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Scientific Figures, Supercharged by AI

Publication-quality charts and diagrams on Mac — powered by Metal GPU acceleration and AI that truly understands your data.

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Buttery Smooooooth! — Native Swift engine with Metal GPU acceleration

Swift

Metal

macOS native

MCP

Metal GPU Acceleration
120fps rendering powered by Apple Metal. Handle 10,000+ data points without breaking a sweat — optimized for Apple Silicon.
MCP-Enabled AI Charting
Connect Claude Desktop or any MCP-compatible AI to create and modify charts through natural conversation. Your AI assistant becomes a figure editor.
Integrated AI Intelligence
Built-in AI understands your data and app structure. Auto-suggest chart types, natural language editing with Command-K, and journal style transfer.
Publication-Ready Export
Export to PDF, SVG, EPS, and PNG at vector quality. Built-in presets for Nature, Science, and other major journals — your figures are submission-ready.

CORE FEATURES

Built for scientists who demand precision

Metal GPU Acceleration

120fps rendering powered by Apple Metal. Handle 10,000+ data points without breaking a sweat — optimized for Apple Silicon.

MCP-Enabled AI Charting

Connect Claude Desktop or any MCP-compatible AI to create and modify charts through natural conversation. Your AI assistant becomes a figure editor.

Integrated AI Intelligence

Built-in AI understands your data and app structure. Auto-suggest chart types, natural language editing with Command-K, and journal style transfer.

Publication-Ready Export

Export to PDF, SVG, EPS, and PNG at vector quality. Built-in presets for Nature, Science, and other major journals — your figures are submission-ready.

AI-POWERED WORKFLOW

Talk to your AI. Get editable charts.

Graphoris connects to your AI assistant via Model Context Protocol (MCP). Just describe what you need — the AI creates publication-ready figures directly in the app.

"Make a plot from this data"

AI CONNECTS

Editable chart created

Don't need to ask AI again to change style, axis, and minor changes.

10+ CHART TYPES

Every chart you need, beautifully rendered

Scatter, line, bar, area, box, violin, histogram, heatmap, 3D charts, and scripted plots — all living on an infinite canvas.

Scatter & Line

With error bars, multiple series, and Metal fast path for 2K+ points.

Bar & Histogram

Grouped, stacked, and dodge layouts with auto-binning.

Box & Violin

Statistical plots with KDE and animated growth transitions.

Heatmap

Category grids with customizable color ramps and Z-value mapping.

3D Charts

Scatter, surface, and bar charts with Metal GPU rendering.

Scripted Plots

Python-driven custom visualizations via GeometryJSON DSL.

One more thing.

AI that sees what you see

AI CURSOR

Point your cursor. Let AI do the thinking.

Drag over any data point, peak, or region on your chart. Graphoris AI instantly analyzes what you're looking at and delivers insights, peak assignments, and suggested next steps.

Grapo AIanalyzing your data...

These are the XRD diffraction peaks of TiO₂ anatase.

| 2θ (°) | Miller Indices | Assignment |

| 25.3 | (101) | Strongest peak — hallmark of anatase TiO₂ |

| 37.8 | (004) | Anatase |

| 48.0 | (200) | Anatase |

| 53.9 | (105) | Anatase |

| 55.1 | (211) | Anatase |

| 62.7 | (204) | Anatase |

| 68.8 | (116) | Anatase |

| 70.3 | (220) | Anatase |

| 75.0 | (215) | Anatase |

The peak at 27.4° is a minor one — it could be a trace of rutile TiO₂, suggesting a small phase impurity in an otherwise pure anatase sample.

The dominant (101) peak at 25.3° with ~10× higher prominence is the definitive fingerprint of the anatase polymorph. Pattern matches JCPDS card #21-1272.

Grapo AIGaussian fitting complete

Gaussian Fitting Results — ZnO Photoluminescence

R² = 0.9893 — Excellent fit; the two-Gaussian model explains ~98.9% of the spectral variance.

Peak 1 — Near-Band-Edge (NBE) Emission 384.8 nm (~3.22 eV)

Characteristic UV emission of ZnO, corresponding to excitonic recombination near the bandgap. Narrow FWHM (19.6 nm) indicates a well-crystallized material with low defect density.

Peak 2 — Deep-Level Emission (DLE) 548.3 nm (~2.26 eV)

Broad visible emission (FWHM ~102 nm) typical of defect-mediated recombination. Commonly attributed to oxygen vacancies (V_O), zinc interstitials, or surface states.

Key Takeaways

• The NBE/DLE intensity ratio (~2.3) suggests moderate-to-good crystal quality

• The broad DLE linewidth confirms its multi-defect or phonon-coupled origin

• Slight redshift of NBE from bulk ZnO may indicate quantum confinement, strain, or temperature effects

Suggested Next Steps

🔬 Deconvolve the DLE further — it may contain sub-peaks (blue ~450, green ~520, yellow ~580 nm)

📊 Calculate the NBE/DLE ratio as a crystal quality metric

🌡 Compare spectra at varying temperatures to identify defect origins

COMMUNITY

Every discipline. One tool.

Physics, chemistry, biology, materials science, engineering — Graphoris is built for anyone who works with data. Join our community to share figures, request features, and help shape the future of scientific visualization.

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Completely Free with MCP, Metal Accelerated Rendering for Mac OS. Just powerful scientific visualization on your Mac.

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Graphoris

Mac-native scientific graph and diagram tool. Free, fast, and AI-powered.