Partial recovery of meter-scale surface weather
- URL: http://arxiv.org/abs/2602.23146v1
- Date: Thu, 26 Feb 2026 16:11:53 GMT
- Title: Partial recovery of meter-scale surface weather
- Authors: Jonathan Giezendanner, Qidong Yang, Eric Schmitt, Anirban Chandra, Daniel Salles Civitarese, Johannes Jakubik, Jeremy Vila, Detlef Hohl, Campbell Watson, Sherrie Wang,
- Abstract summary: Near-surface atmospheric conditions can differ sharply over tens to hundreds of meters due to land cover and topography.<n>It is unclear whether such meter-scale variability reflects irreducibly chaotic dynamics or contains a component predictable from surface characteristics and large-scale atmospheric forcing.<n>We show that a substantial, physically coherent component of meter-scale near-surface weather is statistically recoverable from existing observations.
- Score: 4.903961907292919
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Near-surface atmospheric conditions can differ sharply over tens to hundreds of meters due to land cover and topography, yet this variability is absent from current weather analyses and forecasts. It is unclear whether such meter-scale variability reflects irreducibly chaotic dynamics or contains a component predictable from surface characteristics and large-scale atmospheric forcing. Here we show that a substantial, physically coherent component of meter-scale near-surface weather is statistically recoverable from existing observations. By conditioning coarse atmospheric state on sparse surface station measurements and high-resolution Earth observation data, we infer spatially continuous fields of near-surface wind, temperature, and humidity at 10 m resolution across the contiguous United States. Relative to ERA5, the inferred fields reduce wind error by 29% and temperature and dewpoint error by 6%, while explaining substantially more spatial variance at fixed time steps. They also exhibit physically interpretable structure, including urban heat islands, evapotranspiration-driven humidity contrasts, and wind speed differences across land cover types. Our findings expand the frontier of weather modeling by demonstrating a computationally feasible approach to continental-scale meter-resolution inference. More broadly, they illustrate how conditioning coarse dynamical models on static fine-scale features can reveal previously unresolved components of the Earth system.
Related papers
- FuseTen: A Generative Model for Daily 10 m Land Surface Temperature Estimation from Spatio-Temporal Satellite Observations [3.344876133162209]
Urban heatwaves, droughts, and land heatwaves are pressing and growing challenges in the context of climate change.<n>One of the most important variables for assessing and understanding these phenomena is Land Surface Temperature (LST)<n>We propose FuseTen to produce daily LST observations at a fine 10 m spatial resolution by fusing-basedtemporal observations from Landsat 8, and Terra MODIS.
arXiv Detail & Related papers (2025-07-30T23:04:16Z) - A Generative Framework for Probabilistic, Spatiotemporally Coherent Downscaling of Climate Simulation [18.881422165965017]
We present a novel generative framework that uses a score-based diffusion model trained on high-resolution reanalysis data to capture the statistical properties of local weather dynamics.<n>We demonstrate that the model generates spatially and temporally coherent weather dynamics that align with global climate output.
arXiv Detail & Related papers (2024-12-19T19:47:35Z) - Stratospheric aerosol source inversion: Noise, variability, and uncertainty quantification [0.0]
This article presents a framework for stratospheric aerosol source inversion using a Bayesian approximation error approach.
We leverage specially designed earth system model simulations using the Energy Exascale Earth System Model (E3SM)
A comprehensive framework for data generation, data processing, dimension reduction, operator learning, and Bayesian inversion is presented.
arXiv Detail & Related papers (2024-09-10T20:12:36Z) - MambaDS: Near-Surface Meteorological Field Downscaling with Topography Constrained Selective State Space Modeling [68.69647625472464]
Downscaling, a crucial task in meteorological forecasting, enables the reconstruction of high-resolution meteorological states for target regions.
Previous downscaling methods lacked tailored designs for meteorology and encountered structural limitations.
