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Maps materials science terms, crystal structures, and sample descriptions to standardized ontology classes (CMSO, ASMO, etc.). Resolves natural-language concepts to ontology entries with confidence scores and translates crystal parameters into ontology-compliant annotations.
How this skill is triggered — by the user, by Claude, or both
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/full:ontology-mapperThis skill is limited to the following tools:
The summary Claude sees in its skill listing — used to decide when to auto-load this skill
Translate real-world materials science descriptions into standardized ontology annotations. Given terms like "FCC copper" or structured data like `{"material": "iron", "structure": "BCC", "lattice_a": 2.87}`, produce the corresponding ontology classes and properties for any registered ontology.
Translate real-world materials science descriptions into standardized ontology annotations. Given terms like "FCC copper" or structured data like {"material": "iron", "structure": "BCC", "lattice_a": 2.87}, produce the corresponding ontology classes and properties for any registered ontology.
ontology_registry.json<name>_mappings.json) for ontology-specific synonyms and labels| Input | Description | Example |
|---|---|---|
| Ontology | Ontology name from registry | cmso, asmo |
| Term(s) | Natural-language materials concept(s) | "unit cell", "FCC,copper,lattice" |
| Crystal system | One of the 7 crystal systems | cubic, hexagonal |
| Bravais lattice | Lattice type (symbol or common name) | FCC, cF, BCC |
| Space group | Space group number (1-230) | 225 |
| Lattice parameters | a, b, c in angstroms; alpha, beta, gamma in degrees | a=3.615 |
| Sample description | JSON dict with material properties | {"material":"copper","structure":"FCC"} |
What do you need to map?
├── A concept or term to find its ontology class
│ └── concept_mapper.py --ontology <name> --term "<term>"
├── Crystal structure parameters to ontology terms
│ └── crystal_mapper.py --ontology <name> --bravais <type> --space-group <N> --a <val>
├── A full sample description to ontology annotations
│ └── sample_annotator.py --ontology <name> --sample '<json>'
└── Multiple terms at once
└── concept_mapper.py --ontology <name> --terms "term1,term2,term3"
Ontology scope — crystal/sample annotation is CMSO-only.
crystal_mapper.pyandsample_annotator.pyemit crystal-structure vocabulary (Crystalline Material, Crystal Structure, Unit Cell, Space Group, lattice properties). This vocabulary is defined by CMSO. ASMO is a simulation-methods ontology and does not define any crystal/sample classes — so for ASMO use the concept-mapping path (concept_mapper.py, which resolves terms like DFT, NPT, timestep, PBE to real ASMO classes) only. Ifsample_annotator.py/crystal_mapper.pyis run with an ontology whose summary lacks the required classes (e.g.--ontology asmo), each unresolvable term is flagged inresults.validation_warningsand givenconfidence: 0.0rather than silently emitting an invalid term.
| Script | Key Outputs |
|---|---|
scripts/concept_mapper.py | results.matches, results.unmatched, results.suggestions |
scripts/crystal_mapper.py | results.ontology_classes, results.ontology_properties, results.effective_system, results.bravais_lattice, results.validation_warnings |
scripts/sample_annotator.py | results.annotations, results.sample_type, results.material_type, results.unmapped_fields, results.suggested_properties, results.validation_warnings |
concept_mapper.py to find matching ontology classes.crystal_mapper.py to map them and validate constraints.sample_annotator.py to produce full ontology annotations.unmapped_fields and suggested_properties for completeness.User: I'm setting up an MD simulation of BCC iron with lattice parameter 2.87 angstroms.
What CMSO terms should I use?
Agent: Let me map your iron sample to CMSO ontology terms.
