Light-mediated manipulation of droplets stabilized by fluorinated nanoparticles with photothermal effect

We claim: 1. Fluorinated metal nanoparticles (f-MNPs) stabilized aqueous droplets comprising f-MNPs, the f-MNPs comprising: a plurality of metal nanoparticles or semiconductor nanoparticles having size greater than 20 nm in cross-section, each of the nanoparticles being coated with fluorinated alkyl ligands that make the surface of the nanoparticles fluorophilic, wherein the f-MNPs function as surfactants for stabilizing aqueous droplets containing an aqueous core, wherein the f-MNPs stabilized aqueous droplets are suspended in a fluorinated solvent, wherein the diameter of the stabilized droplets ranges from 5 μm to 500 μm, and wherein the droplets contain at least one biomolecule and chemical reagent. 2. The f-MNPs stabilized aqueous droplets according to claim 1 , wherein the metal of the plurality of metal nanoparticles is selected from the group consisting of gold, silver, platinum, nickel, palladium, cobalt, rhodium, rhenium, titanium, zinc, cerium, iron, iridium, and combinations thereof. 3. The f-MNPs stabilized aqueous droplets according to claim 1 , wherein the fluorinated alkyl ligand is perfluoroalkanethiol of 6 to 26 carbons, or perfluoroalkoxysilane mediated by a layer of silica shell. 4. The f-MNPs stabilized aqueous droplets according to claim 1 , wherein the metal is gold and the fluorinated alkyl ligand is 1H, 1H,2H,2H-perfluorodecanethiol. 5. A light-mediated microfluidic device, comprising a plurality of active f-MNPs stabilized aqueous droplets and at least two lasers including an excitation laser and a sorting laser, wherein at least one laser of the at least two lasers is tuned to a plasmon resonance frequency for the f-MNPs, wherein the laser is the sorting laser, wherein laser excitation by the sorting laser enables the merge, movement, splitting, and sorting of f-MNPs stabilized droplets, and, optionally, a feature to mechanically split an isolated active f-MNPs stabilized aqueous droplet, wherein the f-MNPs comprise a plurality of metal nanoparticles or semiconductor nanoparticles having a size greater than 20 nm in cross-section, each of the nanoparticles being coated with fluorinated alkyl ligands that make the surface of the nanoparticles fluorophilic, wherein the f-MNPs function as surfactants for the stabilized aqueous droplets, wherein the f-MNPs stabilized aqueous droplets contain an aqueous core, wherein the f-MNPs stabilized aqueous droplets are suspended in a fluorinated solvent, wherein the diameter of the stabilized droplets ranges from 5 μm to 500 μm, wherein the droplets contain at least one biomolecule and chemical reagent. 6. The light-mediated microfluidic device according to claim 5 , wherein at least a second laser of the at least two lasers is tuned to an excitation frequency of a fluorescent or phosphorescent chemical within the active f-MNPs stabilized aqueous droplet, wherein the second laser is the excitation laser. 7. A method of manipulating an active f-MNPs stabilized aqueous droplet in a light-mediated microfluidic device according to claim 5 , comprising: introducing the plurality of active f-MNPs stabilized aqueous droplets into said light-mediated microfluidic device; irradiating at least one spot in the light-mediated microfluidic device; and promoting stoppage of movement or initiation of movement of one of the plurality of active f-MNPs stabilized aqueous droplets that come in the vicinity or on the focus of the spot; or promoting merging of a contacting pair of the plurality of active f-MNPs stabilized aqueous droplets that come in the vicinity or on the focus of the spot. 8. The method according to claim 7 , wherein a portion of the active f-MNPs stabilized aqueous droplets contains a fluorescent or phosphorescent chemical. 9. The method according to claim 8 , further comprising activating the fluorescent or phosphorescent chemical by irradiating a laser beam at the absorption frequency of the fluorescent or phosphorescent chemical and detecting fluorescence or phosphorescence. 10. The method according to claim 9 , wherein the irradiating of the spot in the light-mediated microfluidic device is controlled by detecting the fluorescence or phosphorescence. 11. The method according to claim 7 , wherein the spot resides adjacent to the feature to mechanically split an isolated active f-MNPs stabilized aqueous droplet such that during irradiating the spot the active f-MNPs stabilized aqueous droplet undergoes splitting into two unequally sized active f-MNPs stabilized aqueous droplets. 12. The method according to claim 7 , wherein at least one spot resides in a junction of at least two downstream microfluidic channels to direct the droplets into one of the downstream channels.