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The '''mass-to-charge ratio''', is a ] that is widely used in the ] of charged particles, e.g. in electron optics and ]. It appears in the scientific fields of ], ], ], ], ], ], ] and ]. The '''mass-to-charge ratio''', is a ] that is widely used in the ] of charged particles, e.g. in electron optics and ]. It appears in the scientific fields of ], ], ], ], ], ], ] and ].


== History == == History ==

Revision as of 18:01, 24 September 2006

Template:TotallyDisputed The mass-to-charge ratio, is a physical quantity that is widely used in the electrodynamics of charged particles, e.g. in electron optics and ion optics. It appears in the scientific fields of Lithography, electron microscopy, cathode ray tubes, accelerator physics, nuclear physics, Auger spectroscopy, cosmology and mass spectrometry.

History

In the 19th century the mass-to-charge ratio of some ions was measured by electrochemical methods. In 1897 the mass-to-charge ratio m / e {\displaystyle m/e} of the electron was first measured by J.J. Thomson. By doing this he showed that the electron, which was postulated before in order to explain electricity, was in fact a particle with a mass and a charge and that its mass-to-charge ratio was much smaller than that of the hydrogen ion H. In 1898 Wilhelm Wien separated ions (canal rays) according to their mass-to-charge ratio with an ion optical device with superimposed electric and magnetic fields (Wien filter). In 1901 Walter Kaufman measured the relativistic mass incrase of fast electrons. In 1913 J.J. Thomson measured the mass-to-charge ratio of ions with an instrument he called a parabola spectrograph. Today, an instrument that measures the mass-to-charge ratio of charged particles is called mass spectrometer.

Symbols & Units

The official symbol for mass is m {\displaystyle m} . The official symbol for electric charge is Q {\displaystyle Q} . However, q {\displaystyle q} is also very common. Therefore the official symbol for the mass-to-charge ratio is m / Q {\displaystyle m/Q} or m / q {\displaystyle m/q} .

The SI unit of the physical quantity m / q {\displaystyle m/q} is kilogram/coulomb.

[ m / q ] {\displaystyle } = kg/C

In most fields dealing with particles it is much more common to use the atomic mass unit u (the former amu) or its synonym dalton, Da, and the elementary charge unit e {\displaystyle e} , whereby the unit of the mass-to-charge ratio becomes u/e or Da/e.

[ m / q ] {\displaystyle } = u/e = Da/e

Cooks and Rockwood proposed the unit thomson (Th) for the mass-to-charge ratio:

1 Th == 1 u/e == 1 Da/e.

For example, for the ion C7H7, m / q {\displaystyle m/q} = 45.5 Th or m / q {\displaystyle m/q} = 45.5 Da/e

In mass spectrometry besides m/q the notation m/z is also commonly used.

Importance

The importance of the mass-to-charge ratio is that two particles with the same mass-to-charge ratio move exactly the same in a vacuum when subject to electric and magnetic fields.

When charged particles are moved in electric and magnetic fields the following two laws apply:

F = q ( E + v × B ) , {\displaystyle \mathbf {F} =q(\mathbf {E} +\mathbf {v} \times \mathbf {B} ),} (Lorentz force law)
F = m a {\displaystyle \mathbf {F} =m\mathbf {a} } (Newton's second law of motion)

where F is the force applied to the ion, m is the mass of the ion, a is the acceleration, q is the ionic charge, E is the electric field, and v x B is the vector cross product of the ion velocity and the magnetic field

Using Newton's third law of motion yields:

( m / q ) a = E + v × B {\displaystyle (m/q)\mathbf {a} =\mathbf {E} +\mathbf {v} \times \mathbf {B} }

This differential equation is the classic equation of motion of charged particles in vacuum. Together with the particles initial conditions it completely determines the particles motion in space and time. It immediately reveals that two particles with the same physical quantity m/q behave exactly the same. This is why mass-to-charge ratio is an important the physical quantity in those scientific fields where charged particles (represented by their mass m and their charge q) interact with magnetic (B) or electric (E) fields.

See also

Further reading

Books
  • Electron and Ion Optics by Miklos Szilagyi, Plenum Press, ISBN 0-306-42717-6.
  • Introduction into optics of charged particles by J. Grosser, Teubner, ISBN 3-519-03050-0.
  • Applied charged particle optics, edited by A. Septier, Academic Press, ISBN 0-12-014574-X.
Web sites

References and notes

  1. lemoyne.edu
  2. lemoyne.edu
  • Cooks, R. G. and A. L. Rockwood (1991). "The 'Thomson'. A suggested unit for mass spectroscopists." Rapid Communications in Mass Spectrometry 5(2): 93.
  • NIST on units and manuscript check list
  • Physics Today's instructions on quantities and units
  • International Vocabulary of Basic Terms in Metrology (Second edition 1993: ISBN 92-67-01075-1); a guide whith contributions of the following organizations: IUPAP, IUPAC, ISO, OIML, IEC, IFCC.
  • IUPAP Red Book SUNAMCO 87-1 "Symbols, Units, Nomenclature and Fundamental Constants in Physics" (does not have an online version).
  • Symbols Units and Nomenclature in Physics IUPAP-25 IUPAP-25, E.R. Cohen & P. Giacomo, Physics 146A (1987) 1-68.
  • AIP style manual
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