Refractive index and flow rate detector and method

Abstract

Apparatus and method for detecting the refractive index and rate of fluid flowing through an elongated flow cell, having applications in liquid chromatography. The cell may be of circular cross section and has an input window in one end, an exit window in the other, and a longitudinal side wall. A light source directs divergent light through the entrance window, longitudinally through the cell, to pass through the exit window and be sensed by a photoelectric detector outside the exit window. In a first embodiment, heat transmission apparatus connected to the cell establishes a constant temperature gradient in the cell. This temperature gradient, preferably, has a component perpendicular to the longitudinal dimension of the cell and extending toward the center of the cell. This causes the density of the fluid in the cell to vary as an increasing function of its distance from the walls. The index of refraction of the fluid thus, in this embodiment, increases with distance from the cell walls. This causes the divergent light to be bent away from the cell walls, and toward the center of the cell. The degree of this bending, and hence the fraction of light entering the entrance window which passes through the exit window, increases with the refractive index of the fluid. By appropriate selection of the cell dimensions, of the value of the temperature gradient and of a substantially constant flow rate of the fluid, the bending of the light passing through the cell may be governed such that the fraction of entering light which exits from the cell is a highly dependent function of variations in the refractive index of the fluid in the flow cell. In another embodiment, a fluid having a known refractive index value has its flow rate determined by measuring the absorbance of a beam of light passed therethrough after establishing a temperature gradient in the fluid such that the degree of light bending is influenced by the flow rate.