Surface types

Elementary surfaces

Notes:

Elementary surfaces refer here to surfaces that can be represented by a single equation.

Planes

Notes:

Parametric form of the general plane is assumed if four values are provided in the surface card. With six values the plane is assumed to be defined by three points.

Surface name	Parameters	Surface equation	Description
`px`	x₀	$S(x) = x - x_0$	Plane perpendicular to x-axis at x = x₀
`py`	y₀	$S(y) = y - y_0$	Plane perpendicular to y-axis at y = y₀
`pz`	z₀	$S(z) = z - z_0$	Plane perpendicular to z-axis at z = z₀
`plane`	A, B, C, D	$S(x,y,z) = Ax+ By + Cz - D$	General plane in parametric form
`plane`	x₁, y₁, z₁, x₂, y₂, z₂, x₃, y₃, z₃		General plane defined by three points

Second-order quadratic surfaces

Notes:

cyl is the same surface as cylz

Surface name	Parameters	Surface equation	Description
`cylx`	y₀, z₀, r	$S(y,z) = (y - y_0)^2 + (z - z_0)^2 - r^2$	Infinite cylinder parallel to x-axis, centred at (y₀,z₀), radius r
`cyly`	x₀, z₀, r	$S(x,z) = (x - x_0)^2 + (z - z_0)^2 - r^2$	Infinite cylinder parallel to y-axis, centred at (x₀,z₀), radius r
`cylz, cyl`	x₀, y₀, r	$S(x,y) = (x - x_0)^2 + (y - y_0)^2 - r^2$	Infinite cylinder parallel to z-axis, centred at (x₀,y₀), radius r
`cylv`	x₀, y₀, z₀, u₀, v₀, w₀, r	$S(x,y,z) = (1-u_0^2)(x - x_0)^2 + (1-v_0^2)(y - y_0)^2 + (1-w_0^2)(z - z_0)-r^2$	Infinite cylinder, parallel to (u₀,v₀,w₀), centred at (x₀,y₀,z₀), radius r
`sph`	x₀, y₀, z₀, r	$S(x,y,z) = (x - x_0)^2 + (y - y_0)^2 + (z - z_0)^2 - r^2$	Sphere, centred at (x₀,y₀,z₀), radius r
`cone`	x₀, y₀, z₀, r, h	$(x - x_0)^2 + (y - y_0)^2 - \left(1 - (z - z_0)/h\right)r^2$	Half cone parallel to z-axis, base at (x₀,y₀,z₀), base radius r, height h (distance from base to vertex)
`quadratic`	A, B, C, D, E, F, G, H, I, J, K	$S(x,y,z) = Ax^2 + By^2 + Cz^2 + Dxy + Eyz + Fzx + Gx + Hy + Jz + K$	General quadratic surface in parametric form

Non-quadratic surfaces

Notes:

Serpent can currently handle only circular torii. Radii R₁ and R₂ must be set equal (denoted in the surface equations as R).

Surface name	Parameters	Surface equation	Description
`inf`	-	$S(y,x,z) = -\infty$	All space
`torx`	x₀, y₀, z₀, r, R₁, R₂	$S(x,y,z) = \left(R - \sqrt{(y - y_0)^2 + (z - z_0)^2}\right)^2 + (x - x_0)^2 - r^2$	Circular torus with major radius R perpendicular to x-axis, centred at (x₀, y₀, z₀), minor radius r
`tory`	x₀, y₀, z₀, r, R₁, R₂	$S(x,y,z) = \left(R - \sqrt{(x - x_0)^2 + (z - z_0)^2}\right)^2 + (y - y_0)^2 - r^2$	Circular torus with major radius R perpendicular to y-axis, centred at (x₀, y₀, z₀), minor radius r
`torz`	x₀, y₀, z₀, r, R₁, R₂	$S(x,y,z) = \left(R - \sqrt{(x - x_0)^2 + (y - y_0)^2}\right)^2 + (z - z_0)^2 - r^2$	Circular torus with major radius R perpendicular to z-axis, centred at (x₀, y₀, z₀), minor radius r

Derived surface types

Notes:

Derived surfaces refer here to surfaces composed of two or more elementary types.

Truncated cylinders

Notes:

Truncated cylinders use the same names as the infinite cylinders above, with two additional values determining the height.

Surface name	Parameters	Composed of	Description
`cylx`	y₀, z₀, r, z₀, z₁	Infinite cylinder + two planes	Infinite cylinder parallel to x-axis, centred at (y₀,z₀), radius r, truncated between [z₀, z₁]
`cyly`	x₀, z₀, r, z₀, z₁	Infinite cylinder + two planes	Infinite cylinder parallel to y-axis, centred at (x₀,z₀), radius r, truncated between [z₀, z₁]
`cylz, cyl`	x₀, y₀, r, z₀, z₁	Infinite cylinder + two planes	Infinite cylinder parallel to z-axis, centred at (x₀,y₀), radius r, truncated between [z₀, z₁]

Regular prisms

Notes:

All prisms are parallel to z-axis, and they can be rotated using surface transformations.

