6. Defining Geometry¶
6.1. Surfaces and Regions¶
The geometry of a model in OpenMC is defined using constructive solid geometry (CSG), also sometimes referred to as combinatorial geometry. CSG allows a user to create complex regions using Boolean operators (intersection, union, and complement) on simpler regions. In order to define a region that we can assign to a cell, we must first define surfaces which bound the region. A surface is a locus of zeros of a function of Cartesian coordinates \(x,y,z\), e.g.
A plane perpendicular to the \(x\) axis: \(x  x_0 = 0\)
A cylinder parallel to the \(z\) axis: \((x  x_0)^2 + (y  y_0)^2  R^2 = 0\)
A sphere: \((x  x_0)^2 + (y  y_0)^2 + (z  z_0)^2  R^2 = 0\)
Defining a surface alone is not sufficient to specify a volume – in order to define an actual volume, one must reference the halfspace of a surface. A surface halfspace is the region whose points satisfy a positive or negative inequality of the surface equation. For example, for a sphere of radius one centered at the origin, the surface equation is \(f(x,y,z) = x^2 + y^2 + z^2  1 = 0\). Thus, we say that the negative halfspace of the sphere, is defined as the collection of points satisfying \(f(x,y,z) < 0\), which one can reason is the inside of the sphere. Conversely, the positive halfspace of the sphere would correspond to all points outside of the sphere, satisfying \(f(x,y,z) > 0\).
In the Python API, surfaces are created via subclasses of
openmc.Surface
. The available surface types and their corresponding
classes are listed in the following table.
Surface 
Equation 
Class 

Plane perpendicular to \(x\)axis 
\(x  x_0 = 0\) 

Plane perpendicular to \(y\)axis 
\(y  y_0 = 0\) 

Plane perpendicular to \(z\)axis 
\(z  z_0 = 0\) 

Arbitrary plane 
\(Ax + By + Cz = D\) 

Infinite cylinder parallel to \(x\)axis 
\((yy_0)^2 + (zz_0)^2  R^2 = 0\) 

Infinite cylinder parallel to \(y\)axis 
\((xx_0)^2 + (zz_0)^2  R^2 = 0\) 

Infinite cylinder parallel to \(z\)axis 
\((xx_0)^2 + (yy_0)^2  R^2 = 0\) 

Sphere 
\((xx_0)^2 + (yy_0)^2 + (zz_0)^2  R^2 = 0\) 

Cone parallel to the \(x\)axis 
\((yy_0)^2 + (zz_0)^2  R^2(xx_0)^2 = 0\) 

Cone parallel to the \(y\)axis 
\((xx_0)^2 + (zz_0)^2  R^2(yy_0)^2 = 0\) 

Cone parallel to the \(z\)axis 
\((xx_0)^2 + (yy_0)^2  R^2(zz_0)^2 = 0\) 

General quadric surface 
\(Ax^2 + By^2 + Cz^2 + Dxy + Eyz + Fxz + Gx + Hy + Jz + K = 0\) 

Torus parallel to the \(x\)axis 
\((xx_0)^2/B^2+\frac{( \sqrt{(yy_0)^2+(zz_0)^2}  A)^2}{C^2}  1 = 0\) 

Torus parallel to the \(y\)axis 
\((yy_0)^2/B^2+\frac{( \sqrt{(xx_0)^2+(zz_0)^2}  A)^2}{C^2}  1 = 0\) 

