Magnetic Sector Mass Spectrometers: Working Eqs. The dependence of mass-to-charge ratio on the electric and magnetic fields is easily derived.

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Magnetic Sector Mass Spectrometers: Working Eqs. The dependence of mass-to-charge ratio on the electric and magnetic fields is easily derived. All ion formed in the ion source are accelerated to a kinetic energy, T of: Solving for the velocity, v, we get: From the Lorentz force law, the magnetic field applies a force evB: Substituting for v, we arrive at the working equation for a magnetic sector mass spectrometer: 11/21/2018

Magnetic Sector Mass Spectrometers: Working Eqs. The electric sector is usually held constant at a value which passes only ions having the specific kinetic energy. Therefore the parameter that is most commonly varied is B, the magnetic field strength. The magnetic field is usually scanned exponentially or linearly to obtain the mass spectrum. A magnetic field scan can be used to cover a wide range of mass-to charge ratios with a sensitivity that is essentially independent of the mass-to-charge ratio. The maximum ion transmission and sensitivity occur at the maximum working accelerating voltage for a given magnetic sector mass spectrometer. The effective mass range of the mass spectrometer can be increased by decreasing the accelerating voltage, with a sensitivity that is roughly proportional to the accelerating voltage. 11/21/2018