Surface name	Parameters	Composed of	Description
`sqc`	x₀, y₀, d	four planes	Infinite square prism parallel to z-axis, centred at (x₀,y₀), half-width d
`rect`	x₀, x₁, y₀, y₁	four planes	Infinite rectangular prism parallel to z-axis, between [x₀, x₁] and [y₀, y₁]
`hexxc`	x₀, y₀, d	six planes	Infinite hexagonal prism parallel to z-axis, centred at (x₀,y₀), flat surface perpendicular to x-axis, half-width d
`hexyc`	x₀, y₀, d	six planes	Infinite hexagonal prism parallel to z-axis, centred at (x₀,y₀), flat surface perpendicular to y-axis, half-width d
`hexxprism`	x₀, y₀, d, z₀, z₁	eight planes	Truncated hexagonal prism parallel to z-axis, centred at (x₀,y₀), flat surface perpendicular to x-axis, half-width d, truncated between [z₀, z₁]
`hexyprism`	x₀, y₀, d, z₀, z₁	eight planes	Truncated hexagonal prism parallel to z-axis, centred at (x₀,y₀), flat surface perpendicular to y-axis, half-width d, truncated between [z₀, z₁]
`octa`	x₀, y₀, d₁, d₂	eight planes	Infinite octagonal prism parallel to z-axis, centred at (x₀,y₀), half-widths d₁ and d₂
`dode`	x₀, y₀, d₁, d₂	twelve planes	Infinite dodecagonal prism parallel to z-axis, centred at (x₀,y₀), half-widths d₁ and d₂

X-type hexagonal prism (hexxc)
Y-type hexagonal prism (hexyc)
Octagonal prism (octa)
Dodecagonal prism (dode)

3D polyhedra

Notes:

The description of parallelepiped may be wrong.

Surface name	Parameters	Composed of	Description
`cube`	x₀, y₀, z₀, d	six planes	Cube, centred at (x₀,y₀,z₀), half-width d
`cuboid`	x₀, x₁, y₀, y₁, z₀, z₁	six planes	Cuboid, between [x₀, x₁], [y₀, y₁] and [z₀, z₁]
`ppd`	x₀, y₀, z₀, L_x, L_y, L_z, $\alpha$ _x, $\alpha$ _y, $\alpha$ _z	six planes	Parallelepiped, with corner at (x₀, y₀, z₀) and edges of length L_x, L_y and L_z at angles $\alpha$ _x, $\alpha$ _y and $\alpha$ _z (in degrees) with respect to the coordinate axes

Other derived surface types

Surface name	Parameters	Description
`pad`	x₀, y₀, r₁, r₂, $\alpha$ ₁, $\alpha$ ₂	Sector from $\alpha$ ₁ to $\alpha$ ₂ (in degrees) of a cylinder parallel to z-axis, centred at (x₀,y₀), between radii r₁ and r₂
`cross`	x₀, y₀, l, d	Cruciform prism parallel to z-axis, centred at (x₀,y₀), half-width l, half-thickness d
`gcross`	x₀, y₀, d₁, d₂, ...	Prism parallel to z-axis, centred at (x₀,y₀), formed by planes at distances d_n from the center ("generalized cruciform prism", see figure below)

Cylinder sector (pad)
Cruciform prism (cross)
Generalized cruciform prism (gcross)

Rounded corners

Infinite prisms:

sqc
hexxc
hexyc
cross

Allow defining rounded corners. The radius is then provided as the last surface parameter (s in figure below):

Square prism with rounded corners

MCNP-equivalent surfaces

Notes:

Additional surfaces included to simplify input conversion between Serpent and MCNP.
For description, see Chapter 3 of the MCNP5 User's Guide.^[1]

Surface name	Equivalent surface in MCNP
`box`	`BOX`
`ckx`	`K/X`
`cky`	`K/Y`
`ckz`	`K/Z`
`mplane`	`P` (form defined by three points)
`rcc`	`RCC`
`x`	`X`
`y`	`Y`
`z`	`Z`

User-defined surfaces

Notes:

Remember to make a backup of your subroutine before installing new updates.
If you have a working surface routine that might be useful for other users as well, contact the Serpent team and we'll include it in the next update as a built-in type.

Surface name	Parameters	Description
`usr`	p₁, p₂, ...	User-defined surface, implemented in source file "usersurf.c". The subroutine receives the number and list of surface parameters as input. Instructions are included as comments in the source file.

References

^ X-5 Monte Carlo Team. "MCNP — A General Monte Carlo N-Particle Transport Code, Version 5, Volume II: User’s Guide." LA-CP-03-0245, Los Alamos National Laboratory, 2003.

[MCNP5-1] X-5 Monte Carlo Team. "MCNP — A General Monte Carlo N-Particle Transport Code, Version 5, Volume II: User’s Guide." LA-CP-03-0245, Los Alamos National Laboratory, 2003.

[1]

Surface types

Contents

Elementary surfaces

Planes

Second-order quadratic surfaces

Non-quadratic surfaces

Derived surface types

Truncated cylinders

Regular prisms

3D polyhedra

Other derived surface types

Rounded corners

MCNP-equivalent surfaces

User-defined surfaces

References

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