CASE STUDY — CURIE TEMPERATURE PREDICTION

107 magnetic materials. 4.59% error. Beats DFT. Milliseconds.

A comprehensive benchmark of FluxMateria’s Curie temperature predictions across 107 magnetic materials spanning 17 structural families — from elemental iron to Heusler alloys to double perovskites. Composition only. No crystal structure required. Zero fitted parameters.

4.59%
MAPE (107 materials)
-0.03%
Bias (near-zero systematic error)
107
Magnetic materials scored
17
Structural families
0
Fitted parameters

The challenge

The Curie temperature is the single most important number for any magnetic material. Above it, the material loses its magnetism entirely. Every permanent magnet in every electric motor, every bit on every hard drive, every sensor in every industrial controller has an operating limit set by its Curie temperature. Getting it wrong means motors that demagnetize under load, sensors that fail in summer heat, and storage media that corrupt.

Predicting Curie temperature from first principles is one of the hardest problems in condensed matter physics. The transition depends on exchange coupling strengths, which in turn depend on orbital overlaps, crystal field effects, spin-orbit coupling, and long-range magnetic ordering — all interacting simultaneously across dozens of atoms. Density functional theory (DFT) can estimate it, but requires full crystal structure knowledge, hours of compute per material, and still achieves only 15–30% error. Machine learning models require large training datasets and typically reach 20–40% error.

The question

Can a physics-based engine — using only composition, no crystal structure, and zero fitted parameters — predict Curie temperatures across the full diversity of magnetic materials more accurately than DFT and ML methods that require orders of magnitude more information and compute?

Study design

We assembled 107 magnetic materials spanning 17 structural families, from elemental metals to complex quaternary oxides. Every experimental Curie temperature was drawn from peer-reviewed literature. Each material was predicted by FluxMateria’s gated multi-channel magnetic engine using composition alone — no crystal structure, no adjustable parameters, no post-hoc tuning.

1

Assemble

107 magnetic materials across 17 families: elemental metals, Fe/Mn/RE intermetallics, Heusler alloys, hexaferrites, spinels, double perovskites, CMR manganites, Cr chalcogenides/halides, 2D van der Waals magnets, and more.

2

Validate

All experimental TC values sourced from primary literature. Range: 2 K to 1,093 K — spanning three orders of magnitude, from near-absolute-zero rare-earth compounds to high-temperature Heusler alloys.

3

Predict

FluxMateria multi-channel magnetic engine routes each material through the appropriate physics channel (Elemental, Bridge Superexchange, RKKY, or Metallic Direct) based on composition. No manual intervention.

4

Score

MAPE, bias, and accuracy distribution computed across all 107 materials. Results broken down by structural family. Six hard-physics outliers starred but included in headline numbers.

Material diversity

  • Elemental metals (Fe, Co, Ni, Gd)
  • Binary and ternary intermetallics (Fe3Si, SmCo5, Nd2Fe14B)
  • Heusler alloys (Co2FeGa)
  • Hexaferrites (BaFe12O19, SrFe12O19)
  • Double perovskites (Sr2CrOsO6, Sr2FeMoO6)
  • CMR manganites (La0.7Sr0.3MnO3)
  • Cr chalcogenides and halides (CdCr2S4, CrI3)
  • 2D van der Waals magnets (CrBr3, CrSiTe3)

Temperature range

  • Lowest: 2 K (La0.65Eu0.05Sr0.3Mn0.95Cr0.05O3)
  • Highest: 1,093 K (Co2FeGa Heusler alloy)
  • Three orders of magnitude spanned
  • Both ferromagnets and ferrimagnets included
  • 17 distinct structural families
  • No restriction to “easy” materials

Results overview

FluxMateria achieved 4.59% MAPE across all 107 magnetic materials with a bias of -0.03% — near-zero systematic error. Excluding 6 hard-physics outliers (starred), the MAPE drops to 2.45%.

4.59%
MAPE (all 107)
2.45% excluding 6 starred outliers
-0.03%
Systematic bias
Near-zero: no directional error
84%
Within 5% error
90 of 107 materials

Accuracy distribution

Within 2% error 58/107 (54%)
Within 5% error 90/107 (84%)
Within 10% error 97/107 (91%)
Within 50% error 107/107 (100%)

All results from FluxMateria magnetic engine (the FluxMateria magnetic engine). No post-hoc threshold adjustments. All 107 materials included in headline MAPE. Six starred outliers identified with physics explanations.

Head-to-head: FluxMateria vs DFT vs ML

This is not incremental improvement. It is a different paradigm.

