📢 Newly relaunched — code examples are placeholders while we rebuild. Welcome back, partners.
Smart sensing of the living Earth

Predictive understanding of climate-compounded geohazards.

We build digital twins of the Earth — fusing open, multimodal data with AI and cloud computing, all grounded in physical models — to monitor and forecast soil, landslides, liquefaction, and floods.

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The most devastating disasters are coupled.

Landslides from atmospheric rivers, liquefaction in saturated soils, debris flows after wildfire, storms fed by the land surface. These cascade across the ocean, atmosphere, and solid Earth. We take a data-driven, physics-grounded approach to monitor, characterize, and predict them — in real time and under future climate.

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Coupled hazard use cases
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Earth systems linked
14+
Researchers & partners
Sensors, one platform
What we sense

Listening to soil, slope, and sky

Three coupled processes where dense sensing and physical models change what we can see.

Live demos · use cases

See the technology in action

Each demo is a working slice of the GAIA stack applied to a real, coupled-hazard use case — real events, real sensors, real time.

WA-2025 river floods · seis-2-hydro-sed

From rainfall to rivers, sensed in real time

During the December-2025 atmospheric-river floods on Mt. Rainier's glacial rivers, a seismic network estimated river discharge in the long reaches between sparse stream gauges, while a Stage IV precipitation mosaic tracked the rainfall driving the floods — the forcing and the response, side by side, toward earlier flood awareness in the Orting–Puyallup lahar corridor.

Seismic virtual-discharge network. Discharge inverted from seismic ground motion (triangles) fills the gaps between USGS gauges (diamonds) through the storm sequence.
In compilation
Stage IV precipitation (QPE) mosaic
Hourly NCEP Stage IV quantitative precipitation estimates over the basin — the atmospheric-river rainfall forcing the floods. Compiled by Brandon Kerns; live panel coming soon.
Stage IV precipitation. The rainfall driving the discharge response — forcing for the network above.
Shallow landslides · digital twin

A digital twin for rainfall-triggered slope failure

A live digital twin that fuses real-time rainfall, soil-moisture, and seismic signals with physics-based slope-stability models to anticipate where and when shallow landslides are likely to fail — turning monitoring into early warning.

Live demo coming soon
Shallow-landslide digital twin
Interactive, real-time slope-failure forecasting — currently in build. Check back soon for the live panel.
Shallow-landslide digital twin. Real-time, physics-informed slope-failure forecasting — preview in preparation.
The platform

One stack from sensor to forecast

Open, reproducible building blocks — data, models, evaluation, and the tools that connect them.

Now a page of its own

See every sensor on one living map

The GAIA CRESST catalog brings seismic, hydrological, meteorological, and remote-sensing observations into a single interactive view — so researchers across disciplines can spot what's colocated with their region of interest.

Open the full dashboard
How it all connects

The GAIA knowledge graph

Every hazard, the models that predict or detect it, and the data they rely on — one interactive view of the whole system. Hue is the category, brightness the subcategory; hover a node to trace its chain, click for detail.

Open the full graph
Bringing partners back

Built with our community

GAIA HazLab is powered by the people and institutions advancing open geohazard science.

The team

Geoscientists, engineers & AI builders

A cross-disciplinary group spanning seismology, hydrology, geotechnics, and machine learning.