Glow Discharge Mass Spectromet~                                33


      sponding to the accessible transitions of  each element, identification and quan-
      tification of a sample’s elemental composition are straightforward. For a sample
      composed of a single pure element, spectral interpretation is easy. However, when
      it is applied to the analysis of multicomponent materials, the spectral complexity
      often makes interpretation problematic. Mass spectrometry has an advantage in
      this area since there exist far fewer isotopes of a given element than potentially
      populated energy levels. Coburn and coworkers recognized the power of  mass
      spectrometry when they brought the glow discharge source back to the attention of
      mass spectrometrists in the analysis of  solids using both direct current (dc) and
      radio frequency (rf) discharges [ 1 1 - 131. Other milestones occurred when Har-
      rison and Magee [14] and later Colby and Evans [15] demonstrated that a hollow
      cathode glow discharge coupled to a magnetic sector inst~ment could be used to
      provide elemental analysis of the cathode. In 1978, Bruhn et al. [16] reported the
      use of a qua~pole-based glow discharge mass spectrometer. This work indicated
      that a relatively low-cost mass spectrometer could be dedicated to trace elemental
      analysis of  solids.  Since this  time  there  have been  many  advances made  in
      ins~mentation, sample preparation, and techniques for data analysis. Several
      good review articles give further insight into the historical developments of the
      glow discharge as an ion source for mass spectrometry 117-191.  Two achieve-
      ments worth noting are the introduction of commercial instrumentation [203 and
      the development of  a radio frequency glow discharge as an analytical tool for
      the direct analysis of nonconducting samples [21]. As more individuals “redis-
      cover” the power of the glow discharge for trace elemental analysis of solids, the
      future of  GDMS is promising.



                  Y
      The purpose of this section is to provide a basic understanding of glow discharge
      (GD) processes; it is in no way intended to be a complete treatment of GD theory.
      For  a complete treatise on fundamental glow discharge plasma processes, the
      reader is referred to an excellent chapter by Fang and Marcus in Glow Discharge
      Spectroscopies [22].
           Before glow  discharge atomization and ionization processes can be ex-
      plained, it is necessary to establish a vocabulary of the terns used. The glow dis-
      charge is a specific example of a gaseous discharge, which is one type of plasma.
      A  plasm^ is a partially ionized gas consisting of equal numbers of positive and
      negative charges and a larger number of  neutral molecules [23]. The term gas
               refers to the flow of electric current through a gaseous medium [24]. For
      ~isch~rge
      this to occur, a fraction of the gas particles must be ionized. In addition, an electric
      field must exist to accelerate the charged particles, thereby allowing current to
      flow. In the classical version of the glow discharge, a voltage source develops a