pH photothermal spectrometer and performing pH photothermal spectroscopy

What is claimed is: 1. A pH photothermal spectrometer for performing pH photothermal spectroscopy, the pH photothermal spectrometer comprising: a container comprising an interior bounded by a wall of the container, such that container: receives an analyte medium and a pH-sensitive chromophore, the pH-sensitive chromophore comprises an optical absorption spectrum that adjusts to a pH of the analyte medium, the analyte medium comprising an analyte temperature; and optionally receives a fiber encapsulation matrix in which are disposed the analyte medium and the pH-sensitive chromophore; an excitation fiber disposed in the container in optical communication with the pH-sensitive chromophore and that: receives a first excitation light comprising a first wavelength and a second excitation light comprising a second wavelength; and communicates the first excitation light and the second excitation light to the pH-sensitive chromophore, such that the pH-sensitive chromophore: receives the first excitation light and the second excitation light; and absorbs a first amount of the first excitation light and a second amount of the second excitation light based on the pH of the analyte medium such that absorption of the first excitation light or the second excitation light increases the analyte temperature of the analyte medium; and an optical thermometer disposed in the container and comprising: a temperature detector fiber that receives a probe light comprising a probe light wavelength in a first optical amount; and receives a reflected light comprising the probe light wavelength from a light receiver; and the light receiver: disposed on a terminus of the temperature detector fiber in optical communication with the temperature detector fiber and in thermal communication with the analyte medium; and comprising: a receiver temperature that adjusts to match the analyte temperature; and an optical resonance at a resonance wavelength that changes in response to a change in the receiver temperature, such that the light receiver: receives the probe light from the temperature detector fiber; produces, from the probe light, a reflected light in a second optical amount and comprising the probe light wavelength, such that the second optical amount of the reflected light depends on the receiver temperature of the light receiver, so that a ratio of the first optical amount to the second optical amount provides the pH of the analyte medium; and communicates the reflected light to the temperature detector fiber; and the temperature detector fiber receives the reflected light from the light receiver. 2. The pH photothermal spectrometer of claim 1 , further comprising a fiber port disposed on the container through which is disposed the optical thermometer. 3. The pH photothermal spectrometer of claim 1 , further comprising a fiber port disposed on the container through which is disposed the excitation fiber. 4. The pH photothermal spectrometer of claim 1 , comprises the fiber encapsulation matrix that encapsulates the light receiver, the excitation fiber, or a combination comprising at least one of the light receiver and the excitation fiber. 5. The pH photothermal spectrometer of claim 1 , wherein the fiber encapsulation matrix maintains a position of the excitation fiber and the light receiver in the container. 6. The pH photothermal spectrometer of claim 1 , wherein the fiber encapsulation matrix comprises a gel. 7. The pH photothermal spectrometer of claim 1 , wherein the pH-sensitive chromophore is subject to diffusion in the analyte medium. 8. The pH photothermal spectrometer of claim 1 , wherein the pH-sensitive chromophore is disposed in the fiber encapsulation matrix via entropic trapping, covalent bond attachment, or electrostatic trapping. 9. The pH photothermal spectrometer of claim 1 , wherein the light receiver comprises a fiber Bragg grating, an on-chip thermometer, a Raman fiber optic thermometer, a Brillouin fiber optic thermometer), or a fluorescent particle. 10. The pH photothermal spectrometer of claim 1 , wherein the light receiver is the fluorescent particle that comprises a nitrogen vacancy diamond. 11. The pH photothermal spectrometer of claim 1 , wherein the analyte medium comprises a cell medium. 12. The pH photothermal spectrometer of claim 1 , further comprising an excitation light source in optical communication with the excitation fiber and that provides the first excitation light to the excitation fiber. 13. The pH photothermal spectrometer of claim 1 , further comprising a probe light source in optical communication with the temperature detector fiber and that provides the probe light to the temperature detector fiber. 14. The pH photothermal spectrometer of claim 1 , further comprising a detector in optical communication with the temperature detector fiber and that receives the reflected light from the optical thermometer. 15. The pH photothermal spectrometer of claim 1 , wherein the temperature detector fiber extends into and out of the interior of the container in a plurality of locations of the wall of the container. 16. The pH photothermal spectrometer of claim 1 , wherein the excitation fiber is disposed orthogonal to the optical thermometer in the container, parallel to the optical thermometer in the container, or at an oblique angle with respect to the optical thermometer. 17. The pH photothermal spectrometer of claim 1 , wherein the excitation fiber comprises an optical taper disposed at a terminus of the excitation fiber proximate to the light receiver. 18. A process for performing pH photothermal spectroscopy with the pH photothermal spectrometer of claim 1 , the process comprising: receiving, by the excitation fiber, the first excitation light that comprises the first wavelength and the second excitation light that comprises the second wavelength; contacting the pH-sensitive chromophore with the analyte medium; adjusting the optical absorption spectrum of the pH-sensitive chromophore in response to the pH of the analyte medium; communicating the first excitation light and the second excitation light from the excitation fiber to the pH-sensitive chromophore; receiving, by the pH-sensitive chromophore, the first excitation light and the second excitation light; absorbing, by the pH-sensitive chromophore, the first amount of the first excitation light based on the pH of the analyte medium; absorbing, by the pH-sensitive chromophore, the second amount of the second excitation light based on pH of the analyte medium; adjusting the analyte temperature of the analyte medium in response to the pH-sensitive chromophore absorbing the first excitation light and the second excitation light; adjusting the receiver temperature of the light receiver to match the analyte temperature of the analyte medium in response to adjusting the analyte temperature of the analyte medium; receiving, by the light receiver, the probe light in the first optical amount from the temperature detector fiber; producing, by the light receiver from the probe light, the reflected light in the second optical amount that depends on the receiver temperature of the light receiver, the reflected light comprising the probe light wavelength; and determining the pH of the analyte medium from a ratio of the first optical amount to the second optical amount to perform pH photothermal spectroscopy. 19. The process of claim 18 , further comprising: communicating, from the light receiver, the reflected light to the temperature