Processes and systems for monitoring one or more gases dissolved in a liquid

1 . A process for sensing a gas dissolved in a liquid, comprising: introducing a fluid into an inlet of a sample cell, wherein the fluid comprises at least one gas dissolved in a liquid; flowing the fluid through the sample cell, wherein at least a portion of the fluid flows past an optical window such that the fluid is viewable within the sample cell through the optical window; recovering the fluid from an outlet of the sample cell; emitting an electromagnetic radiation signal into the sample cell through the optical window for at least a portion of the time the fluid is viewable through the optical window; contacting the fluid with the electromagnetic radiation signal within the sample cell; directing a scattered electromagnetic radiation signal comprising elastic scattered radiation and inelastic scattered radiation emitted from the sample cell through the optical window into a filter to remove at least a portion of the elastic scattered radiation to produce a primarily inelastic scattered radiation signal; and directing the primarily inelastic scatted radiation signal to a detector to detect a Raman signal indicating the presence of the at least one gas dissolved in the liquid. 2 . (canceled) 3 . The process of claim 1 , wherein a wavelength of the electromagnetic radiation signal is in the visible spectrum having a wavelength of about 400 nm to ≤700 nm, in the near infrared spectrum having a wavelength of >700 nm to about 1,400 nm, or in the near ultraviolet spectrum having a wavelength of about 300 nm to <400 nm. 4 . The process of any of claim 1 , wherein the filter comprises a notch filter, an edge pass filter, a band pass filter, or a combination thereof. 5 . The process any of claim 1 , further comprising directing the primarily inelastic scattered radiation signal through a grating to separate the primarily inelastic scattered radiation signal into discrete monochromatic signals, such that the discrete monochromatic signals are directed to the detector. 6 . The process of claim 5 , wherein the grating comprises about 300 grooves to about 3,600 grooves per mm. 7 . The process of any of claim 1 , further comprising passing the electromagnetic radiation signal through an optical assembly prior to emitting the electromagnetic radiation signal into the sample cell through the optical window. 8 . (canceled) 9 . (canceled) 10 . The process of any of claim 1 , wherein the fluid is at a pressure of about 14.7 psi-absolute to about 2,000 psi-absolute. 11 . The process of any of claim 1 , wherein the fluid is at a pressure of ≥14.7 psi-absolute, ≥50 psi-absolute, ≥100 psi-absolute, ≥200 psi-absolute, ≥300 psi-absolute, ≥400 psi-absolute, ≥435 psi, ≥510 psi, ≥660 psi, ≥850 psi, ≥1,000 psi, or ≥1,100 psi. 12 . The process of any of claim 1 , wherein the fluid is introduced into the inlet and recovered from the outlet of the sample cell on a continuous basis. 13 . The process of claim 12 , wherein the electromagnetic radiation signal is emitted into the sample cell through the optical window on a continuous basis, such that the primarily inelastic scatted radiation signal is directed to the detector to detect the Raman signal indicating the presence of the at least one dissolved gas in the liquid on a continuous basis. 14 . The process of claim 12 , wherein the electromagnetic radiation signal is emitted into the sample cell on a periodic basis, such that the primarily inelastic scattered radiation signal is directed to the detector to detect the Raman signal indicated the presence of the at least one dissolved gas in the liquid on a periodic basis. 15 . The process of any of claim 1 , wherein the at lease one gas dissolved in the liquid comprises CO 2 , CH 4 , H 2 S, N 2 , or any mixture thereof. 16 . The process of any of claim 1 , wherein the liquid comprises water or a hydrocarbon oil. 17 . The process of any of claim 1 , wherein the optical window comprises Al 2 O 3 , SiO 2 , or MgF 2 . 18 . (canceled) 19 . (canceled) 20 . (canceled) 21 . (canceled) 22 . The process of any of claim 1 , further comprising: obtaining a hydrocarbon production fluid from a hydrocarbon well, wherein the fluid comprises the hydrocarbon production fluid. 23 . The process of any of claim 1 , further comprising: obtaining a hydrocarbon production fluid from a hydrocarbon well; introducing the hydrocarbon production fluid into a gas/liquid separator to produce a gas phase product and a liquid phase product; and introducing the liquid phase product into an oil/water separator to produce a hydrocarbon product and an aqueous product, wherein the fluid comprises the aqueous product. 24 . The process of any of claim 1 , further comprising sensing the presence of at least one second gas dissolved in the liquid with a transmission infrared measurement system. 25 . The process of claim 24 , wherein the presence of the at least one second gas sensed with the transmission infrared measurement system comprises CO 2 , CH 4 , H 2 S, or any mixture thereof. 26 . A process for calibrating a Raman system, comprising: preparing a mixture comprising water and at least one gas at a pressure of about 14.7 psi-absolute to about 2,000 psi-absolute, wherein the at least one gas is dissolved in the water, and wherein the mixture is at thermodynamic equilibrium; flowing the mixture through a flowline and into an inlet of a sample cell, wherein degassing in the flowline is substantially avoided by increasing the pressure by at least 1 psi-absolute above the pressure the mixture of water and the at least one gas was prepared; flowing the mixture through the sample cell, wherein at least a portion of the mixture flows past an optical window such that the mixture is viewable within the sample cell through the optical window; recovering the mixture from an outlet of the sample cell; emitting an electromagnetic radiation signal into the sample cell through the optical window for at least a portion of the time the mixture is viewable through the optical window; contacting the mixture with the electromagnetic radiation signal within the sample cell; directing a scattered electromagnetic radiation signal comprising elastic scattered radiation and inelastic scattered radiation emitted from the sample cell through the optical window into a filter to remove at least a portion of the elastic scattered radiation to produce a primarily inelastic scattered radiation signal; directing the primarily inelastic scatted radiation signal to a detector to detect a Raman signal indicating the presence of the at least one gas dissolved in the liquid; and correlating the Raman signal to a dissolved concentration of the at least one gas with a thermodynamic model for the mixture of water and the at least one gas. 27 . The process of claim 26 , wherein the at least one gas comprises CO 2 , CH 4 , H 2 S, N 2 , or any mixture thereof. 28 . (canceled) 29 . The process of any of claim 26 , wherein the mixture consists essentially of water and the at least one gas. 30 . The process of any of claim 26 , wherein degassing in the flowline is substantially avoided by increasing the pressure by at least 3 psi-absolute, at least 5 psi-absolute, at least 10 psi-absolute, at least 15 psi-absolute, at least 20 psi-absolute, or at least 25 psi-absolut