                              KALYPSO EXAMPLE PROJECTS

A list of  the projects follows.  See the individual  _readme.doc files in  each
folder for information about the  project. The parameters used for  the projects
are not necessarily optimal (e.g. timesteps, target size, number of impacts) but
they shouild run correctly  on your machine. If  they do not, please  inform the
author.

Most  projects  consist  of input  files  that  are named  with  a  common stem:
Cu(100).trg, Cu(100).prj  etc. If  you load  the projectile  file first, Kalypso
will  search  for  the other  files.  A  few projects  (e.g.  the  Cu(110) ICISS
projects) have input files that have a variety of names e.g. those that apply to
different  directions  of projectile  incidence.  In this  case  a project  will
consist of  the files  that are  common to  all situations: He-Cu(110).prj etc.,
and those that   are specific  to  a  certain experiment:   He-Cu(110)-[001] etc
(this refers  to  projectile  incidence   along the  [001]  azimuth).  See   the
project documentation for more information.

Some of the projects include  Inelastic data input files (*.inl).  Check whether
such a file exists before you run the project. If so, you should make sure it is
also loaded (disable the "Omit" checkbox in the input files dialog box in  order
to load this file). By default, Kalypso does not check for Inelastic files.

Back-up the input files  before attempting to modify  them. Some files are  read
-only because they cannot be recreated correctly using Spider. Examples are  the
projectile file  in the  "cluster" project,  and the  impact files  in the  same
project and the "multi" project.


\cluster deposition: impact of Cu9 clusters (2 eV per atom) with Ni(100)

\grid: gamma ray induced doppler broadening simulation for Ni(100)

\iss: 

(a) azimuthal  dependence of specular  scattering  of 4  keV H projectiles  from
Ag(110)

(b)ICISS simulation for  1.5 keV He  projectiles from Cu(110)  along 3 azimuthal
directions  for  a range  of  projectile altitudinal  angles  of incidence  with
periodic targets

(c) ICISS  simulation that  involves a  periodic binary  compound target,  Ne ->
KBr(100)

(d) another example of an ICISS simulation for a metal, namely 5 keV He incident
along a <011> azimuth of (periodic) Ni(100)

(e) Trajectory modelling for He scattering from periodic 3D Ag(110) target

(f) Distribution of apsidal distances for F -> NaCl(100) scattering

(g) Simulation of image potential effects in 200 eV He -> Cu(110) scattering

\melting:

melting behaviour of Cu(100) [& Pt(100)] and Mo(100) periodic crystallites

\multi-impact:

illustrates  the  procedure  for  carrying  out  a  multiple  projectile  impact
simulation [30 eV Cu -> Ni(100)]

\sputtering

(a) simulation of sputtering and cluster emission from 5 keV Ar-> Cu(111)

(b) sputter  yield as  a function  of altitudinal  angle of  incidence, 3 keV Ar
->Cu(100)

(c) sputter yield prediction for 100 eV Ar -> Fe(100)

(d) sputtering of a radiation damaged Cu/Ni(100) target that contains implanted
Ar projectile species