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Sonochemistry

 
Sci-Tech Dictionary: sonochemistry
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(¦sän·ə′kem·ə·strē)

(chemistry) Any chemical change, such as in reaction type or rate, that occurs in response to sound or ultrasound.

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Sci-Tech Encyclopedia: Sonochemistry
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The study of the chemical changes that occur in the presence of sound or ultrasound. Industrial applications of ultrasound include many physical and chemical effects, for example, cleaning, soldering, welding, dispersion, emulsification, disinfection, pasteurization, extraction, flotation of minerals, degassing of liquids, defoaming, and production of gas-liquid sols.

When liquids are exposed to intense ultrasound, high-energy chemical reactions occur, often accompanied by the emission of light. There are three classes of such reactions: homogeneous sonochemistry of liquids, heterogeneous sonochemistry of liquid-liquid or liquid-solid systems, and sonocatalysis (which overlaps the first two). In some cases, ultrasonic irradiation can increase reactivity by nearly a millionfold. Especially for liquid-solid reactions, the rate enhancements via ultrasound have proved extremely useful for the synthesis of organic and organometallic compounds. Because cavitation occurs only in liquids, chemical reactions are not generally seen in the ultrasonic irradiation of solids or solid-gas systems.

Ultrasound spans the frequencies of roughly 20 kHz to 10 MHz (human hearing has an upper limit of less than 18 kHz). Ultrasound has acoustic wavelengths of roughly 7.5–0.015 cm which are much larger than molecular dimensions. As a result, the chemical effects of ultrasound are not from direct interaction, but are derived from several different physical mechanisms, depending on the nature of the system. For both sonochemistry and sonoluminescence, the most important of these mechanisms is acoustic cavitation: the formation, growth, and implosive collapse of bubbles in liquids irradiated with high-intensity sound. During the final stages of cavitation, compression of the gas inside the bubbles produces enormous local heating and high pressures. See also Cavitation.

When a liquid-solid interface is subjected to ultrasound, cavitation occurs, but a markedly asymmetric bubble collapse occurs, which generates a jet of liquid directed at the surface with velocities greater than 330 ft/s (100 m/s). The impingement of this jet can create a localized erosion (and even melting), responsible for surface pitting and ultrasonic cleaning. Enhanced chemical reactivity of solid surfaces is associated with these processes.

Ultrasonic irradiation of liquid-powder suspensions produces another effect: high-velocity interparticle collisions. Cavitation and the shock waves that it creates in a slurry can accelerate solid particles to high velocities. The resultant collisions are capable of inducing dramatic changes in surface morphology, composition, and reactivity.

The predominant reactions of homogeneous sonochemistry are bond breaking and radical formation. In addition to the initiation or enhancement of chemical reactions, irradiation of liquids with high-intensity ultrasound generates the emission of visible light. The production of such luminescence is a consequence of the localized hot spot created by the implosive collapse of gas- and vapor-filled bubbles during acoustic cavitation. In general, sonoluminescence may be considered a special case of homogeneous sonochemistry. Under conditions where an isolated, single bubble undergoes cavitation, recent studies on the duration of the sonoluminescence flash suggest that a shock wave may be created within the collapsing bubble. See also Chemiluminescence; Homogeneous catalysis.

A major industrial application of ultrasound is emulsification. The first reported and most studied liquid-liquid heterogeneous systems have involved ultrasonically dispersed mercury. The effect of the ultrasound in this system appears to be due to the large surface area of mercury generated in the emulsion. See also Emulsion.

The effects of ultrasound on liquid-solid heterogeneous organometallic reactions have been a matter of intense investigation. Various research groups have dealt with extremely reactive metals, such as lithium (Li), magnesium (Mg), or zinc (Zn), as stoichiometric reagents for a variety of common transformations.

Sonochemistry can be used as a synthetic tool for the creation of unusual inorganic materials. Ultrasound has proved extremely useful in the synthesis of a wide range of nanostructured materials, including high-surface-area transition metals, alloys, carbides, oxides, and colloids. Sonochemistry is also proving to have important applications with polymeric materials. Substantial work has been accomplished in the sonochemical initiation of polymerization and in the modification of polymers after synthesis. Sonochemistry has found another recent application in the preparation of unusual biomaterials, notably protein microspheres. The mechanism responsible for microsphere formation is a combination of two acoustic phenomena: emulsification and cavitation. These protein microspheres have a wide range of biomedical applications, including their use as echo contrast agents for sonography, magnetic resonance imaging contrast enhancement, and drug delivery. See also Nanochemistry; Nanostructure; Polymer; Protein.

Wikipedia: Sonochemistry
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In chemistry, the study of sonochemistry is concerned with understanding the effect of sonic waves and wave properties on chemical systems. The chemical effects of ultrasound do not come from a direct interaction with molecular species. Studies have shown that no direct coupling of the acoustic field with chemical species on a molecular level can account for sonochemistry[1] or sonoluminescence[2]. Instead, sonochemistry arises from acoustic cavitation: the formation, growth, and implosive collapse of bubbles in a liquid. This is demonstrated in phenomena such as ultrasound, sonication, sonoluminescence, and sonic cavitation.

