Three-dimensional optical trapping and evanescent wave light scattering for direct measurement of long range forces between a colloidal particle and a surface
Ar. Clapp et al., Three-dimensional optical trapping and evanescent wave light scattering for direct measurement of long range forces between a colloidal particle and a surface, REV SCI INS, 70(6), 1999, pp. 2627-2636
A novel technique is described to measure weaker long range forces between
a single colloidal particle and a flat surface as a function of separation
distance. The technique uses a three-dimensional optical trap as a force tr
ansducer and evanescent wave light scattering to measure the particle-surfa
ce separation distance. The three-dimensional optical trap allows direct ma
nipulation of the particle near the surface, and the measured displacement
of the particle from the center of the optical trap determines the force of
interaction between the particle and the surface. The particle position is
determined by measuring the scattered light from the particle in an evanes
cent wave created by total internal reflection of a laser beam on the surfa
ce. This combination of optical techniques allows forces to be directly mea
sured for smaller particles (similar to 0.25-5.0 mu m) and over a range of
forces (similar to 10(-14)-10(-11) N) than has been previously reported for
similar force measurement techniques such as atomic force microscopy and t
otal internal reflection microscopy. The experimental results have been com
pared with DLVO theory predictions for 1.5 mu m silica microspheres interac
ting with glass in NaCl solutions of known ionic strength. (C) 1999 America
n Institute of Physics. [S0034-6748(99)00306-8].