A fluid quality sensor system comprising a light source, a first light sensitive element disposed at a distance from the light source, forming a gap having dimensions suitable for permitting a fluid to flow therebetween, and aligned with the light source to receive light transmitted by the light sou
A fluid quality sensor system comprising a light source, a first light sensitive element disposed at a distance from the light source, forming a gap having dimensions suitable for permitting a fluid to flow therebetween, and aligned with the light source to receive light transmitted by the light source through the fluid, a second light sensitive element disposed perpendicular to a midpoint of a light path between the light source and the first light sensitive element, and a third light sensitive element disposed so as to form an acute angle at the midpoint with the light source.
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A fluid quality sensor system comprising a light source, a first light sensitive element disposed at a distance from the light source, forming a gap having dimensions suitable for permitting a fluid to flow therebetween, and aligned with the light source to receive light transmitted by the light sou
A fluid quality sensor system comprising a light source, a first light sensitive element disposed at a distance from the light source, forming a gap having dimensions suitable for permitting a fluid to flow therebetween, and aligned with the light source to receive light transmitted by the light source through the fluid, a second light sensitive element disposed perpendicular to a midpoint of a light path between the light source and the first light sensitive element, and a third light sensitive element disposed so as to form an acute angle at the midpoint with the light source. sample of the plurality of liquid samples by light-scattering methods that include transmitting light from a light-scattering probe into the first sample, and detecting light scattered from the first sample or a component thereof, translating the plurality of samples or the light-scattering probe relative to each other, and analyzing a second sample of the plurality of liquid samples by light-scattering methods that include transmitting light from the probe into the second sample, and detecting light scattered from the second sample or a component thereof. 14. A method for characterizing a plurality of liquid samples or components thereof, the method comprising providing four or more liquid samples, providing an array of two or more light scattering probes, analyzing a first plurality of the four or more samples in parallel by light scattering methods that include simultaneously transmitting light from the two or more probes into the first plurality of samples, and detecting light scattered from the first plurality of samples or a component thereof, translating the four or more samples or the array of two or more probes relative to each other, and analyzing a second plurality of the four or more samples in parallel by light scattering methods that include simultaneously transmitting light from two or more probes into the second plurality of samples, and detecting light scattered from the second plurality of samples or a component thereof. 15. A method for identifying useful materials, the method comprising providing a library of liquid samples, the library comprising four or more different liquid samples, analyzing at least four samples of the library in parallel by light scattering methods that include simultaneously transmitting light into the at least four samples of the library, detecting light scattered from the at least four samples of the library or components thereof, and determining a property of the at least four samples of the library or components thereof, and comparing the determined property of each of the at least four samples of the library. 16. The method of claim 13 wherein the first and second liquid samples each have an exposed surface that defines a gas-liquid sample interface, light is transmitted or detected through the gas-liquid sample interface of the first sample, and light is transmitted or detected through the gas-liquid sample interface of the second sample. 17. The method of claim 14 herein each of the four or more samples has an exposed surface that defines a gas-liquid sample interface, and light is transmitted or detected through the gas-liquid sample interface of each of the four or more samples. 18. The method of claim 15 wherein each of the four or more samples has an exposed surface that defines a gas-liquid sample interface, and light is transmitted or detected through the gas-liquid sample interface of each of the four or more samples. 19. The method of claims 12, 16, 17 or 18 wherein the light is transmitted through the gas-liquid sample interface, and the scattered light is detected through the gas-liquid sample interface. 20. The method of claims 12, 16, 17 or 18 wherein the analyzed samples are contained in a vessel, the light is transmitted through a gas-liquid sample interface, and the scattered light is detected through a bottom of the vessel. 21. The method of claims 12, 16, 17 or 18 wherein the gas-liquid sample interface of the analyzed samples is substantially planar in the region through which the light is transmitted. 22. The method of claims 12, 13, 14 or 15 wherein the samples or a component thereof are analyzed by static light scattering. 23. The method of claims 12, 13, 14 or 15 wherein the samples or a component thereof are analyzed by dynamic light scattering. 24. The method of claims 12, 13 or 14 wherein the light scattering analysis further comprises determining at least one property of each of the plurality of samples or of a component thereof, th
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