← Benchmarks | Crystal Structural Properties

Crystal Bond Length BENCHMARK

Crystal nearest-neighbor distances from composition alone. 1.93% MAPE across 351 truly novel materials spanning 80 elements and 65 structure categories. Sub-millisecond runtime.

1.93%

Blind MAPE

across 351 truly novel materials

0.77%

In-Sample MAPE

master benchmark reference set

Elements Covered

s-, p-, d-block, lanthanides, light actinides

Structure Categories

perovskite, Laves, Heusler, spinel…

Family Scorecard

Performance by structure family (sorted by accuracy; families with N≥3 shown)

Family	N	MAPE	Bias	Status
Garnet	7	0.32%	−0.07%	Excellent
Layered Oxide	3	0.49%	−0.06%	Excellent
Pyrochlore	24	0.56%	+0.28%	Excellent
Antifluorite	4	0.71%	−0.19%	Excellent
CaCu₅-type	5	0.97%	−0.97%	Excellent
Trichalcogenide	3	1.01%	+1.01%	Excellent
Spinel	10	1.13%	−0.52%	Excellent
Hexaboride	9	1.18%	−0.59%	Excellent
Anti-Perovskite	17	1.20%	+0.36%	Excellent
Sulvanite	8	1.23%	−0.11%	Excellent
Filled-Skutterudite	7	1.26%	−0.89%	Excellent
Half-Heusler	22	1.33%	+0.74%	Excellent
NiAs	5	1.34%	−1.12%	Excellent
Heusler (L2₁)	4	1.48%	+1.48%	Excellent
Perovskite	31	1.69%	+1.12%	Good
RS Chalcogenide	7	1.71%	+0.14%	Good
Th₃P₄-class	6	1.71%	−0.59%	Good
Chevrel	3	1.76%	−1.76%	Good
Rutile	8	1.87%	−1.37%	Good
Laves C15	30	1.88%	−0.51%	Good
Bixbyite	9	2.07%	−1.25%	Good
B2-intermetallic	15	2.11%	+1.09%	Good
NaTl-type Zintl	20	2.23%	−0.81%	Good
L1₂-intermetallic	4	2.30%	+0.14%	Good
MAX-phase	6	2.39%	+1.93%	Good
Fluorite	6	2.47%	+2.38%	Good
Laves C14	11	2.54%	−0.73%	Acceptable
Olivine	4	3.09%	−3.09%	Acceptable
K₂NiF₄	3	3.16%	+3.16%	Acceptable
Halide-Perovskite	7	3.61%	+0.33%	Acceptable
Double-Perovskite	5	3.99%	+2.95%	Acceptable

Categories with N<3 (single- or two-material outliers) are summarized in the Scope & Limitations section below.

Comparison with DFT and Empirical Methods

Crystal bond length prediction accuracy and computational cost vs. established methods

Method	Mean error	Input required	Wall time	FluxMateria
DFT-PBE (full relaxation)	1–2% lattice constant	Crystal structure + cell	minutes – hours	1.93% MAPE on 351 truly novel materials, composition only, sub-millisecond
HSE06 / hybrid DFT	0.5–1% lattice constant	Crystal structure + cell	hours – days	Same accuracy ballpark, no structure input
Shannon ionic radii sum	5–15% on covalent/intermetallic	Oxidation states + coord numbers	< ms	Covers ionic, covalent, metallic, intermetallic, Zintl uniformly
ML interatomic potentials	1–3% (in-distribution)	Trained on DFT or experimental dataset	ms per material	No training set; deterministic; extrapolates to novel chemistries

All FluxMateria predictions are from composition + structure category + coordination number only. No fitted parameters, no training set, no crystal-structure input.

Methodology

How FluxMateria predicts crystal bond lengths

Benchmark Method Summary

Crystal nearest-neighbor distances are computed by pure Flux Physics from composition alone — no crystal structure input required. This is one of our purest property calculators: zero parameters fitted to crystal bond-length data.