Sonochemistry is that branch of one,which deals with the study of sonic waves and their properties on chemical systems.

The influence of sonic waves traveling through liquids was first reported by Robert Williams Wood (1868-1955) and Alfred Lee Loomis (1887-1975) in 1927, but the article was left mostly unnoticed.[3] Sonochemistry experienced a renaissance in the 1980s with the advent of inexpensive and reliable generators of high-intensity ultrasound.

Upon irradiation with high intensity sound or ultrasound, acoustic cavitation usually occurs. Cavitation – the formation, growth, and implosive collapse of bubbles irradiated with sound— is the impetus for sonochemistry and sonoluminescence.[4] Bubble collapse in liquids produces enormous amounts of energy from the conversion of kinetic energy of the liquid motion into heating the contents of the bubble. The compression of the bubbles during cavitation is more rapid than thermal transport, which generates a short-lived localized hot-spot. Experimental results have shown that these bubbles have temperatures around 5000 K, pressures of roughly 1000 atm, and heating and cooling rates above 1010 K/s.[5][6] These cavitations can create extreme physical and chemical conditions in otherwise cold liquids.

With liquids containing solids, similar phenomena may occur with exposure to ultrasound. Once cavitation occurs near an extended solid surface, cavity collapse is nonspherical and drives high-speed jets of liquid to the surface[7]. These jets and associated shock waves can damage the now highly heated surface. Liquid-powder suspensions produce high velocity interparticle collisions. These collisions can change the surface morphology, composition, and reactivity.[8]

Three classes of sonochemical reactions exist: homogeneous sonochemistry of liquids, heterogeneous sonochemistry of liquid-liquid or solid-liquid systems, and, overlapping with the aforementioned, sonocatalysis.[9][10][11] Sonoluminescence is typically regarded as a special case of homogeneous sonochemistry.[12][13] The chemical enhancement of reactions by ultrasound has been explored and has beneficial applications in mixed phase synthesis, materials chemistry, and biomedical uses. Because cavitation can only occur in liquids, chemical reactions are not seen in the ultrasonic irradiation of solids or solid-gas systems.

For example, in chemical kinetics, it has been observed that ultrasound can greatly enhance chemical reactivity in a number of systems by as much as a million-fold [14]; effectively acting as a catalyst by exciting the atomic and molecular modes of the system (such as the vibrational, rotational, and translational modes). In addition, in reactions that use solids, ultrasound breaks up the solid pieces from the energy released from the bubbles created by cavitation collapsing through them. This gives the solid reactant a larger surface area for the reaction to proceed over, increasing the observed rate of reaction.

While the application of ultrasound often generates mixtures of products, a paper published in 2007 in the journal Nature described the use of ultrasound to selectively effect a certain cyclobutane ring-opening reaction.[15]

Sonochemistry can be performed by using a bath (usually used for ultrasonic cleaning) or with a high power probe.

See also

References

  1. ^ Suslick, K. S. "Sonochemistry," Science 1990, 247, 1439-1445.
  2. ^ Suslick, K. S.; Flannigan, D. J. “Inside a Collapsing Bubble, Sonoluminescence and Conditions during Cavitation” Annual Rev. Phys. Chem. 2008, 59, 659-683.
  3. ^ Wood, R.W.; Loomis, A.L. The Physical and Biological Effects of High Frequency Sound Waves of Great Intensity. Philos. Mag. 1927, 4, 414.
  4. ^ Leighton, T.G. The Acoustic Bubble; Academic Press: London, 1994, pp.531-555.
  5. ^ Suslick, K.S.; Hammerton, D.A.; Cline, R.E., Jr. J. Am. Chem. Soc. 1986, 108, 5641.
  6. ^ Flint, E.B.; Suslick, K.S. Science. 1991, 253, 1397.
  7. ^ Leighton, T.G. The Acoustic Bubble; Academic Press: London, 1994, pp.531-555.
  8. ^ Suslick, K.S.; Doktycz, S.J. Adv. Sonochem. 1990, 1, 197-230.
  9. ^ Einhorn, C.; Einhorn, J. Luche, J.L. Synthesis 1989, 787.
  10. ^ Luche, J.L.; Compets. Rendus. Serie. IIB 1996, 323, 203, 307.
  11. ^ Pestman, J.M.; Engberts, J.B.F.N.; de Jong, F. Jong. Recl. Trav. Chim. Pays-Bas. 1994, 113, 533.
  12. ^ Crum, L.A. Physics Today 1994, 47, 22.
  13. ^ Putterman, S.J. Sci. Am. February 1995, p. 46.
  14. ^ Suslick, K.S.; Casadonte, D.J. J. Am. Chem. Soc. 1987, 109, 3459.
  15. ^ "Brute Force Breaks Bonds". Chemical & Engineering News. 22 March 2007. http://pubs.acs.org/cen/news/85/i13/8513notw4.html. 

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