Inductively  Coupled Plasma Mass Spectrometry


                 Analyte Transport  Efficiency  as  a  Function
         of Sample Uptake Rate for Three Different  Nebulizers
        . Used  with  a  Scott Double-Pass Spray  Chambera
                         Analyte  transport  efficiency (%)
         Liquid uptake   Meinhard   Meinhard   Cetac
         rate (mL/min)   TR-30-A3   HEN      MCN
         0.010           50%        60%      60%
         0.020           40%        55%      45%
         0.050           20%        30%      22%
         0.100           13%        16%      14%
         0.200            8%         9.5%     9%
         0.500            4%         5.2%     5%
         l .ooo           2.5%       3%       2.9%

         “Nebulizer gas flow rare was 1.0 Llmin in all cases.
         Source: Ref. 422.



         in  Fig. 3.8 and  Table 3.1, Argon  at  room  temperature  becomes  saturated  when it
         contains  about  25  mglL of water  vapor.  At  an  uptake  rate of  1 mL/min, less than
                                                                       of
         2% of the aerosol  can  evaporate  in  the  spray  chamber  when  a  gas  flow  rate 1
         L/min  is  used.  Then  the  argon  is  saturated  with  water  vapor  and  no  further
         evaporation of  the  aerosol  takes  place.  However,  as  the  sample  uptake  rate   is
          decreased, the percentage of the sample  aerosol  that  can  evaporate  increases.  At
          sample  uptake  rates  below 25 p.,L/min,  all of the water  aerosol  can  evaporate  in
                                                           of
          the  spray  chamber,  thereby  increasing  the  transport  efficiency analyte into the
          ICP. The  largest  drops  may  not  have  sufficient time to evaporate  before  impacting
          the walls of the spray  chamber.
              As  can be seen  from  the  results  in  Table  3.1,  the  analyte  transport  efficiency
          is similar for both “conventional” and “micro-” or “high-efficiency9’ nebulizers
          when  compared  under  identical  flow  rates. The increase  in  analyte  transport effi-
          ciency  with  decrease  in the sample  uptake rate (sometimes  called “starving” the
          nebulizer  because  uptake  rates less than the natural  aspiration  rate  are  used)  was
          reported  long  ago  [21,22].
                               So the  main  advantage of the  newer “micronebulizers”
          is that  their internal volume is small,  a feature that  becomes  more  important  as  the
          uptake  rate  is reduced. A capillary  can  also be inserted into a  “conventional”
          concentric,  pneumatic  nebulizer to decrease its internal dead  volume  [23,24].



          Ultrasonic  nebulizers  are  unique  in that  a  piezoelectric  transducer,  powered  at
          frequencies of 200 IsHz to 10 MHz, is used  to  generate  aerosol  from  sample  that