351 truly novel materials in the blind cohort (zero overlap with master reference set)
65 structure categories from perovskite and spinel to Chevrel, Th₃P₄, MAX-phase, K₂NiF₄
80 distinct elements across s-block, p-block, d-block, lanthanides, and light actinides (Th, U)
Bond-length range: 178 pm (stishovite SiO₂) to 380+ pm (heavy alkali Zintl pairs)
Coordination numbers: 2 (linear sp) to 12 (FCC/HCP, hexaboride cage)
Metric: Mean Absolute Percentage Error (MAPE) and signed bias (%)
Runtime: Sub-millisecond per material

Validation Discipline

Validation is structured as ten sequential cold-blind cohorts (v1 through v10), each constructed to target structure classes not yet validated in prior cohorts. The engine predicts every cohort "cold" — before any residual analysis — and predictions are then compared to primary X-ray crystallography literature.

Zero overlap between holdout cohorts and the master in-sample reference
All experimental values cited from primary crystallography sources (Wyckoff, Pauling File, IUCr, ICSD)
Per-material predictions and full sources are public in the data export below
Each refactor of the engine is re-scored across all cohorts to confirm bit-exact preservation

Scope & Limitations

Strengths

351 truly novel materials at 1.93% mean MAPE (1.36% median)
80 elements, 65 structure categories — ionic, covalent, metallic, intermetallic, Zintl, lone-pair-active all covered
Composition-only input: no crystal structure required
Sub-millisecond runtime per prediction
Fully reproducible: per-material predictions + sources published below
Excellent on perovskites (N=31), Laves (N=30 C15 + 11 C14), Half-Heuslers (N=22), Pyrochlores (N=24)

Known Limitations

Single-material outliers in rare polytypes (e.g. MgNi₂ Laves C36 at −8.5%) await additional examples to constrain a generalizable correction
Halide perovskites and double-perovskites show 3–4% MAPE — complex coordination ambiguity
Actinide nitrides (UN, ThN) and Th₃P₄-cage classes have only 2–4 materials each; targeted cohort expansion planned
Heavy actinides (Np, Pu) not yet validated — Th and U only
K₂NiF₄ layered-perovskite and BiOX-tetragonal classes under-represented (N≤3 each)
Layered van der Waals materials (TMDs, etc.) require a separate interlayer model and are outside the current scope

Benchmark Data Export

Per-material predictions, experimental values, and primary X-ray sources

Machine-readable benchmark values for independent review and reproducible analysis. Covers all 351 truly novel materials in cohorts v1–v10, with predicted and experimental nearest-neighbor distances (in picometers), structure category, coordination, and primary X-ray crystallography source for every row.

crystal_bond_lengths_benchmark.json

Full benchmark in JSON: summary stats + 351 per-material rows with predictions and sources.

Download JSON

crystal_bond_lengths_benchmark.csv

Same 351-material table as flat CSV for spreadsheet analysis.

Download CSV

crystal_bond_lengths_benchmark.md

Human-readable markdown summary with the first 30 rows inline.

Download MD

References

Primary data sources for experimental validation

R.W.G. Wyckoff, Crystal Structures, 2nd ed., Vol. 1–6, Interscience, 1963–1971.
P. Villars & K. Cenzual, Pearson's Crystal Data — Crystal Structure Database for Inorganic Compounds, ASM International, accessed 2026.
International Union of Crystallography (IUCr) primary literature, various authors and journals.
Inorganic Crystal Structure Database (ICSD), FIZ Karlsruhe / NIST, accessed 2026.
R.D. Shannon, "Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides," Acta Cryst. A32, 751–767 (1976).
Materials Project Database, materialsproject.org (accessed 2026).

Benchmark basis

Crystal bond lengths are computed by pure Flux Physics with zero parameters fitted to crystal data. Per-material predictions and primary X-ray sources are public.

Pure Flux

Try the Materials module

Predict crystal bond lengths alongside band gap, elastic, thermal, and magnetic properties — all from composition alone.

← Back to Module Request Access