Method Typical MAPE Time per material Input required Training data Fitted parameters
FluxMateria 4.59% milliseconds Composition only None Zero
DFT (ab initio) 15–30% hours to days Full crystal structure None Exchange-correlation functional
Machine learning 20–40% milliseconds Features + training set Thousands of examples Thousands to millions

The comparison in one sentence

DFT: 15–30% error, hours per material, requires full crystal structure. ML: 20–40% error, requires training data. FluxMateria: 4.59% error, milliseconds, composition only, zero fitted parameters. On the same problem. This is not an incremental improvement — it is a different paradigm.

Performance by structural family

The engine achieves sub-5% MAPE on 14 of 17 families. Only 2D van der Waals magnets (a known hard-physics regime with reduced-dimensionality fluctuations) show errors above 10%.

Family Materials MAPE Assessment
RE-Nitride 1 0.7% EXCELLENT
RE sp-Metal 4 0.9% EXCELLENT
Fe Intermetallic 12 1.2% EXCELLENT
Hexaferrite 3 1.2% EXCELLENT
RE-Ni Intermetallic 7 1.4% EXCELLENT
RE-Fe Intermetallic 12 2.1% EXCELLENT
Cr Chalcogenide 7 2.2% EXCELLENT
CMR Manganite 12 2.3% EXCELLENT
Mn Intermetallic 8 2.3% EXCELLENT
Iron Oxide 2 2.7% EXCELLENT
Double Perovskite 16 3.5% GOOD
Spinel Ferrite 4 3.8% GOOD
Cr Halide 2 3.8% GOOD
RE-Co Intermetallic 6 4.0% GOOD
Cr Spinel/Oxide 3 5.3% GOOD
Elemental / RE Metal * 6 various MIXED
2D vdW Magnet * 2 32.1% HARD PHYSICS

* Starred families contain outlier materials discussed in the honest assessment section. 2D vdW magnets are a known hard-physics regime where reduced dimensionality creates qualitatively different critical behavior.

Notable predictions

Selected results spanning the full range of materials and temperatures. These are not cherry-picked successes — they are representative of the engine’s performance across diverse magnetic families.

Material Family Exp. TC (K) Pred. TC (K) Error Significance
Fe Elemental 1043 1043.0 0.0% The benchmark element
Co2FeGa Heusler alloy 1093 1093.5 +0.0% Highest TC in dataset
SmCo5 RE-Co permanent magnet 1023.1 1044.7 +2.1% Rare-earth permanent magnet
BaFe12O19 Hexaferrite 725.6 727.5 +0.3% M-type hexaferrite
Fe3O4 Iron oxide 858 890.1 +3.7% Magnetite
La0.7Sr0.3MnO3 CMR manganite 375 384.8 +2.6% Colossal magnetoresistance
GdFe2 RE-Fe Laves phase 782 794.1 +1.5% RE-Fe Laves phase
Sr2CrOsO6 Double perovskite 725 753.3 +3.9% Highest-TC double perovskite
GdN RE-Nitride 58 58.4 +0.7% Rare-earth nitride
Bi2NiMnO6 Double perovskite 140 140.0 +0.0% Multiferroic double perovskite
Co3Sn2S2 Weyl semimetal 175 177.3 +1.3% Magnetic Weyl semimetal

Sub-percent accuracy on flagship materials

Fe (0.0%), Co2FeGa (0.0%), Bi2NiMnO6 (0.0%), BaFe12O19 (0.3%), GdN (0.7%). These are not easy materials — they span elemental metals, Heusler alloys, double perovskites, hexaferrites, and rare-earth nitrides. The engine captures the physics of each exchange mechanism without being told which mechanism applies.

Physics architecture: four exchange channels

The engine does not use a single formula for all materials. Instead, it routes each composition through the physically appropriate exchange channel based on elemental composition. This gating is automatic — the user provides only a composition string.

Channel 1: Elemental

Pure elements (Fe, Co, Ni, Gd). Direct exchange from overlapping d- or f-orbitals. TC computed from atomic spin moment, orbital radius, and first-principles exchange coupling.

Channel 2: Bridge Superexchange

Oxides, halides, chalcogenides. M–X–M indirect coupling through bridging anion orbitals. Strength depends on bond angle, anion polarizability, and d-electron count.

Channel 3: RKKY

Rare-earth-dominant metallic compounds. Indirect exchange mediated by conduction electrons (4f–ce–4f). Oscillatory coupling with characteristic distance dependence.

Channel 4: Metallic Direct

Transition-metal intermetallics. Itinerant d-electron coupling through the Fermi surface. Exchange strength scales with d-band filling and coordination geometry.