[Runs: sample_annotator.py --ontology cmso --sample '{"material":"iron","structure":"BCC","lattice_a":2.87,"space_group":229}' --json]
Your BCC iron simulation maps to these CMSO annotations:
- **Sample**: Atomic Scale Sample (subclass of Computational Sample)
- **Material**: Crystalline Material
- **Unit Cell**: Bravais lattice = "cI" (body-centered cubic)
- **Space Group**: number = 229 (Im-3m)
- **Lattice**: a = 2.87 Å
- **Element**: Fe
Suggested additions:
- Number of atoms in the simulation cell
- Simulation cell vectors and angles
# Map a single concept
python3 skills/ontology/ontology-mapper/scripts/concept_mapper.py \
--ontology cmso --term "space group" --json
# Map multiple terms
python3 skills/ontology/ontology-mapper/scripts/concept_mapper.py \
--ontology cmso --terms "FCC,copper,lattice constant" --json
# Map crystal parameters (with ontology-specific labels)
python3 skills/ontology/ontology-mapper/scripts/crystal_mapper.py \
--ontology cmso --bravais FCC --space-group 225 --a 3.615 --json
# Map crystal parameters (generic labels, no ontology specified)
python3 skills/ontology/ontology-mapper/scripts/crystal_mapper.py \
--bravais FCC --space-group 225 --a 3.615 --json
# Annotate a full sample
python3 skills/ontology/ontology-mapper/scripts/sample_annotator.py \
--ontology cmso \
--sample '{"material":"copper","structure":"FCC","space_group":225,"lattice_a":3.615}' \
--json
To support a new ontology, create a <name>_mappings.json in references/:
{
"ontology": "myonto",
"synonyms": { "simulation method": "Simulation Method", ... },
"property_synonyms": { "timestep": "has timestep", ... },
"material_type_rules": { "keyword_rules": [...], "default": "Material" },
"sample_schema": { "sample_class": "Simulation", ... },
"crystal_output": { "base_classes": [...], "property_map": {...} },
"annotation_routing": { "unit_cell_indicators": [...], ... }
}
Then add "mappings_file": "myonto_mappings.json" to the ontology's entry in ontology_registry.json. No code changes needed.
Only include the sample_schema, crystal_output, material_type_rules and
annotation_routing blocks if every class/property they name actually exists in that
ontology's summary. sample_annotator.py validates emitted terms against the loaded
summary and flags any that are undefined (results.validation_warnings, confidence: 0.0).
For example, asmo_mappings.json deliberately ships only synonyms and
property_synonyms because ASMO is a simulation-methods ontology with no crystal/sample
vocabulary — its concept terms (DFT, NPT, timestep, PBE) all resolve, but a crystal/sample
config would emit unresolvable terms.
| Error | Cause | Resolution |
|---|---|---|
space_group must be between 1 and 230 | Invalid space group number | Use a valid space group number |
a must be positive | Non-positive lattice parameter | Provide positive values in angstroms |
Unrecognized Bravais lattice '<x>' | Bravais symbol/name not in the recognized set | Use a common name (FCC, BCC, HCP) or a Pearson symbol (cF, cI, hP, ...) |
Term exceeds maximum length of 200 characters | A --term/--terms entry is too long | Shorten the term |
Too many terms (max 100) | More than 100 terms supplied | Split into smaller batches |
Sample must be a non-empty dict | Empty or missing sample data | Provide a valid JSON sample dict |
Sample has too many keys (max 100) | Oversized sample dict | Reduce the number of sample keys |
| Validation warnings (lattice) | Lattice parameters inconsistent with crystal system | Check that a=b=c for cubic, etc. |
results.validation_warnings (terms) | Emitted class/property not defined in the chosen ontology (e.g. crystal terms for ASMO) | Use CMSO for crystal/sample annotation; use ASMO only for concept mapping |
space group, unit cell, atom) is reported as a 0.9 synonym match even though it coincides exactly with a class label — the matched class and IRI are still correct.sample_annotator.py validation warnings: every emitted class/property is checked against the loaded ontology summary. Terms not defined in that ontology are flagged in results.validation_warnings (and the corresponding annotation gets a validation_warning field with confidence: 0.0). This is how the annotator signals that a crystal/sample term cannot resolve to an IRI in the chosen ontology (e.g. running --ontology asmo on a crystalline sample — see below).results.validation_warnings is empty (or every entry is explained) — a non-empty list means an emitted class/property is not defined in the chosen ontology and was given confidence: 0.0; do not report such terms as valid annotations.match_type and confidence for each concept match and confirmed the chosen term is acceptable for its tier (1.0 exact, 0.9 synonym, 0.7 substring, 0.5 description); for any substring_* or description_class match, verified the