Hyperlayer separation in hollow fiber flow field-flow fractionation: effect of membrane materials on resolution and selectivity

Hollow fiber flow field-flow fractionation HF-FlFFF has been tested Ž . by varying the temperature 21᎐73ЊC to increase separation speed with reduced lift forces. It has been experimentally shown that the separation time of 0.050᎐0.426-m polystyrene latex standards can be reduced approximately by hal

## Abstract Since hollow‐fiber flow field‐flow fractionation (HF FlFFF) utilizes a cylindrical channel made of a hollow‐fiber membrane, which is inexpensive and simple in channel assembly and thus disposable, interests are increasing as a potential separation device in cells, proteins, and macromol

## Abstract The influence of forces on the particles other than the applied cross flow is studied in hollow fiber flow field‐flow fractionation (HF^5^). Such forces can be of either attractive or repelling in nature. It is shown by injecting polystyrene latex beads (0.091 μm in diameter) at differe

## Abstract Electrical field flow fractionation (EFFF) has two perpendicular driving forces that help to produce an optimal separation of solute in a mixture [Giddings, Science 1993; 260:1456–1465]. For Couette flow based devices, the ratio of the velocity of the capillary walls offers an extra par