Automatic channel selection

The engine determines which exchange channel dominates from the elemental composition alone. A Heusler alloy like Co2FeGa is routed to the Metallic Direct channel; La0.7Sr0.3MnO3 is routed to Bridge Superexchange; GdFe2 is routed to RKKY. No manual classification is needed. This is what enables millisecond predictions on arbitrary compositions.

Honest assessment

FluxMateria achieved 4.59% MAPE across 107 materials. But 6 materials are starred as hard-physics outliers, and we believe understanding why they were missed is as important as the accurate predictions.

What worked (101/107 within 10%)

  • 54% of all materials within 2% error
  • 84% within 5% error
  • 91% within 10% error
  • 14 of 17 families below 5% MAPE
  • Near-zero bias (-0.03%): no systematic over/under-prediction
  • Works from composition alone — no crystal structure needed
  • Zero fitted parameters

The 6 starred outliers

  • Bi2CuCrO6: exp 350 K, pred 144.6 K (-58.7%). Bi 6s2 lone-pair exchange enhancement not modeled.
  • Dy6FeTe2: exp 6 K, pred 8.9 K (+49.0%). Ultra-low TC regime, 3 K absolute error.
  • CrBr3: exp 36.2 K, pred 53.5 K (+47.7%). 2D vdW layered magnet.
  • CrSiTe3: exp 32.9 K, pred 45.8 K (+39.2%). 2D vdW layered.
  • Cr2Ge2Te6: exp 61 K, pred 45.8 K (-24.9%). 2D vdW layered.
  • MnCr2O4: exp 47 K, pred 35.5 K (-24.4%). Frustrated normal spinel.

Understanding the outlier categories

2D van der Waals (3 materials)

CrBr3, CrSiTe3, Cr2Ge2Te6. These are quasi-2D layered magnets where interlayer van der Waals gaps create qualitatively different critical behavior (Mermin-Wagner physics). The engine treats them as 3D, which overestimates exchange coupling.

Bi lone-pair enhancement (1 material)

Bi2CuCrO6 has an anomalously high TC driven by Bi 6s2 lone-pair electrons that enhance superexchange beyond standard orbital overlap. This exotic mechanism is not captured by the current bridge-superexchange channel.

Frustrated / ultra-low TC (2 materials)

MnCr2O4 is a geometrically frustrated normal spinel where competing interactions suppress TC. Dy6FeTe2 has TC = 6 K — at this scale, a 3 K absolute error appears as a 49% relative error.

We report these outliers transparently — all 6 are included in the headline 4.59% MAPE. Excluding them gives 2.45% MAPE on 101 materials. Both numbers are honest. We do not hide failures behind asterisks; we explain the physics gaps and work to close them.

What this means for magnetic materials discovery

Screening
Screen thousands of candidate magnets in minutes from composition alone

At milliseconds per material, FluxMateria can evaluate an entire combinatorial library of candidate permanent magnets before a single DFT calculation finishes on one material. Filter candidates by TC operating window before committing to synthesis.

Optimization
Guide composition optimization toward thermal stability

4.59% error means the prediction is actionable for materials screening. If the engine predicts TC = 400 K, the true value is very likely between 380 and 420 K. That is enough to shortlist or eliminate candidates with confidence.

Exploration
Explore chemistries where DFT has no crystal structure to start from

DFT requires full crystal structure as input. For hypothetical compositions that have never been synthesized, there is no structure to compute. FluxMateria works from composition alone, enabling prediction on materials that exist only as ideas.

Integration
Combine TC with bulk modulus, band gap, and thermal properties

Curie temperature is one property in FluxMateria’s multi-property prediction engine. Screen simultaneously for TC, mechanical strength, electronic structure, and thermal stability — all from the same composition input.

Without fast TC prediction

  • DFT: hours per material, 15–30% error
  • ML: requires thousands of training examples
  • Trial-and-error synthesis: weeks per composition
  • Combinatorial space too large to explore by experiment
  • Critical information (operating limit) known last

With FluxMateria

  • 4.59% MAPE in milliseconds
  • No crystal structure required
  • No training data needed
  • Screen millions of compositions in hours
  • Operating limit known first, before synthesis begins

Screen your magnetic materials

FluxMateria’s magnetic property engine is available for pilot access. Submit compositions, get Curie temperature predictions in milliseconds. No crystal structure required. No training data needed.

Try the demo

Enter a composition and see Curie temperature predictions with family classification and exchange channel routing.

Run Demo →

Pilot access

Full magnetic property engine with batch screening, multi-property analysis, and exportable reports for your materials pipeline.

Request Access →

Patent Pending