Investigating High-Latitude Permafrost Carbon Dynamics with Artificial Intelligence and Earth System Data Assimilation
It is well-established that positive feedbacks between permafrost degradation and the release of soil carbon into the atmosphere impacts land-atmosphere interactions, disrupts the global carbon cycle, and accelerates climate change. The widespread distribution of thawing permafrost is causing a casc...
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Authorea, Inc.
2023
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| Online Access: | http://dx.doi.org/10.22541/essoar.170355053.35677457/v1 |
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crwinnower:10.22541/essoar.170355053.35677457/v1 2024-06-02T08:12:55+00:00 Investigating High-Latitude Permafrost Carbon Dynamics with Artificial Intelligence and Earth System Data Assimilation Gay, Bradley A Züfle, Andreas E Armstrong, Amanda H Pastick, Neal J Watts, Jennifer D Dirmeyer, Paul A Miner, Kimberley R Wessels, Konrad J Qu, John J Miller, Charles E 2023 http://dx.doi.org/10.22541/essoar.170355053.35677457/v1 unknown Authorea, Inc. posted-content 2023 crwinnower https://doi.org/10.22541/essoar.170355053.35677457/v1 2024-05-07T14:19:21Z It is well-established that positive feedbacks between permafrost degradation and the release of soil carbon into the atmosphere impacts land-atmosphere interactions, disrupts the global carbon cycle, and accelerates climate change. The widespread distribution of thawing permafrost is causing a cascade of geophysical and biochemical disturbances with global impact. Currently, few earth system models account for permafrost carbon feedback mechanisms. This research identifies, interprets, and explains the feedback sensitivities attributed to permafrost degradation and terrestrial carbon cycling imbalance with in situ and flux tower measurements, remote sensing observations, process-based modeling simulations, and deep learning architecture. We defined and formulated high-resolution polymodal datasets with multitemporal extents and hyperspatiospectral fidelity (i.e., 12.4 million parameters with 13.1 million in situ data points, 2.84 billion ground-controlled remotely sensed data points, and 36.58 million model-based simulation outputs to computationally reflect the state space of the earth system), simulated the non-linear feedback mechanisms attributed to permafrost degradation and carbon cycle perturbation across Alaska with a process-constrained deep learning architecture composed of cascading stacks of convolutionally layered memory-encoded recurrent neural networks (i.e., GeoCryoAI), and interpreted historical and future emulations of freeze-thaw dynamics and the permafrost carbon feedback with a suite of evaluation and performance metrics (e.g., cross-entropic loss, root-mean-square deviation, accuracy). This framework introduces ecological memory components and effectively learns subtle spatiotemporal covariate complexities in high-latitude ecosystems by emulating permafrost degradation and carbon flux dynamics across Alaska with high precision and minimal loss (RMSE: 1.007cm, 0.694nmolCH4m-2s-1, 0.213µmolCO2m-2s-1). This methodology and findings offer significant insight about the permafrost carbon ... Other/Unknown Material permafrost Alaska The Winnower |
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Open Polar |
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The Winnower |
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crwinnower |
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unknown |
| description |
It is well-established that positive feedbacks between permafrost degradation and the release of soil carbon into the atmosphere impacts land-atmosphere interactions, disrupts the global carbon cycle, and accelerates climate change. The widespread distribution of thawing permafrost is causing a cascade of geophysical and biochemical disturbances with global impact. Currently, few earth system models account for permafrost carbon feedback mechanisms. This research identifies, interprets, and explains the feedback sensitivities attributed to permafrost degradation and terrestrial carbon cycling imbalance with in situ and flux tower measurements, remote sensing observations, process-based modeling simulations, and deep learning architecture. We defined and formulated high-resolution polymodal datasets with multitemporal extents and hyperspatiospectral fidelity (i.e., 12.4 million parameters with 13.1 million in situ data points, 2.84 billion ground-controlled remotely sensed data points, and 36.58 million model-based simulation outputs to computationally reflect the state space of the earth system), simulated the non-linear feedback mechanisms attributed to permafrost degradation and carbon cycle perturbation across Alaska with a process-constrained deep learning architecture composed of cascading stacks of convolutionally layered memory-encoded recurrent neural networks (i.e., GeoCryoAI), and interpreted historical and future emulations of freeze-thaw dynamics and the permafrost carbon feedback with a suite of evaluation and performance metrics (e.g., cross-entropic loss, root-mean-square deviation, accuracy). This framework introduces ecological memory components and effectively learns subtle spatiotemporal covariate complexities in high-latitude ecosystems by emulating permafrost degradation and carbon flux dynamics across Alaska with high precision and minimal loss (RMSE: 1.007cm, 0.694nmolCH4m-2s-1, 0.213µmolCO2m-2s-1). This methodology and findings offer significant insight about the permafrost carbon ... |
| format |
Other/Unknown Material |
| author |
Gay, Bradley A Züfle, Andreas E Armstrong, Amanda H Pastick, Neal J Watts, Jennifer D Dirmeyer, Paul A Miner, Kimberley R Wessels, Konrad J Qu, John J Miller, Charles E |
| spellingShingle |
Gay, Bradley A Züfle, Andreas E Armstrong, Amanda H Pastick, Neal J Watts, Jennifer D Dirmeyer, Paul A Miner, Kimberley R Wessels, Konrad J Qu, John J Miller, Charles E Investigating High-Latitude Permafrost Carbon Dynamics with Artificial Intelligence and Earth System Data Assimilation |
| author_facet |
Gay, Bradley A Züfle, Andreas E Armstrong, Amanda H Pastick, Neal J Watts, Jennifer D Dirmeyer, Paul A Miner, Kimberley R Wessels, Konrad J Qu, John J Miller, Charles E |
| author_sort |
Gay, Bradley A |
| title |
Investigating High-Latitude Permafrost Carbon Dynamics with Artificial Intelligence and Earth System Data Assimilation |
| title_short |
Investigating High-Latitude Permafrost Carbon Dynamics with Artificial Intelligence and Earth System Data Assimilation |
| title_full |
Investigating High-Latitude Permafrost Carbon Dynamics with Artificial Intelligence and Earth System Data Assimilation |
| title_fullStr |
Investigating High-Latitude Permafrost Carbon Dynamics with Artificial Intelligence and Earth System Data Assimilation |
| title_full_unstemmed |
Investigating High-Latitude Permafrost Carbon Dynamics with Artificial Intelligence and Earth System Data Assimilation |
| title_sort |
investigating high-latitude permafrost carbon dynamics with artificial intelligence and earth system data assimilation |
| publisher |
Authorea, Inc. |
| publishDate |
2023 |
| url |
http://dx.doi.org/10.22541/essoar.170355053.35677457/v1 |
| genre |
permafrost Alaska |
| genre_facet |
permafrost Alaska |
| op_doi |
https://doi.org/10.22541/essoar.170355053.35677457/v1 |
| _version_ |
1800759501725368320 |