Torus parallel to the \(z\)axis 
\((zz_0)^2/B^2+\frac{( \sqrt{(xx_0)^2+(yy_0)^2}  A)^2}{C^2}  1 = 0\) 
Each surface is characterized by several parameters. As one example, the parameters for a sphere are the \(x,y,z\) coordinates of the center of the sphere and the radius of the sphere. All of these parameters can be set either as optional keyword arguments to the class constructor or via attributes:
sphere = openmc.Sphere(r=10.0)
# This is equivalent
sphere = openmc.Sphere()
sphere.r = 10.0
Once a surface has been created, halfspaces can be obtained by applying the
unary 
or +
operators, corresponding to the negative and positive
halfspaces, respectively. For example:
>>> sphere = openmc.Sphere(r=10.0)
>>> inside_sphere = sphere
>>> outside_sphere = +sphere
>>> type(inside_sphere)
<class 'openmc.surface.Halfspace'>
Instances of openmc.Halfspace
can be combined together using the
Boolean operators &
(intersection), 
(union), and ~
(complement):
>>> inside_sphere = openmc.Sphere()
>>> above_plane = +openmc.ZPlane()
>>> northern_hemisphere = inside_sphere & above_plane
>>> type(northern_hemisphere)
<class 'openmc.region.Intersection'>
The &
operator can be thought of as a logical AND, the 
operator as a
logical OR, and the ~
operator as a logical NOT. Thus, if you wanted to
create a region that consists of the space for which \(4 < z < 3\) or
\(3 < z < 4\), a union could be used:
>>> region_bottom = +openmc.ZPlane(4) & openmc.ZPlane(3)
>>> region_top = +openmc.ZPlane(3) & openmc.ZPlane(4)
>>> combined_region = region_bottom  region_top
Halfspaces and the objects resulting from taking the intersection, union, and/or complement or halfspaces are all considered regions that can be assigned to cells.
For many regions, a boundingbox can be determined automatically:
>>> northern_hemisphere.bounding_box
(array([1., 1., 0.]), array([1., 1., 1.]))
While a bounding box can be determined for regions involving halfspaces of
spheres, cylinders, and axisaligned planes, it generally cannot be determined
if the region involves cones, nonaxisaligned planes, or other exotic
secondorder surfaces. For example, the openmc.model.hexagonal_prism()
function returns the interior region of a hexagonal prism; because it is bounded
by a openmc.Plane
, trying to get its bounding box won’t work:
>>> hex = openmc.model.hexagonal_prism()
>>> hex.bounding_box
(array([0.8660254, inf, inf]),
array([ 0.8660254, inf, inf]))
6.1.1. Boundary Conditions¶
When a surface is created, by default particles that pass through the surface
will consider it to be transmissive, i.e., they pass through the surface
freely. If your model does not extend to infinity in all spatial dimensions, you
may want to specify different behavior for particles passing through a
surface. To specify a vacuum boundary condition, simply change the
Surface.boundary_type
attribute to ‘vacuum’:
outer_surface = openmc.Sphere(r=100.0, boundary_type='vacuum')
# This is equivalent
outer_surface = openmc.Sphere(r=100.0)
outer_surface.boundary_type = 'vacuum'
Reflective and periodic boundary conditions can be set with the strings
‘reflective’ and ‘periodic’. Vacuum and reflective boundary conditions can be
applied to any type of surface. Periodic boundary conditions can be applied to
pairs of planar surfaces. If there are only two periodic surfaces they will be
matched automatically. Otherwise it is necessary to specify pairs explicitly
using the Surface.periodic_surface
attribute as in the following
example:
p1 = openmc.Plane(a=0.3, b=5.0, d=1.0, boundary_type='periodic')
p2 = openmc.Plane(a=0.3, b=5.0, d=1.0, boundary_type='periodic')
p1.periodic_surface = p2
Both rotational and translational periodic boundary conditions are specified in the same fashion. If both planes have the same normal vector, a translational periodicity is assumed; rotational periodicity is assumed otherwise. Currently, only rotations about the \(z\)axis are supported.
For a rotational periodic BC, the normal vectors of each surface must point
inwards—towards the valid geometry. For example, a XPlane
and
YPlane
would be valid for a 90degree periodic rotation if the geometry
lies in the first quadrant of the Cartesian grid. If the geometry instead lies
in the fourth quadrant, the YPlane
must be replaced by a
Plane
with the normal vector pointing in the \(y\) direction.
6.2. Cells¶
Once you have a material created and a region of space defined, you need to
define a cell that assigns the material to the region. Cells are created using
the openmc.Cell
class:
fuel = openmc.Cell(fill=uo2, region=pellet)
# This is equivalent
fuel = openmc.Cell()
fuel.fill = uo2
fuel.region = pellet
In this example, an instance of openmc.Material
is assigned to the
Cell.fill
attribute. One can also fill a cell with a universe or lattice. If you provide
no fill to a cell or assign a value of None, it will be treated as a “void”
cell with no material within. Particles are allowed to stream through the cell but
will undergo no collisions:
# This cell will be filled with void on export to XML
gap = openmc.Cell(region=pellet_gap)
The classes Halfspace
, Intersection
, Union
, and
Complement