We propose a novel model called MambaDS, which enhances the utilization of multivariable correlations and topography information.
arXiv Detail & Related papers (2024-08-20T13:45:49Z) - Cluster-Segregate-Perturb (CSP): A Model-agnostic Explainability Pipeline for Spatiotemporal Land Surface Forecasting Models [5.586191108738564]
This paper introduces a pipeline that integrates principles from both perturbation-based explainability techniques like LIME and global marginal explainability like PDP.
The proposed pipeline simplifies the undertaking of diverse investigative analyses, such as marginal sensitivity analysis, marginal correlation analysis, lag analysis, etc., on complex land surface forecasting models.
arXiv Detail & Related papers (2024-08-12T04:29:54Z) - Spatial Temporal Approach for High-Resolution Gridded Wind Forecasting across Southwest Western Australia [0.43012765978447565]
This paper shows the potential of our machine learning model for wind forecasts across various prediction horizons and spatial coverage.
It can help facilitate more informed decision-making and enhance resilience across critical sectors.
arXiv Detail & Related papers (2024-07-26T05:44:27Z) - FengWu-GHR: Learning the Kilometer-scale Medium-range Global Weather
Forecasting [56.73502043159699]
This work presents FengWu-GHR, the first data-driven global weather forecasting model running at the 0.09$circ$ horizontal resolution.
It introduces a novel approach that opens the door for operating ML-based high-resolution forecasts by inheriting prior knowledge from a low-resolution model.
The hindcast of weather prediction in 2022 indicates that FengWu-GHR is superior to the IFS-HRES.
arXiv Detail & Related papers (2024-01-28T13:23:25Z) - Observation-Guided Meteorological Field Downscaling at Station Scale: A
Benchmark and a New Method [66.80344502790231]
We extend meteorological downscaling to arbitrary scattered station scales and establish a new benchmark and dataset.
Inspired by data assimilation techniques, we integrate observational data into the downscaling process, providing multi-scale observational priors.
Our proposed method outperforms other specially designed baseline models on multiple surface variables.
arXiv Detail & Related papers (2024-01-22T14:02:56Z) - Residual Corrective Diffusion Modeling for Km-scale Atmospheric Downscaling [58.456404022536425]
State of the art for physical hazard prediction from weather and climate requires expensive km-scale numerical simulations driven by coarser resolution global inputs.
Here, a generative diffusion architecture is explored for downscaling such global inputs to km-scale, as a cost-effective machine learning alternative.
The model is trained to predict 2km data from a regional weather model over Taiwan, conditioned on a 25km global reanalysis.
arXiv Detail & Related papers (2023-09-24T19:57:22Z) - Multi-scale Digital Twin: Developing a fast and physics-informed
surrogate model for groundwater contamination with uncertain climate models [53.44486283038738]
Climate change exacerbates the long-term soil management problem of groundwater contamination.
We develop a physics-informed machine learning surrogate model using U-Net enhanced Fourier Neural Contaminated (PDENO)
In parallel, we develop a convolutional autoencoder combined with climate data to reduce the dimensionality of climatic region similarities across the United States.
arXiv Detail & Related papers (2022-11-20T06:46:35Z) - EarthNet2021: A novel large-scale dataset and challenge for forecasting
localized climate impacts [12.795776149170978]
Large Earth observation datasets now enable us to create machine learning models capable of translating coarse weather information into high-resolution Earth surface forecasts.
We define high-resolution Earth surface forecasting as video prediction of satellite imagery conditional on mesoscale weather forecasts.
We introduce EarthNet 2021, a new curated dataset containing target-temporal Sentinel 2 satellite imagery at 20 m resolution, matched with high-resolution topography and mesoscale (1.28 km) weather variables.
arXiv Detail & Related papers (2020-12-11T11:21:00Z) - Dynamical Landscape and Multistability of a Climate Model [64.467612647225]
We find a third intermediate stable state in one of the two climate models we consider.
The combination of our approaches allows to identify how the negative feedback of ocean heat transport and entropy production drastically change the topography of Earth's climate.
arXiv Detail & Related papers (2020-10-20T15:31:38Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.