matched class is actually the intended concept and not an incidental string hit.results.effective_system and results.bravais_lattice (the resolved Pearson symbol, e.g. cF/cI), and confirmed the input Bravais/space-group/system are mutually consistent (no "space group N implies X but Y was specified" warning in validation_warnings).effective_system — confirmed no warnings such as "Cubic requires a=b" / angle-90 violations, or explicitly justified each one (warnings are advisory, the mapping still proceeds).results.unmatched (concept) and results.unmapped_fields (sample) and confirmed nothing materially important was silently dropped; ran the emitted class_browser.py suggestion for any unmatched term that should have resolved.results.suggested_properties and recorded which missing fields (elements, space_group, lattice_a, ...) are intentionally omitted vs. should be added before the annotation is considered complete.| Tempting shortcut | Why it's wrong / what to do |
|---|---|
| "The script printed annotations, so the sample is correctly annotated." | Emission is not validation. sample_annotator.py will emit a term and then flag it with validation_warning / confidence: 0.0 if it is not in the ontology — always read results.validation_warnings before trusting the output. |
"I'll annotate this crystalline sample with --ontology asmo." | ASMO is a simulation-methods ontology with no crystal/sample vocabulary; every crystal term comes back at confidence: 0.0. Use CMSO for crystal/sample annotation; use ASMO only via the concept-mapping path. |
| "It matched the term, so the mapping is high-confidence." | A match can be a 0.7 substring or 0.5 description hit (e.g. an incidental substring inside an unrelated label). Check confidence/match_type; treat anything below an exact/synonym match as a candidate to verify, not a fact. |
"space group matched a class label, so that's a 1.0 exact match." | The per-ontology synonym table is consulted before exact-label matching, so synonym-key terms (space group, unit cell, atom) report as 0.9 synonym matches even when they equal a class label. The matched class/IRI is still correct — do not "correct" the confidence. |
| "The space group is valid (1–230), so my crystal system is fine." | A valid space group can still contradict an explicitly given --system or Bravais lattice. Read effective_system and check for a "space group N implies X but Y was specified" entry in validation_warnings. |
"My sample has a structure field, so the Bravais lattice resolved." | In the sample path strict_bravais=False: free-text structures (e.g. rocksalt, perovskite) are passed through unmapped with a warning, leaving bravais_lattice null. Verify results.bravais_lattice is the expected Pearson symbol, or supply FCC/BCC/HCP/a Pearson code. |
--ontology is validated against registered ontology names in ontology_registry.json (fixed allowlist)--term and --terms are length-limited and used only for substring matching against pre-processed synonym tables (never interpolated into code)--bravais is validated against a fixed set of recognized lattice type symbols--space-group is validated as an integer between 1 and 230--a, --b, --c, --alpha, --beta, --gamma) are validated as finite positive numbers--sample JSON is parsed with json.loads() and validated as a non-empty dict; keys and values are type-checkedreferences/ directory: ontology_registry.json, *_mappings.json, *_summary.json, crystal_systems.json, element_data.json (all read-only)eval(), exec(), or dynamic code generationscripts/class_browser.py --ontology <name> --search <term> browses classes when a concept is unmatched| Date | Version | Changes |
|---|---|---|
| 2026-06-23 | 1.2 | Validate emitted terms against the loaded ontology (ASMO crystal/sample terms now flagged, not silently emitted); document ASMO is concept-mapping only; clarify synonym-vs-exact confidence precedence; self-contained class_browser suggestion; harden input validation (term/sample size caps, Bravais allowlist) |
| 2026-02-25 | 1.1 | Refactored for multi-ontology support: externalized CMSO-specific knowledge to config |
| 2026-02-25 | 1.0 | Initial release with CMSO mapping support |
npx claudepluginhub heshamfs/materials-simulation-skills --plugin core-numericalParses and queries materials science ontology structures (CMSO, ASMO) — browse class hierarchies, inspect class/property definitions, search terms, and summarize OWL/XML files.
Analyzes materials with pymatgen: crystal structures, phase diagrams, electronic structure, surfaces, interfaces, Materials Project API. Handles structure conversion, symmetry analysis, VASP/Gaussian/QE output.
Analyzes crystal structures, computes phase diagrams and electronic structure (band structure, DOS), integrates with Materials Project, converts file formats.