and all instances of openmc.Region
and can be
assigned to the Cell.region
attribute.
6.3. Universes¶
Similar to MCNP and Serpent, OpenMC is capable of using universes, collections
of cells that can be used as repeatable units of geometry. At a minimum, there
must be one “root” universe present in the model. To define a universe, an
instance of openmc.Universe
is created and then cells can be added
using the Universe.add_cells()
or Universe.add_cell()
methods. Alternatively, a list of cells can be specified in the constructor:
universe = openmc.Universe(cells=[cell1, cell2, cell3])
# This is equivalent
universe = openmc.Universe()
universe.add_cells([cell1, cell2])
universe.add_cell(cell3)
Universes are generally used in three ways:
To be assigned to a
Geometry
object (see Exporting a Geometry Model),To be assigned as the fill for a cell via the
Cell.fill
attribute, andTo be used in a regular arrangement of universes in a lattice.
Once a universe is constructed, it can actually be used to determine what cell
or material is found at a given location by using the Universe.find()
method, which returns a list of universes, cells, and lattices which are
traversed to find a given point. The last element of that list would contain the
lowestlevel cell at that location:
>>> universe.find((0., 0., 0.))[1]
Cell
ID = 10000
Name = cell 1
Fill = Material 10000
Region = 10000
Rotation = None
Temperature = None
Translation = None
As you are building a geometry, it is also possible to display a plot of single
universe using the Universe.plot()
method. This method requires that you
have matplotlib installed.
6.4. Lattices¶
Many particle transport models involve repeated structures that occur in a
regular pattern such as a rectangular or hexagonal lattice. In such a case, it
would be cumbersome to have to define the boundaries of each of the cells to be
filled with a universe. OpenMC provides a means to define lattice structures
through the openmc.RectLattice
and openmc.HexLattice
classes.
6.4.1. Rectangular Lattices¶
A rectangular lattice defines a twodimensional or threedimensional array of universes that are filled into rectangular prisms (lattice elements) each of which has the same width, length, and height. To completely define a rectangular lattice, one needs to specify
The coordinates of the lowerleft corner of the lattice (
RectLattice.lower_left
),The pitch of the lattice, i.e., the distance between the center of adjacent lattice elements (
RectLattice.pitch
),What universes should fill each lattice element (
RectLattice.universes
), andA universe that is used to fill any lattice position outside the welldefined portion of the lattice (
RectLattice.outer
).
For example, to create a 3x3 lattice centered at the origin in which each
lattice element is 5cm by 5cm and is filled by a universe u
, one could run:
lattice = openmc.RectLattice()
lattice.lower_left = (7.5, 7.5)
lattice.pitch = (5.0, 5.0)
lattice.universes = [[u, u, u],
[u, u, u],
[u, u, u]]
Note that because this is a twodimensional lattice, the lowerleft coordinates
and pitch only need to specify the \(x,y\) values. The order that the
universes appear is such that the first row corresponds to lattice elements with
the highest \(y\) value. Note that the RectLattice.universes
attribute expects a doublynested iterable of type openmc.Universe
—
this can be normal Python lists, as shown above, or a NumPy array can be used as
well:
lattice.universes = np.tile(u, (3, 3))
For a threedimensional lattice, the \(x,y,z\) coordinates of the lowerleft
coordinate need to be given and the pitch should also give dimensions for all
three axes. For example, to make a 3x3x3 lattice where the bottom layer is
universe u
, the middle layer is universe q
and the top layer is universe
z
would look like:
lat3d = openmc.RectLattice()
lat3d.lower_left = (7.5, 7.5, 7.5)
lat3d.pitch = (5.0, 5.0, 5.0)
lat3d.universes = [
[[u, u, u],
[u, u, u],
[u, u, u]],
[[q, q, q],
[q, q, q],
[q, q, q]],
[[z, z, z],
[z, z, z]
[z, z, z]]]
Again, using NumPy can make things easier:
lat3d.universes = np.empty((3, 3, 3), dtype=openmc.Universe)
lat3d.universes[0, ...] = u
lat3d.universes[1, ...] = q
lat3d.universes[2, ...] = z
Finally, it’s possible to specify that lattice positions that aren’t normally
without the bounds of the lattice be filled with an “outer” universe. This
allows one to create a truly infinite lattice if desired. An outer universe is
set with the RectLattice.outer
attribute.
6.4.2. Hexagonal Lattices¶
OpenMC also allows creation of 2D and 3D hexagonal lattices. Creating a hexagonal lattice is similar to creating a rectangular lattice with a few differences:
The center of the lattice must be specified (
HexLattice.center
).For a 2D hexagonal lattice, a single value for the pitch should be specified, although it still needs to appear in a list. For a 3D hexagonal lattice, the pitch in the radial and axial directions should be given.
For a hexagonal lattice, the
HexLattice.universes
attribute cannot be given as a NumPy array for reasons explained below.As with rectangular lattices, the
HexLattice.outer
attribute will specify an outer universe.
