Wide-field imaging using nitrogen vacancies

The invention claimed is: 1. A method of imaging at least one of an electric field, magnetic field, temperature, pressure, or strain applied to a color center, the method comprising: (A) applying a magnetic field from a microwave source to the color center so as to manipulate an electron spin state of the color center; (B) irradiating the color center with an optical pulse from a light source so as to excite the color center from a first energy level to a second energy level and to induce emission of fluorescence from the color center, the fluorescence representative of the at least one of the electric field, magnetic field, temperature, pressure, or strain applied to the color center; and (C) imaging, with a wide-field imaging system, the fluorescence emitted by the color center onto a detector array, wherein (C) comprises irradiating the color center with another optical pulse from the light source within a relaxation time associated with the second energy level. 2. The method of claim 1 , further comprising, before (A): disposing the color center on a surface of an inorganic material; and exposing the inorganic material to the at least one of the electric field, magnetic field, temperature, pressure, or strain. 3. The method of claim 1 , wherein the color center is disposed within a nanodiamond, and further comprising, before (A): functionalizing a surface of the nanodiamond; and disposing the nanodiamond within organic tissue. 4. The method of claim 1 , wherein (A) comprises applying a plurality of microwave pulses to the color center in an absence of any other magnetic field. 5. The method of claim 1 , wherein: the color center has a first orientation with respect to the magnetic field, and (A) further comprises manipulating an electron spin state of another color center, the other color center having a second orientation different than the first orientation with respect to the magnetic field. 6. The method of claim 1 , wherein (C) comprises imaging fluorescence emitted by a plurality of color centers onto the detector array with the wide-field imaging system. 7. A system for imaging at least one of an electric field, magnetic field, temperature, pressure, or strain applied to a color center, the system comprising: a light source, in optical communication with the color center, to irradiate the first color center with an optical pulse so as to excite the color center from a first energy level to a second energy level and to induce emission of fluorescence from the color center, the fluorescence representative of the at least one of the electric field, magnetic field, temperature, pressure, or strain applied to the first color center; a microwave source, in electromagnetic communication with the color center, to apply a magnetic field to the color center so as to manipulate an electron spin state of the first color center; and a wide-field imaging system, in optical communication with the color center, to image the fluorescence emitted by the color center onto a detector array, wherein the microwave source is configured to apply the magnetic field at a first orientation with respect to the color center and at a second orientation with respect to another color center so as to manipulate the electron spin state of the color center and the electron spin state of the other color center. 8. A system for imaging at least one of an electric field, magnetic field, temperature, pressure, or strain applied to a plurality of color centers, the system comprising: a light source, in optical communication with the plurality of color centers, to irradiate the plurality of color centers with an optical pulse so as to excite the plurality of color centers from a first energy level to a second energy level and to induce emission of fluorescence from the plurality of color centers, the fluorescence representative of the at least one of the electric field, magnetic field, temperature, pressure, or strain applied to the plurality of color centers; a microwave source, in electromagnetic communication with the plurality of color centers, to apply a magnetic field to the plurality of color centers so as to manipulate an electron spin state of the plurality of color centers; and a wide-field imaging system, in optical communication with the plurality of color centers, to image the fluorescence emitted by the plurality of color centers onto a detector array, wherein the light source is configured to irradiate the plurality of color centers with another optical pulse within a relaxation time associated with the second energy level. 9. The system of claim 8 , wherein the color center comprises a nitrogen vacancy. 10. The system of claim 8 , wherein the color center is disposed on a surface of an inorganic material exposed to the at least one of the electric field, magnetic field, temperature, pressure, or strain applied to the color center. 11. The system of claim 8 , wherein the color center is disposed within organic tissue exposed to the at least one of the electric field, magnetic field, temperature, pressure, or strain applied to the color center. 12. The system of claim 8 , wherein the light source is configured to emit the optical pulse at a wavelength of about 532 nm. 13. The system of claim 8 , wherein the microwave source is configured to apply a plurality of microwave pulses to the color center in an absence of any other magnetic field. 14. The system of claim 8 , wherein the wide-field imaging system is configured to image fluorescence emitted by the color center onto the detector array. 15. A system for imaging at least one of an electric field, magnetic field, temperature, pressure, or strain applied to the color center applied to a nanodiamond, the system comprising: a laser, in optical communication with the nanodiamond, to illuminate the nanodiamond with an optical pulse so as to simultaneously to induce emission of fluorescence from a nitrogen vacancy in the nanodiamond and to excite the nitrogen vacancy in the nanodiamond from a first energy level to a second energy level; a wide-field imaging system, in optical communication with the nanodiamond, to image the fluorescence emitted by the nitrogen vacancy to a point in an image plane; and a detector array, disposed within the image plane, to sense the fluorescence emitted by the nitrogen vacancy, wherein the laser is configured to illuminate the nanodiamond with another optical pulse within a relaxation time of the second energy level. 16. The system of claim 15 , wherein the wide-field imaging system is configured to image fluorescence emitted by another nitrogen vacancy to the image plane. 17. The system of claim 15 , further comprising: a microwave source, in electromagnetic communication with the nanodiamond, to apply at least one microwave pulse to the nitrogen vacancy so as to manipulate an electron spin state of the first nitrogen vacancy. 18. A method of imaging at least one of an electric field, temperature, pressure, or strain applied to a color center, the method comprising: (A) applying a plurality of microwave pulses from a microwave source to the color center in an absence of a magnetic field so as to manipulate an electron spin state of the color center; (B) irradiating the color center with an optical pulse from a light source so as to excite the color center from a first energy level to a second energy level and to induce emission of fluorescence from the color center, the fluorescence representative of the at least one of the electric field, temperature, pressure, or str