Standard model outputs#

In order for multiple simulation engines to be able to exploit atomic properties computing by arbitrary metatensor atomistic models, we need all the models to return data with specific metadata. If your model returns one of the output defined in this documentation, then the model should follow the metadata structure described here.

For other kind of output, you are free to use any relevant metadata structure, but if multiple people are producing the same kind of outputs, they are encouraged to come together, define the metadata they need and add a new section to this page.

Energy#

Energy is associated with the "energy" key in the model outputs, and must have the following metadata:

Metadata for energy output#

Metadata

Names

Description

keys

"_"

the energy keys must have a single dimension named "_", with a single entry set to 0. The energy is always a metatensor.torch.TensorMap with a single block.

samples

["system", "atom"] or ["system"]

if doing per_atom output, the sample names must be ["system", "atom"], otherwise the sample names must be ["system"].

"system" must range from 0 to the number of systems given as input to the model. "atom" must range between 0 and the number of atoms/particles in the corresponding system. If selected_atoms is provided, then only the selected atoms for each system should be part of the samples.

components

the energy must not have any components

properties

"energy"

the energy must have a single property dimension named "energy", with a single entry set to 0.

Energy gradients#

Most of the time when writing an atomistic model compatible with metatensor, gradients will be handled implicitly and computed by the simulation engine using a backward pass. Additionally, it is possible for the model to support explicit, forward mode gradients

The following gradients can be defined and requested with explicit_gradients:

  • “positions” (\(r_j\)) gradients will contain the negative of the forces \(F_j\).

    \[\frac{\partial E}{\partial r_j} = -F_j\]
Metadata for positions energy’s gradients#

Metadata

Names

Description

samples

["sample", "system", "atom"]

"sample" indicates which of the values samples we are taking the gradient of, and ("system", "atom") indicates which of the atom’s positions we are taking the gradients with respect to; i.e. \(j\) in the equation above.

components

"xyz"

there must be a single component named "xyz" with values 0, 1, 2; indicating the direction of the displacement of the atom in the gradient samples.

  • “strain” (\(\epsilon\)) gradients will contain the stress \(\sigma\) acting on the system, multiplied by the volume \(V\) (sometimes also called the virial of this system)

    \[\frac{\partial E}{\partial \epsilon} = V \sigma\]
Metadata for strain energy’s gradients#

Metadata

Names

Description

samples

"sample"

There is a single gradient sample dimension, "sample" indicating which of the values samples we are taking the gradient of.

components

["xyz_1", "xyz_2"]

Both "xyz_1" and "xyz_2" have values [0, 1, 2], and correspond to the two axes of the 3x3 strain matrix \(\epsilon\).