, a microdroplet at a location; illuminating, by a light source, the microdroplet; and causing an evaporative flux at an apex of the microdroplet that is greater than another evaporative flux at an edge of the microdroplet, wherein the focusing module focuses the light source on the microdroplet. 18. The method of evaporating a microdroplet of claim 17 , wherein the drying of the microdroplet leaves a deposition of solids that were previously dissolved in the microdroplet before the microdroplet was dried. 19. The method of evaporating a microdroplet of claim 18 , wherein the deposition of solids is uniform or nearly uniform across the dried microdroplet. 20. The method of evaporating a microdroplet of claim 18 , wherein the deposition of solids includes deposition of water-soluble molecules including one or more of nucleic acids, proteins, inks, and other small molecules.