1998
DOI: 10.1021/jp981335u
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New Method for Determination of Surface Potential of Microscopic Particles by Second Harmonic Generation

Abstract: A new noninvasive method for determining the surface electrostatic potential and surface charge density of microscopic particles using second harmonic generation (SHG) is described. The surface electrostatic properties of 1.05 µm polystyrene sulfate spheres in aqueous solution and that of 0.22 µm oil droplets in aqueous emulsions are obtained. Comparisons of the surface potentials obtained from SHG with the zeta potential obtained from electrophoresis are in excellent agreement with theoretical predictions.

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Cited by 210 publications
(326 citation statements)
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“…Recently, we have employed this technique to selectively study the surfaces of micron-and submicron-sized particles in suspensions. Taking advantage of both the surface specificity and spectroscopic selectivity of SHG, we have studied aqueous suspensions of polystyrene beads, 36,37 liposomes, 38 semiconductor particles, 39 clay particles, 40 and oil/water emulsions, 37,41 obtaining information on the interface adsorbate populations, the free energies of adsorption, the electrostatic potential at the surface of microparticles when they are charged, 41 and the real time measurement of molecular transport across the bilayer of liposomes. 38 Under the dipole approximation, SHG is forbidden in centrosymmetric media, e.g., in bulk solutions.…”
Section: Methodsmentioning
confidence: 99%
“…Recently, we have employed this technique to selectively study the surfaces of micron-and submicron-sized particles in suspensions. Taking advantage of both the surface specificity and spectroscopic selectivity of SHG, we have studied aqueous suspensions of polystyrene beads, 36,37 liposomes, 38 semiconductor particles, 39 clay particles, 40 and oil/water emulsions, 37,41 obtaining information on the interface adsorbate populations, the free energies of adsorption, the electrostatic potential at the surface of microparticles when they are charged, 41 and the real time measurement of molecular transport across the bilayer of liposomes. 38 Under the dipole approximation, SHG is forbidden in centrosymmetric media, e.g., in bulk solutions.…”
Section: Methodsmentioning
confidence: 99%
“…Therefore, SHG can be generated from this kind of material provided the size of the microparticle is comparable to the coherence length of the SHG, i.e., roughly the wavelength of the SH light. [22][23][24][25][26][27][28][29][30][31][32][33] One of the promising applications of this method is to investigate transport kinetics of molecules across liposome bilayers. 28,31,33 Liposomes are spherical self-assembled bilayer structures that separate two aqueous phases.…”
Section: Methodsmentioning
confidence: 99%
“…The SHG signal is dependent on the surface potential created by the electrostatic field of the surface charges, often called the χ (3) contribution to the SHG signal. The χ (3) method has been used to extract the surface charge density of charged planar surfaces and microparticle surfaces, e.g., liposomes, polymer beads, and oil droplets in water (21,25,(34)(35)(36)(37)(38)(39).…”
Section: Significancementioning
confidence: 99%