For a 2D hexagonal lattice, the HexLattice.universes
attribute should be
set to a twodimensional list of universes filling each lattice element. Each
sublist corresponds to one ring of universes and is ordered from the outermost
ring to the innermost ring. The universes within each sublist are ordered from
the “top” (position with greatest y value) and proceed in a clockwise fashion
around the ring. The HexLattice.show_indices()
static method can be used
to help figure out how to place universes:
>>> print(openmc.HexLattice.show_indices(3))
(0, 0)
(0,11) (0, 1)
(0,10) (1, 0) (0, 2)
(1, 5) (1, 1)
(0, 9) (2, 0) (0, 3)
(1, 4) (1, 2)
(0, 8) (1, 3) (0, 4)
(0, 7) (0, 5)
(0, 6)
Note that by default, hexagonal lattices are positioned such that each lattice
element has two faces that are parallel to the \(y\) axis. As one example,
to create a threering lattice centered at the origin with a pitch of 10 cm
where all the lattice elements centered along the \(y\) axis are filled with
universe u
and the remainder are filled with universe q
, the following
code would work:
hexlat = openmc.HexLattice()
hexlat.center = (0, 0)
hexlat.pitch = [10]
outer_ring = [u, q, q, q, q, q, u, q, q, q, q, q]
middle_ring = [u, q, q, u, q, q]
inner_ring = [u]
hexlat.universes = [outer_ring, middle_ring, inner_ring]
If you need to create a hexagonal boundary (composed of six planar surfaces) for
a hexagonal lattice, openmc.model.hexagonal_prism()
can be used.
6.5. Exporting a Geometry Model¶
Once you have finished building your geometry by creating surfaces, cell, and,
if needed, lattices, the last step is to create an instance of
openmc.Geometry
and export it to an XML file that the
openmc executable can read using the
Geometry.export_to_xml()
method. This can be done as follows:
geom = openmc.Geometry(root_univ)
geom.export_to_xml()
# This is equivalent
geom = openmc.Geometry()
geom.root_universe = root_univ
geom.export_to_xml()
Note that it’s not strictly required to manually create a root universe. You can
also pass a list of cells to the openmc.Geometry
constructor and it
will handle creating the unverse:
geom = openmc.Geometry([cell1, cell2, cell3])
geom.export_to_xml()
6.6. Using CADbased Geometry¶
6.6.1. Defining Geometry¶
OpenMC relies on the Direct Accelerated Geometry Monte Carlo (DAGMC)
to represent CADbased geometry in a surface mesh format. DAGMC geometries are
applied as universes in the OpenMC geometry file. A geometry represented
entirely by a DAGMC geometry will contain only the DAGMC universe. Using a
openmc.DAGMCUniverse
looks like the following:
dag_univ = openmc.DAGMCUniverse(filename='dagmc.h5m')
geometry = openmc.Geometry(dag_univ)
geometry.export_to_xml()
The resulting geometry.xml
file will be:
<?xml version='1.0' encoding='utf8'?>
<geometry>
<dagmc auto_ids="false" filename="dagmc.h5m" id="1" name="" />
</geometry>
DAGMC universes can also be used to fill CSG cells or lattice cells in a geometry:
cell.fill = dagmc_univ
It is important in these cases to understand the DAGMC model’s position with respect to the CSG geometry. DAGMC geometries can be plotted with OpenMC to verify that the model matches one’s expectations.
Note: DAGMC geometries used in OpenMC are currently required to be clean, meaning that all surfaces have been imprinted and merged successfully and that the model is watertight. Future implementations of DAGMC geometry will support small volume overlaps and unmerged surfaces.
6.6.2. Cell, Surface, and Material IDs¶
By default, DAGMC applies cell and surface IDs defined by the CAD engine that
the model originated in. If these IDs overlap with IDs in the CSG ID space,
this will result in an error. However, the auto_ids
property of a DAGMC
universe can be set to set DAGMC cell and surface IDs by appending to the
existing CSG cell ID space in the OpenMC model.
Similar options exist for the material IDs of DAGMC models. If DAGMC material
assignments are based on natively defined OpenMC materials, no further work is
required. If DAGMC materials are assigned using the University of Wisconsin
Unified Workflow (UWUW), however, material IDs in the UWUW material library
may overlap with those used in the CSG geometry. In this case, overlaps in the
UWUW and OpenMC material ID space will cause an error. To automatically resolve
these ID overlaps, auto_ids
can be set to True
to append the UWUW
material IDs to the OpenMC material ID space.
6.7. Calculating Atoms Content¶
If the total volume occupied by all instances of a cell in the geometry is known by the user, it is possible to assign this volume to a cell without performing a stochastic volume calculation:
from uncertainties import ufloat
# Set known total volume in [cc]
cell = openmc.Cell()
cell.volume = 17.0
# Set volume if it is known with some uncertainty
cell.volume = ufloat(17.0, 0.1)
Once a volume is set, and a cell is filled with a material or distributed
materials, it is possible to use the atoms()
method to obtain
a dictionary of nuclides and their total number of atoms in all instances
of a cell (e.g. {'H1': 1.0e22, 'O16': 0.5e22, ...}
):
cell = openmc.Cell(fill = u02)
cell.volume = 17.0
O16_atoms = cell.atoms['O16']