Inductively  Coupled   Pla,~~a Mass Spectrometry             113


              The optimal  nebulizer  gas  flow  rate for a  particular  power  also  depends  on
         the sampling  depth.  At  a  power  of  1.1 kW and  a  sampling  depth  of  15 mm,  a
         nebulizer  gas  flow  rate of  1.05  L/min  produces the peak Li+ signal. At a  sampling
         depth of 10 mm, the  optimal  nebulizer  gas  flow rate is 0.90 L/min.  At  a  sampling
         depth of 5 mm,  the  optimal  nebulizer  gas  flow  rate is 0.85 L/min.  Again,  this  can
                                                               of
         be understood  from  the  processes  described  in  Fig.  3.2  and  the  effect changes in
         nebulizer  gas  flow  rate  on  the  plasma  temperature  profile  shown  in  Fig.  3.17.  As
         the sampling  depth is increased,  the  optimal  nebulizer  gas  flow  rate  increases.
                                                                      The
                                               of
         optimal  signal  should  occur  when  the  majority the sample  has  been  converted
         into ions  but  the  ions  have  not  diffused  significantly  out   of  the  center  of  the
         plasma.  When  ions  are  sampled farther from  the  load coil, a  higher  nebulizer  gas
         flow  rate is needed so that the initial hot  region of the plasma in the ICP center
         is moved farther away  from  the  load  coil as  well,  as  shown  in  Fig.  3.18.   The
         “mountain,’  behavior of the  signals  as  a  function of nebulizer  gas  flow  rate  and
         sampling  depth is also likely  affected by variations  in  ion  energy  and  ion
                                                                  transmis-
         sion  efficiency.
              Under  normal  plasma  and  sampling  conditions, the elemental  ion is domi-
         nant  compared  to  doubly  charged  ions  or   the  molecular  oxide or  molecular
         hydroxide ions. Barium  has  an  unusually  low  second  ionization  potential eV).
                                                                   (10
         Under  conditions  in  which  the  plasma  temperature  near  the  sampling  orifice  is
         hot  (well  after  the  sample  aerosol  has  been  completely  vaporized  and  ionized),
         Ba2+ signals  are  significant,  Therefore, the Ba2+ signals  are  maximum  at  a  lower
         nebulizer gas flow rate than  that  of  Ba+ (Fig.  3.19).  Doubly  charged  ions  may
         also be created if there is a  discharge  between the plasma  and  the  mass  spectrome-
         ter, or in  the  interface  region.  Molecular  oxide  signals  are  high  when  plasma
         conditions  are  colder.  Near  incompletely  desolvated  droplets  molecular oxide ion
         signals  are  high  and  elemental  ion  signals  are  low  [ 1601. As a  result, BaO+ and




               100 -f               10 mm

                80
                60
                40
                20
                 0
                  0.60   0.70   0.80   0.90   1.00   1  IO
                      Nebulizer  gas flow rate  (Llmin)
                   Effect of  sampling depth on CS+ ICP-MS signals versus nebulizer  gas  flow
         rate. Power  was  1 .l kW. (From Ref. 156.)