Particle-particle and particle-wall capillary interactions were measur
ed as a function of the separation distance. The ''particles'' were ve
rtical thin glass cylinders and/or small glass spheres, protruding fro
m an air/liquid interface. The particles attract each other due to the
overlapping of the menisci formed around each of them. The force of i
nteraction is detected by a sensitive torsion microbalance. It is base
d on counterbalancing the moment of a couple of forces, acting between
two pairs of particles, by the torsion moment of a thin platinum wire
. By varying the wire diameter, we accessed forces differing by severa
l orders of magnitude, from about 5 dyn at small separation between th
e particles down to 0.001 dyn at large separation. The smallest force
was measured with two cylinders of diameters about 300 mu m. For two s
pheres (diameters 1.2 mm) we obtained difference in the forces corresp
onding to different heights of protrusion from the liquid surface. For
interacting sphere and glass cylinder the force follows similar trend
s as the forces between two spheres or two cylinders. In the case of s
phere and glass wall, however, the force first increases with decreasi
ng the distance and then decreases close to the wall passing through a
maximum. The predictions of the theory of capillary immersion forces
are in quantitative agreement with the experimental results.