Cómo cachar un átomo y jugar con él
trampas iónicas
Keywords:
Traps, atoms, ions, laser, cooling
Abstract
Ion traps, as tools to confine and to lessen the movement of charged particles into small regions of space and isolated from surrounding media, have become of great importance in the study of properties, of not only atoms and molecules, but also in elementary particles such as electrons and protons. Leading to improved and new kind of experiments and applications that are relevant to physics, chemistry and other disciplines. And as a source to new phenomena, which, otherwise, may not be possible to observe. In all of this lies the importance of this kind of traps that have given a boost to basic science and to the development of technologies with applications to common life problems.
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References
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Baker, C. J., et al, Sympathetic cooling of positrons to cryogenic temperatures for antihydrogen production. Nature Communications 12, 6139. 2021.
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Hanneke, D., Fogwell, S. y Gabrielse, G., New Measurement of the Electron Magnetic Moment and the Fine Structure Constant. Phys. Rev. Lett.100, 120801. 2008.
March, R. E., Quadrupole ion traps. Mass Spectrom. Rev., 28, 961– 989. 2009.
Nägerl, H. C., Bechter, W., Eschner, J., Schmidt- Kaler, F., Blatt, R., Ion strings for quantum gates. Appl. Phys. B 66, 603–608. 1998.
Neuhauser, N., Hohenstatt, M., Toschek, P. E. y Dehmelt, H., Localized visible Ba+ mono-ion oscillator. Physical Review A, 22(3),1137. 1980.
Paul, W. Electromagnetic traps for charged and neutral particles. Reviews of modern physics, Vol. 62, No. 3. 1990.
Wineland, D., Drullinger, R. E. y Walls, F. L., Radiation pressure cooling of bound resonant absorbers, Phys. Rev. Lett., 40, 1639. 1978.
Sauter, T. H., Blatt, R., Neuhauser, W. y Toschek, P. E., Quantum jumps observed in the fluorescence of a single ion. Optics Communications, 60(5):287–292. 1986.
Baker, C. J., et al, Sympathetic cooling of positrons to cryogenic temperatures for antihydrogen production. Nature Communications 12, 6139. 2021.
Blaum, K., Novikov, Y. N. y Werth, G., Penning traps as a versatile tool for precise experiments in fundamental physics. Contemporary physics, 51 (2). 2010.
Hanneke, D., Fogwell, S. y Gabrielse, G., New Measurement of the Electron Magnetic Moment and the Fine Structure Constant. Phys. Rev. Lett.100, 120801. 2008.
March, R. E., Quadrupole ion traps. Mass Spectrom. Rev., 28, 961– 989. 2009.
Nägerl, H. C., Bechter, W., Eschner, J., Schmidt- Kaler, F., Blatt, R., Ion strings for quantum gates. Appl. Phys. B 66, 603–608. 1998.
Neuhauser, N., Hohenstatt, M., Toschek, P. E. y Dehmelt, H., Localized visible Ba+ mono-ion oscillator. Physical Review A, 22(3),1137. 1980.
Paul, W. Electromagnetic traps for charged and neutral particles. Reviews of modern physics, Vol. 62, No. 3. 1990.
Wineland, D., Drullinger, R. E. y Walls, F. L., Radiation pressure cooling of bound resonant absorbers, Phys. Rev. Lett., 40, 1639. 1978.
Sauter, T. H., Blatt, R., Neuhauser, W. y Toschek, P. E., Quantum jumps observed in the fluorescence of a single ion. Optics Communications, 60(5):287–292. 1986.
Published
2024-12-19
How to Cite
Nava Rodríguez, L. A., & Hernández Pozos, J. L. (2024). Cómo cachar un átomo y jugar con él: trampas iónicas. Contactos, Revista De Educación En Ciencias E Ingeniería, (139), 138 - 146. Retrieved from https://contactos.izt.uam.mx/index.php/contactos/article/view/476
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