Physically operable and mechanically reconfigurable light sources

What is claimed is: 1. A physically operable optofluidic light-source, comprising: a substrate layer; and an active layer comprising: a channel configured to comprise a first fluid comprising a gain medium for a light source; and a flexible layer comprising a trap defining an active region of the light source and configured to confine a predetermined volume of the first fluid; wherein the flexible layer is configured to deform and to thereby move the trap between a first position and a second position, wherein: when the trap is in the first position, in which the trap is configured to form a seal against a wall of the channel such that the first fluid may not flow into or out of the trap, the light source is activated, and when the trap is in the second position, in which the trap is configured to allow the first fluid to flow into and out of an opening on one side of the trap, the light source is deactivated. 2. The optofluidic light-source of claim 1 , wherein the light source is a laser light source and wherein, when the trap is in the first position, the laser light source is activated. 3. The optofluidic light-source of claim 2 , wherein the trap comprises one or more mirrors configured to define a cavity of the active region of the laser light source. 4. The optofluidic light-source of claim 2 , wherein the trap comprises one or more distributed Bragg reflectors configured to cause the laser light source to operate as a distributed Bragg reflector laser. 5. The optofluidic light-source of claim 1 , comprising a chamber configured to be pressurized or depressurized with a fluid to cause the flexible layer to deform. 6. The optofluidic light-source of claim 1 , wherein the first fluid has a refractive index of greater than or equal to 1.0 and less than or equal to 2.25. 7. The optofluidic light-source of claim 1 , wherein the substrate layer has a refractive index of greater than or equal to 1.3 and less than or equal 4. 8. The optofluidic light-source of claim 1 , wherein the trap has a refractive index of greater than or equal to 1.2 and less than or equal to 1.6. 9. The optofluidic light-source of claim 1 , wherein the light source is configured to output light in a first direction parallel to a plane defined by the substrate layer. 10. The optofluidic light-source of claim 1 , comprising an analyte channel configured to contain an analyte in a position such that the analyte is illuminated by the light source. 11. The optofluidic light-source of claim 10 , wherein light from the light source is directed to the analyte channel by one or more waveguides. 12. The optofluidic light-source of claim 1 , wherein the active region of the light source is configured to be pumped by illumination incident on the active region at an angle to the active layer. 13. The optofluidic light-source of claim 1 , wherein the active region of the light source is configured to be pumped by illumination incident on the active region from within the active layer. 14. The optofluidic light source of claim 1 , wherein the optofluidic light source is configured to evacuate the first fluid in the channel and in the trap and to replace it with a second fluid having a different index of refraction, such that the light source generates output light at a first wavelength when using the first fluid and at a second wavelength when using the second fluid with a same pump source. 15. The optofluidic light-source of claim 1 , wherein the trap comprises one or more gratings configured to cause the light source to operate as a distributed feedback laser. 16. The optofluidic light-source of claim 15 , wherein the trap is configured to deform and to thereby adjust a period of the one or more gratings and to thereby adjust a wavelength of output laser light of the distributed feedback laser. 17. The optofluidic light-source of claim 1 , wherein the trap comprises an annular shape configured to create a ring resonator. 18. The optofluidic light-source of claim 1 , wherein the predetermined volume of the first fluid is greater than or equal to 100 fL and less than or equal to 10 nL. 19. The optofluidic light-source of claim 1 , wherein a distance between the first position and the second position is greater than or equal to 0.1 μm and less than or equal to 1 mm. 20. The optofluidic light-source of claim 1 , wherein the active layer is disposed on a chip comprising one or more of: one or more analyte channels, one or more pump light sources, one or more sample preparation components, or one or more detectors. 21. A physically operable light-source, comprising: a substrate layer; an active layer that is flexible and configured to deform comprising a solid-core optical component comprising a gain medium for a laser light source, wherein the solid-core optical component comprises an active region of the laser light source; and a chamber formed from an upper layer of the laser light source, the chamber configured to be pressurized or depressurized with a gas to cause the active layer to deform; wherein the active layer is configured to deform from a first position to a second position, wherein: when the active layer is in the first position, the laser light source is activated, and when the active layer is in the second position, the laser light source is deactivated. 22. The physically operable light-source of claim 21 , wherein the active layer deforming between the first position and the second position causes the solid-core optical component to selectably move from a first component position at which the laser light source is activated to a second component position at which the laser light source is deactivated. 23. The physically operable light-source of claim 22 , wherein the active layer deforming between the first position and the second position causes the solid-core optical component to selectably deform from a state at which the laser light source is activated to a second state at which the laser light source is deactivated. 24. The physically operable light-source of claim 23 , wherein a distance between the first component position and the second component position is greater than or equal to 0.1 μm and less than or equal to 1 mm. 25. The physically operable light-source of claim 21 , wherein the solid-core optical component has a refractive index greater than or equal to 1.3 and less than or equal to 1.8. 26. The physically operable light-source of claim 21 , wherein the solid-core optical component has a refractive index greater than or equal to a refractive index of one or more adjacent layers. 27. The physically operable light-source of claim 21 , wherein the substrate layer has a refractive index that is less than a refractive index of the solid-core optical component. 28. The physically operable light-source of claim 21 , wherein the light source is configured to output light in a first direction parallel to a plane defined by the substrate layer. 29. The physically operable light-source of claim 21 , comprising an analyte channel configured to contain an analyte in a position such that the analyte is illuminated by the light source. 30. The physically operable light-source of claim 29 , wherein light from the light source is directed to the analyte channel by one or more waveguides. 31. The physically operable l