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Colloidal probe technique : ウィキペディア英語版
Colloidal probe technique

The colloidal probe technique is commonly used to measure interaction forces acting between colloidal particles and/or planar surfaces in air or in solution. This technique relies on the use of an atomic force microscope (AFM). However, instead of a cantilever with a sharp AFM tip, one uses the ''colloidal probe''. The colloidal probe consists of a colloidal particle of few micrometers in diameter that is attached to an AFM cantilever. The colloidal probe technique can be used in the ''sphere-plane'' or ''sphere-sphere'' geometries (''see figure''). One typically achieves a force resolution between 1 and 100 pN and a distance resolution between 0.5 and 2 nm.
The colloidal probe technique has been developed in 1991 independently by Ducker〔W. A. Ducker, T. J. Senden, R. M. Pashley (1991). ''Nature'' 353: 239-241.〕 and Butt.〔H. J. Butt, Biophys. J. 60 (1991) 1438-1444.〕 Since its development this tool has gained wide popularity in numerous research laboratories, and numerous reviews are available in the scientific literature.〔H. J. Butt, B. Cappella, M. Kappl (2005). ''Surf. Sci. Rep''. 59: 1-152.〕〔J. Ralston, I. Larson, M. W: Rutland, A. A. Feiler, M. Kleijn (2005). ''Pure Appl. Chem''. 77: 2149-2170.〕〔M. Borkovec, I. Szilagyi, I. Popa, M. Finessi, P. Sinha, P. Maroni, G. Papastavrou (2012). ''Adv. Colloid Interf. Sci''. 179-182: 85-98.〕
Alternative techniques to measure force between surfaces involve the surface forces apparatus, total internal reflection microscopy, and optical tweezers techniques to with video microscopy.
==Purpose==
The possibility to measure forces involving particles and surfaces directly is essential since such forces are relevant in a variety of processes involving colloidal and polymeric systems. Examples include particle aggregation, suspension rheology, particle deposition, and adhesion processes. One can equally study similar biological phenomena, such as deposition of bacteria or the infection of cells by viruses. Forces are equally most informative to investigate the mechanical properties of interfaces, bubbles, capsules, membranes, or cell walls. Such measurements permit to make conclusions about the elastic or plastic deformation or eventual rupture in such systems.
The colloidal probe technique provides a versatile tool to measure such forces between a colloidal particle and a planar substrate or between two colloidal particles (see figure above). The particles used in such experiments have typically a diameter between 1–10 μm. Typical applications involve measurements of electrical double layer forces and the corresponding surface potentials or surface charge, van der Waals forces, or forces induced by adsorbed polymers.〔〔〔I. Larson, C. J. Drummond, D. Y. C. Chan, F. Grieser, J. Phys. Chem. 99 (1995) 2114-2118; G. Toikka, R. A. Hayes, J. Ralston, Langmuir 12 (1996) 3783-3788.〕

抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)
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