Tools

Graphs

Allows to graph different quantities for a given trajectory. A ‘save’ button also gives the opportunity to save the data to file.

This example plots the maximal force for each image i and could help in investigating the convergence properties for relaxations:

i, e-min(E), fmax

These are the symbols that can be used:

Symbol Interpretation
e total energy
epot potential energy
ekin kinetic energy
fmax maximum force
fave average force
d(n1,n2) distance between two atoms
R[n,0-2] position of atom number n
i current image number
E[i] energy of image number i
F[n,0-2] force on atom number n
M[n] magnetic moment of atom number n
A[0-2,0-2] unit-cell basis vectors
s path length
a(n1,n2,n3) tangle between atoms n1, n2 and n3, centered on n2
dih(n1,n2,n3,n4) dihedral angle between n1, n2, n3, and n4
T temperature (requires velocity)

Movie

Allows to play the current trajectory as a movie using a number of different settings. Default duration is 5 s.

Expert mode

Python interface to all ase-gui functions, with numerous extra commands defined that help to modify and visualize a system. The commands come in two flavors, the first is interpreted on an atom-by-atom basis (e.g. operates on position, color, etc) and the second is based on the entire frame. The flavor of a given line is determined from the first command. Note that the frame-based commands can be used in atom-based operations, but not vice versa. See below for some examples.

Regular python syntax applies to the commands and numpy has been imported as np.

Two buttons allow to reduce the operation to a given frame:

Only selected atoms (sa) Restricts operation only to the selected atoms. The text command sa activates or deactivates this button.
Only current frame (cf) Restricts operation only to the current frame, useful for long trajectories. The text command cf activates or deactivates this button.

List of atom-based commands with a few examples:

Command Interpretation
x,y,z Cartesian coordinates. Example: x += A[0][0]
r,g,b Color components, invoking the expert mode changes the color mode to manual and allows to address all colors individually. Example: r = (z-min(R[:,2]))/(max(R[:,2])-min(R[:,2]))
rad atomic display radius
s Boolean to control the selection of an atom. Example: s = Z == 6 and x > 5 or s = d == False
f force on an atom
Z atomic number
m magnetic moment
d dynamic, e.g. d = False fixes an atom

List of frame-based and global commands and global objects with examples:

Command Interpretation
e total energy
fmax maximal force
A unit cell
E total energy array of all frames. Example: e-min(E)
F all forces in one frame
M all magnetic moments
R all atomic positions
S boolean array of the entire selection
D boolean array of dynamic atoms (False = atom is fixed)
del S deletes current selection
sa,cf toggles the selected-atoms-only or the current-frame-only buttons
frame provides and edits the frame number in a trajectory
center centers system in its unit cell
cov array of original covalent radii
self expert mode window
gui ase-gui GUI object, this controls the entire ase-gui session
img ase-gui images object, all physical data is stored here

To save data between commands, one has to assign variables to parent objects in the gui, e.g. via self.temp_var = R-img.P[0,:]. DISCLAIMER: Doing so might risk the functionality of the entire ase-gui session if you accidentally overwrite basic functionality of the gui or the image objects stored within.

Finally, recurring selections of commands collected as scripts can be executed as

exec <filename>

If the file in question is saved in the directory ~/.ase/ then just the filename will also do.

Constraints

Allows to set (or remove) constraints based on the currently selected atoms.

Render scene

Graphical interface to the ASE povray interface, ideally it requires that povray is installed on your computer to function, but it also can be used just to export the complete set of povray files.

The texture of each atom is adjustable: The default texture is applied to all atoms, but then additional textures can be defined based on selections (Create new texture from current selection). These can be obtained either from selecting atoms by hand or by defining a selection with a boolean expression, for example Z==6 and x>5 and y<0 will select all carbons with coordinates x>5 and y<0. The available commands are listed in the Help on textures window.

A movie-making mode (render all N frames) is also available. After rendering, the frames can be stitched together using the convert unix program e.g.

localhost:doc hanke$ convert -delay 4.17 temp.*.png temp.gif

For this particular application it might be a good idea to use a white background instead of the default transparent option.

Move atoms

Allows selected atoms to be moved using the arrow keys. The direction is always parallel to the plane of the screen. Two possible movements are available: Just pressing the arrow keys will move by 0.1 Angstrom, shift + arrow keys will move by 0.01 Angstrom.

Rotate atoms

Allows sets of atoms to be rotated using the arrow keys. Different rotation modes are available depending on the number of selected atoms. Again, two modes are available. Just the arrow keys will rotate by 2.5 degrees, and shift + arrow keys will rotate by 0.5 deg.

number of atoms labeled rotation mode
0 atoms, 1, 3, 5 or more atoms uses the centre of mass of the atoms to be rotated as the rotation centre.
2 atoms Defines the vector connecting the two atoms as rotation axis.
4 atoms, selected sequentially Defines the vector connecting the two atoms as rotation axis. This mode has the advantage that the dihedral angle is measured at the same time, thus allowing one to monitor the degree of rotation.

Orient atoms

stub

NEB

stub

Bulk Modulus

stub