A New Retention Method for Sub-10 nm Liquid Filtration Using Fluorescent CdSe QDs

Su Wen Liu; Hai Zheng Zhang

doi:10.4028/www.scientific.net/SSP.195.217

Paper Titles

Direct vs. Indirect Megasonic Tank Cleaning Systems; Uniformity, Cleaning Efficiency and Cost of Ownership
p.201

Development of a Near-Field Megasonic Cleaning System for Nano-Particle Removal
p.205

Megasonic Cleaning to Remove Nano-Dimensional Contaminants from Wafer Surfaces: An Analytical Study
p.209

Frictional Analysis of PVA Brush for Post CMP Cleaning: Effects of Rotation Speed, Compression Distance, and Fluid Viscosity
p.213

A New Retention Method for Sub-10 nm Liquid Filtration Using Fluorescent CdSe QDs
p.217

Investigation of the Evaporation and Wetting Mechanism of IPA-DIW Mixtures
p.223

Effect of the Surface/Water Chemistry on the Creation of Watermarks
p.227

Influence of Ammonia Gas Ambient in IPA Drying Process of the Single Wafer Cleaning System
p.231

Wetting Challenges in Cleaning of High Aspect Ratio Nano-Structures
p.235

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A New Retention Method for Sub-10 nm Liquid Filtration Using Fluorescent CdSe QDs

Abstract:

As advances are made in the lithographic patterning process and critical defect size continues to shrink, new filters are required to remove particles in the sub-10 nm size range. Membrane filtration separates unwanted particles from a fluid by retaining particles on the membrane surface and pores, in much the same manner as a sieve. One key parameter of membrane performance is pore size, usually expressed as pore diameter. However, for nanofiltration, especially for the membranes whose pore size measures under 30 nm, manufacturers may use different methods to rate the membranes pore. Considering the different chemical structures of membranes, the vast combination of materials, and the methods of manufacturing, it is highly unlikely that a universal method can be used for all combinations.