A Coulombic explosion is a condensed-matter physics process in which a molecule or crystal lattice is destroyed by the Coulombic repulsion between its constituent atoms. Coulombic explosions are a prominent technique in laser-based machining, and appear naturally in certain high-energy reactions.
Mechanism
editA Coulombic explosion begins when an intense electric field (often from a laser) excites the valence electrons in a solid, ejecting them from the system and leaving behind positively charged ions. The chemical bonds holding the solid together are weakened by the loss of the electrons, enabling the Coulombic repulsion between the ions to overcome them. The result is an explosion of ions and electrons – a plasma.
The laser must be very intense to produce a Coulomb explosion. If it is too weak, the energy given to the electrons will be transferred to the ions via electron-phonon coupling. This will cause the entire material to heat up, melt, and thermally ablate away as a plasma. The end result is similar to Coulomb explosion, except that any fine structure in the material will be damaged by thermal melting.[1]
It may be shown that the Coulomb explosion occurs in the same parameter regime as the superradiant phase transition i.e. when the destabilizing interactions become overwhelming and dominate over the oscillatory phonon-solid binding motions.[citation needed]
Technological use
editA Coulomb explosion is a "cold" alternative to the dominant laser etching technique of thermal ablation, which depends on local heating, melting, and vaporization of molecules and atoms using less-intense beams. Pulse brevity down only to the nanosecond regime is sufficient to localize thermal ablation – before the heat is conducted far, the energy input (pulse) has ended. Nevertheless, thermally ablated materials may seal pores important in catalysis or battery operation, and recrystallize or even burn the substrate, thus changing the physical and chemical properties at the etch site. In contrast, even light foams remain unsealed after ablation by Coulomb explosion.
Coulomb explosions for industrial machining are made with ultra-short (picosecond or femtoseconds) laser pulses. The enormous beam intensities required (10–400 terawatt per square centimeter thresholds, depending on material) are only practical to generate, shape, and deliver for very brief instants of time.[citation needed] Coulomb explosion etching can be used in any material to bore holes, remove surface layers, and texture and microstructure surfaces; e.g., to control ink loading in printing presses.[2]
Appearance in nature
editHigh speed camera imaging of alkali metals exploding in water has suggested the explosion is a coulomb explosion.[3][4]
During a nuclear explosion based on the fission of uranium, 167 MeV is emitted in the form of a coulombic explosion between each prior nucleus of uranium, the repulsive electrostatic energy between the two fission daughter nuclei, translates into the kinetic energy of the fission products that results in both the primary driver of the blackbody radiation that rapidly generates the hot dense plasma/nuclear fireball formation and thus also both later blast and thermal effects.[5][6]
Scientists at the University of Cologne Zoological Institute have suggested that coulomb explosion (specifically, the electrostatic repulsion of dissociated carboxyl groups of polyglutamic acid) may be part of the explosive action of nematocytes, the stinging cells in aquatic organisms of the phylum Cnidaria.[7]
Coulomb explosion imaging
editMolecules are held together by a balance of charge between negative electrons and positive nuclei. When multiple electrons are expelled, either by laser irradiation or bombardment using highly charged ions, the remaining, mutually repulsive, nuclei fly apart in a Coulomb explosion. The structure of simple gas phase molecules can be determined by imaging which tracks the fragment trajectories.[8][9] As of 2022 the method can work with up to 11-atom molecules.[10][11]
See also
editReferences
edit- ^ Hashida, M.; Mishima, H.; Tokita, S.; Sakabe, S. (2009). "Non-thermal ablation of expanded polytetrafluoroethylene with an intense femtosecond-pulse laser" (PDF). Optics Express. 17 (15): 13116–13121. Bibcode:2009OExpr..1713116H. doi:10.1364/OE.17.013116. hdl:2433/145970. PMID 19654716.
- ^ Müller, D. (November 2009). "Picosecond Lasers for High-Quality Industrial Micromachining". Photonics Spectra: 46–47.
- ^ Mason, Philip E.; Uhlig, Frank; Vaněk, Václav; Buttersack, Tillmann; Bauerecker, Sigurd; Jungwirth, Pavel (26 Jan 2015). "Coulomb explosion during the early stages of the reaction of alkali metals with water". Nature Chemistry. 7 (3): 250–254. Bibcode:2015NatCh...7..250M. doi:10.1038/nchem.2161. PMID 25698335.
- ^ "Sodium's Explosive Secrets Revealed". Scientific American. 27 Jan 2015.
- ^ Alt, Leonard A.; Forcino, Douglas; Walker, Richard I. (2000). "Nuclear events and their consequences" (PDF). In Cerveny, T. Jan (ed.). Medical Consequences of Nuclear Warfare. U.S. Government Printing Office. ISBN 9780160591341.
approximately 82% of the fission energy is released as kinetic energy of the two large fission fragments. These fragments, being massive and highly charged particles, interact readily with matter. They transfer their energy quickly to the surrounding weapon materials, which rapidly become heated
- ^ "Nuclear Engineering Overview" (PDF). Technical University Vienna. Archived from the original (PDF) on May 15, 2018.
The various energies emitted per fission event pg 4. "167 MeV" is emitted by means of the repulsive electrostatic energy between the 2 daughter nuclei, which takes the form of the "kinetic energy" of the fission products, this kinetic energy results in both later blast and thermal effects. "5 MeV" is released in prompt or initial gamma radiation, "5 MeV" in prompt neutron radiation (99.36% of total), "7 MeV" in delayed neutron energy (0.64%) and "13 MeV" in beta decay and gamma decay(residual radiation)
- ^ Berking, Stefan; Herrmann, Klaus (2006). "Formation and discharge of nematocysts is controlled by a proton gradient across the cyst membrane". Helgoland Marine Research. 60 (3): 180–188. Bibcode:2006HMR....60..180B. doi:10.1007/s10152-005-0019-y.
- ^ Légaré, F.; et al. (2005). "Laser Coulomb-explosion imaging of small molecules". Physical Review A. 71 (1): 013415. Bibcode:2005PhRvA..71a3415L. doi:10.1103/PhysRevA.71.013415. S2CID 39373145.
- ^ B. Siegmann; U. Werner; H. O. Lutz; R. Mann (2002). "Complete Coulomb fragmentation of CO2 in collisions with 5.9 MeV u−1 Xe18+ and Xe43+". J Phys B Atom Mol Opt Phys. 35 (17): 3755. Bibcode:2002JPhB...35.3755S. doi:10.1088/0953-4075/35/17/311. S2CID 250782825.
- ^ Boll, Rebecca; Schäfer, Julia M.; Richard, Benoît; Fehre, Kilian; Kastirke, Gregor; Jurek, Zoltan; Schöffler, Markus S.; Abdullah, Malik M.; Anders, Nils; Baumann, Thomas M.; Eckart, Sebastian (2022-02-21). "X-ray multiphoton-induced Coulomb explosion images complex single molecules". Nature Physics. 18 (4): 423–428. doi:10.1038/s41567-022-01507-0. ISSN 1745-2473. S2CID 247047286.
- ^ Miller, Johanna L. (2022-03-25). "Coulomb-explosion imaging tackles an 11-atom molecule". Physics Today. 2022 (1): 0325a. Bibcode:2022PhT..2022a.325.. doi:10.1063/pt.6.1.20220325a. ISSN 1945-0699. S2CID 247826394.