Claims
- 1. A nanopump comprising of:
(a) a source of radiation energy; and (b) at least one waveguide connected on one side with of said source of radiation; and (c) at least one transmitter connected with at least one of said waveguide on the other side of said waveguide.
- 2. A nanopump of claim 1, wherein said transmitter has at least one thermal resistant tip transparent for the beamed radiation and is connected with at least one of said waveguide on the of said the other side of said waveguide.
- 3. A nanopump of claim 1, wherein said a source of radiation energy is a laser.
- 4. A nanopump of claim 2, wherein said transmitter has at least one thermal resistant and thermal conductive layer having good absorption properties for the radiation energy and connected on one side with thermal resistant tip and on the other side with the medium.
- 5. A nanopump of claim 2, wherein said transmitter has at least one heat pipe having good absorption properties for the radiation energy and connected on one side with the thermal resistant tip and on the other side with the medium.
- 6. A nanopump of claim 2, wherein said thermal resistant tip has different diameter.
- 7. A nanopump of claim 4, wherein said other side of the transmitter has flat outer surface.
- 8. A nanopump of claim 4, wherein said other side of the transmitter has rough outer surface.
- 9. A nanopump of claim 4, wherein said other side of the transmitter has oval outer surface.
- 10. A nanopump of claim 4, wherein said other side of the transmitter has triangular outer surface.
- 11. A nanopump of claim 3, wherein said transmitter has cross-section adaptable to the form of at least one nano- and/or micro-metric dimensional channel.
- 12. A nanopump of claim 1, wherein said waveguide is a fiber optic.
- 13. A nanopump of claim 1, wherein said waveguide is a vacuum tube sealed by aluminum foil.
- 14. A nanopump of claim 1, further comprising a plurality of waveguides, wherein each of said transmitter is connected with at least one of said waveguide.
- 15. A nanopump of claim 12, wherein said a plurality of waveguides is assembled in a bundle.
- 16. A nanopump of claim 14, wherein said transmitters have common oval outer surface.
- 17. A nanopump of claim 14, wherein said transmitters have common triangular outer surface.
- 18. A nanopump of claim 14, wherein said transmitters have cross-section adaptable to the form of at least one nano- and/or micro-metric dimensional channel.
- 19. A nanopump of claims 11, further comprising of a plurality of nano- and/or micro-metric dimensional channels.
- 20. A nanopump of claim 19, wherein said nano- and/or micro-metric dimensional channels are arranged in a micro fluidic array.
- 21. A system for positioning, selection, separation and treatment of nano- and/or micro-objects, comprising of:
(a) at least one nanopump; and (b) a plurality of sources of the radiation energy that has at least one different range of wavelengths; and (c) at least one microscope. (d) plurality of waveguides.
- 22. A system of claim 21, wherein said different range of wavelengths is an x-ray portion of the spectrum.
- 23. A system of claim 21, wherein said different range of wavelengths is a microwave portion of the spectrum.
- 24. A system of claim 21, wherein said plurality of waveguides transmit of said radiation energy with a different range of wavelengths from said plurality of sources to the medium.
- 25. A system of claim 21, wherein said plurality of waveguides transmit of said radiation with a different range of wavelengths from said medium to at least one of said microscope.
- 26. A system of claim 21, wherein said microscope is a near field optic microscope.
- 27. A system of claim 24, wherein said a medium is liquid with nanoparticles and/or nanoparticle structures.
- 28. A system of claim 24, wherein said a medium is liquid with at least one biological agent.
- 29. A system of claim 28, further comprising of at least one biological agent that is associated with said nanoparticles and/or nanoparticle structures.
- 30. A system for heating up, overheating and/or melting of nano- and/or micro-objects, comprising of:
(a) at least one nanopump; (b) plurality of the heat pipes, wherein said plurality of heat pipes is connected with at least one of said nanopump: (c) plurality of nano- and/or micro-metric dimensional devices, wherein each of said plurality of nano- and/or micro-metric dimensional devices is connected with at least one of said heat pipes.
- 31. A system of no-moving parts valve of claim 30, wherein gap of liquid size nano- or micro-meter exists between the said plurality of heat pipes and of said nanopump.
- 32. A method for conversion the radiation energy into thermal energy using of said nanopump, comprising the steps of:
(a) illuminating the transmitter with the incident radiation, from a source of the radiation energy of said nanopump; and (b) conversion of the radiation energy into the thermal energy using of said transmitter.
- 33. A method of claim 32, further comprising of transferring of said thermal energy from said transmitter to the medium.
- 34. A method of claim 33, further comprising of overheating of said medium using of said thermal energy in a close proximity to the transmitter and generating directed pumping force and motion of said medium in a close proximity to the transmitter and delivering of this motion to another parts of said medium for pumping of said medium.
- 35. A method of claim 34, further comprising of the surface to be cleaned and treated by said pumped medium.
- 36. A method of claim 35, further comprising of a chemical aggressive liquid added to the said medium.
- 37. A method of claim 33, further comprising of the heated up, overheated and/or melted said medium using the heat pipe, wherein of said heat pipe is connected with at least one of said transmitter.
- 38. A method of claim 34, further comprising of a near field optic microscope, and at least one of said waveguide, wherein said waveguide is connected with said near field optic microscope for positioning, selection, separation and treatment of nano- and/or micro-objects in said liquid medium.
CROSS REFERENCE TO RELATED APPLICATION
[0001] This application claims the benefit of U.S. Provisional Application, titled “Nanopump”, inventor Oleg A. Yevin, No. 60/307,746, filed Jul. 25, 2001.
Provisional Applications (1)
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Number |
Date |
Country |
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60307746 |
Jul 2001 |
US |