Fountain solution thickness identification via gloss measurement system and method

What is claimed is: 1. A method of controlling fountain solution thickness on an imaging member surface of a rotating imaging member in an image forming device, comprising: (a) applying a fountain solution fluid layer at a dispense rate via vapor deposition onto the imaging member surface, the imaging member surface being a reimageable ink transfer member surface having carbon black therein to absorb laser light, the fountain solution fluid layer having a surface above the imaging member surface and a thickness maximum of 100 nm; (b) measuring gloss of the fountain solution fluid layer surface while the fountain solution layer is steadily decreasing in thickness from at most 100 nm over time due to evaporation thereof on the imaging member surface as a gloss value with a gloss meter spatially separate from the imaging member surface, the measuring including projecting an incident light having a wavelength onto the fountain solution fluid layer surface at an angle offset from the surface perpendicular, and measuring reflection of the incident light as reflected light by the gloss meter at an equal but opposite angle to the surface perpendicular, wherein a difference between the angle and the opposite angle is 85°, the measuring including determining the fountain solution layer thickness by correlating gloss measurements of the fountain solution layer steadily decreasing in thickness using a slope change of measured gloss to fountain solution thickness, wherein a gloss decrease down from 90 GU corresponds to a fountain solution thickness of 4.6 μm minus about 140 nm per GU; (b′) appying ink onto the continuous decreasing fountain solution layer after the measuring; (c) modifying the fountain solution dispense rate based on the measured gloss value; and (d) applying a subsequent fountain solution fluid layer at the modified fountain solution dispense rate onto the imaging member surface. 2. The method of claim 1 , further comprising, after Step (b), comparing the measured gloss value to a target gloss value, and Step (c) includes modifying the fountain solution dispense rate based on the comparison between the measured gloss value and the target gloss value. 3. The method of claim 1 , further comprising, after Step (b), estimating a thickness of the applied fountain solution fluid layer based on the measured gloss value, and Step (c) includes modifying the fountain solution dispense rate based on the estimated thickness of the applied fountain solution fluid layer. 4. The method of claim 3 , further comprising comparing the estimated thickness of the applied fountain solution fluid layer with a target thickness, and Step (c) further includes modifying the fountain solution dispense rate based on the comparison between the estimated thickness of the applied fountain solution fluid layer and the target thickness. 5. The method of claim 1 , wherein the wavelength is in the visible spectrum. 6. The method of claim 1 , further comprising, after Step (a), vaporizing in an image wise fashion a portion of the fountain solution fluid layer to form a latent image, applying ink onto the latent image over the imaging member surface to form an ink image, and transferring the ink image from the imaging member surface to a print substrate. 7. The method of claim 6 , further comprising, after Step (d), vaporizing in an image wise fashion a portion of the subsequent fountain solution fluid layer to form a subsequent latent image, applying ink onto the subsequent latent image over the imaging member surface to form a subsequent ink image, and transferring the subsequent ink image from the imaging member surface to the print substrate. 8. A method of controlling fountain solution thickness on an imaging member surface of a rotating imaging member in an image forming device, the image forming device printing a current image onto a print substrate, the printing including applying a fountain solution fluid layer via vapor deposition at a dispense rate onto the imaging member surface, the imaging member surface being a reimageable ink transfer member surface having carbon black therein to absorb laser light, the fountain solution fluid layer having a surface above the imaging member surface and thickness maximum of 100 nm, vaporizing in an image wise fashion a portion of the fountain solution fluid layer to form a latent image, applying ink onto the latent image over the imaging member surface, and transferring the applied ink from the imaging member surface to the print substrate, the method comprising: a) measuring a specular reflection of the fountain solution fluid layer surface while the fountain solution layer is steadily decreasing in thickness from at most 100 nm over time due to evaporation thereof on the imaging member surface as a gloss value with a gloss meter spatially separate from the imaging member surface, the measuring including projecting an incident light having a wavelength onto the fountain solution fluid layer surface at an angle offset from the surface perpendicular, and measuring reflection of the incident light as reflected light by the gloss meter at an equal but opposite angle to the surface perpendicular, wherein a difference between the angle and the opposite angle is 85°, the measuring including determining the fountain solution layer thickness by correlating gloss measurements of the fountain solution aver steadily decreasing in thickness using a slope change of measured gloss to fountain solution thickness, wherein a gloss decrease down from 90 GU corresponds to a fountain solution thickness of 4.6 μm minus about 140 nm GU, the measuring of Step a) occurring before applying ink onto the latent image over the imaging member surface; b) modifying the fountain solution dispense rate based on the measured gloss value; and c) printing a subsequent image by the image forming device using the modified fountain solution dispense rate. 9. The method of claim 8 , further comprising, after Step (a), comparing the measured gloss value to a target gloss value, and Step (b) includes modifying the fountain solution dispense rate based on the comparison between the measured gloss value and the target gloss value. 10. The method of claim 8 , further comprising, after Step (a), estimating a thickness of the applied fountain solution fluid layer based on the measured gloss value, and Step (b) includes modifying the fountain solution dispense rate based on the estimated thickness of the applied fountain solution fluid layer. 11. The method of claim 10 , further comprising comparing the estimated thickness of the applied fountain solution fluid layer with a target thickness, and Step (b) further includes modifying the fountain solution dispense rate based on the comparison between the estimated thickness of the applied fountain solution fluid layer and the target thickness. 12. An image forming device controlling fountain solution thickness on an imaging member surface of a rotating imaging member, comprising: the imaging member surface being a reimageable ink transfer member surface having carbon black therein to absorb laser light; a fountain solution applicator configured to apply a fountain solution fluid layer via vapor deposition at a dispense rate onto the imaging member surface for a printing, the fountain solution fluid layer having a surface above the imaging member surface and a thickness maximum of 100 nm; a gloss meter spatially separate from the imaging member surface forming a gap therebetween, the gloss meter located between the fountain solution applicator and an inking member and configured to measure a specular reflection of the fountain solution fluid layer surface while the founta