136  The solid-gas  interface

        reason  why nitrogen  is a  particularly  suitable  adsorbate  for surface
        area determinations  is because the value of c is generally high enough
        to  give  a  well-defined point  B,  but  not  too  high  to  give  excessive
        localisation  of  adsorption.
          Effective  cross-sectional  areas  of  molecules  adsorbed  on  to  solid
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        surfaces  are  catalogued  in reference .
          Krypton  adsorption  at  77 K is often  used  for the  determination of
        relatively  low  solid-surface  areas.  At  this  temperature  the  vapour
        pressure  of krypton (and so the dead-space  correction)  is small, and a
        reasonable  precision  is  attainable.
          The  specific surface  area  of a powder  can be  used  to estimate  the
        average  particle  size  if the  particle  shape  is known.

        Thermal desorption spectroscopy

        A  clean  solid  surface  at  fixed temperature  is  exposed  to  gas at  low
                       8
        pressure  (c.  10~ -10~ 7  torr)  to  allow  an  appropriate  amount  of
        chemisorption  to  take  place  and  the  remaining adsorptive  is then
        pumped  off.  The  sample  is  heated  rapidly  at  a  programmed  rate.
        Pressure surges  are detected  in characteristic  temperature  regions at
        which  the  rate  of  chemidesorption  from  the  various  types  of
        adsorption site becomes appreciable. In addition  to allowing different
        types  of  chemisorption  site  to  be  distinguished,  this  technique
        provides  a  means  for  estimating  activation  energies  of  desorption,
        which,  in  turn,  set  upper  limits for  the  corresponding  adsorption
        energies.


        Composition and structure    of solid surfaces


        So  far  in  this  chapter,  gross  properties  of  solid  surfaces  (specific
        surface  area,  pore  size  distribution  and  adsorption  energies)  have
        been  considered. In Chapter  3, the use of the electron  microscope  to
        investigate  surface  morphology  was discussed.  In  this section,  some
        of  the  spectroscopic, diffractometric  and other  techniques  which are
        available  for investigating  the  atomic  detail  at  solid  surfaces will  be
        considered.  Most  of  these  are  fairly  modern  and  exploit  high
        technology  to  the  full  (at  corresponding  cost!).  Like  some  of  the
        techniques referred  to in Chapter 3 (TEM, SEM, PCS, etc.), they are
        mostly  known by  acronyms.  They  are  many  in number (Adamson 2