HelioWebJacob Bortnik
flowchart
A[Jacob Bortnik]
AC["Associated Concepts (25)"]
AW["Authored Works (52)"]
CA["Linked Co-Authors (90)"]
CI["Linked Collaborating Institutions (52)"]
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click AW "#authored-works"
click CA "#co-authors"
click CI "#collaborating-institutions"
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- ORCiD
- https://orcid.org/0000-0001-8811-8836
- OpenAlex ID
- https://openalex.org/A5011734134 (API record)
Associated Concepts [?]
- Physics
- Quantum mechanics
- Nuclear physics
- Magnetic field
- Geology
- Plasma
- Magnetosphere
- Geophysics
- Electron
- Computational physics
- Astronomy
- Van Allen radiation belt
- Optics
- Geography
- Engineering
- Van Allen Probes
- Computer science
- Meteorology
- Art
- Chemistry
- Mathematics
- Atomic physics
- Organic chemistry
- Literature
- Chorus
Authored Works
sorted by decreasing year, and then by display-name
- Upper Limit of Outer Radiation Belt Electron Acceleration by Whistler-Mode Chorus Waves
- Title: Forests for Forests: Combining vegetation indices and solar-induced chlorophyll fluorescence in random forest models improves gross primary production prediction in the Boreal Forest
- The Response of Equivalent Ionospheric Currents to the External Drivers via Spatiotemporal Prediction by Neural Network
- The Machine Learning application to the Spatiotemporal Prediction of Equivalent Ionospheric Currents
- Temporal and spatial evolution of chorus waves modeled by an artificial neural network
- Statistical Analysis of Plasmaspheric Erosion and Refilling - Machine Learning Approach
- Spatial distributions of EMIC (Electromagnetic Ion Cyclotron) waves and characteristics of rising tone EMIC waves in the inner magnetosphere using Arase observations
- Predicting SWARM plasma bubbles via Machine Learning
- Predicting Equatorial Electron Flux Measurements from low-Earth-orbit
- Opening the Black Box of the Radiation Belt Machine Learning Model
- Nonresonant scattering of relativistic electrons by electromagnetic ion cyclotron waves in Earth's radiation belts
- Multiple conjugate observations of magnetospheric fast flow bursts using THEMIS observations
- Modeling Ring Current Proton Fluxes Using Artificial Neural Network and Van Allen Probe Measurements
- Hiss in the plasmasphere and plumes: Global distribution from machine learning techniques and their effects on the loss of energetic electrons
- Global distribution and evolution of chorus waves modeled by an artificial neural network
- Excitation of Electron Acoustic Waves by electron beams in nonlinear Landau resonance with Whistler Waves
- Ensemble Modeling of Radiation Belt Electron Acceleration by Chorus Waves: Dependence on Key Input Parameters
- Enhanced Radiation Levels at Aviation Altitudes and its relationship to the Van Allen radiation belts.
- Dynamics of Plasmaspheric Ions Modeled by a Neural Network
- Controlling Factors of Microburst Scale Sizes Induced by Chorus Waves: from Microscopic Wave-Particle Interaction to Macroscopic L-MLT Dependence
- Analyzing Pyrocumulonimbus Lightning Activity in British Columbia Summer 2021
- Analysis of Electron Precipitation and Ionospheric Density Enhancements due to Hiss Using Incoherent Scatter Radar and Arase Observations
- Analysis of Dynamics of Ions in the Plasmasphere Using a Machine Learning Model
- Active Control of the Radiation Belt Particle Populations with Ionospheric Amplification of VLF Waves
- A statistical study of the behaviors of energetic ions (H+, He+, and O+) in the inner magnetosphere using the Arase satellite observations
- A Test of Electron Precipitation Models Using Incoherent Scatter Radar and Van Allen Probes Observations
- Unraveling the formation region, frequency and bandwidth of chorus spectral gaps
- Unraveling the drivers of electron loss in the Earths inner radiation belt
- Understanding the interconnected space weather system: The Convergence Hub for the Exploration of Space Science (CHESS) project and workshop
- Towards Event-Based Modeling of Earths Radiation Belt Electrons
- The response of ionospheric currents to different types of magnetospheric fast flow bursts using THEMIS observations
- Ten ways to apply machine learning in the Earth and Space Sciences
- Statistical Investigation of the Frequency Dependence of the Chorus Source Mechanism of Plasmaspheric Hiss
- Statistical Investigation of the Erosion and Refilling of the Plasmasphere - Machine Learning Based Approach
- Sensitivity Analysis of Modeling Radiation Belt Electron Acceleration and Decay After Geomagnetic Storms
- Propagation of Minimum-B Pockets Originated Chorus Waves
- Physical and ecophysiological controls on the relationship between solar-induced chlorophyll fluorescence and gross primary productivity across diurnal and seasonal scales in the boreal forest
- Nonlinear precipitation blocking of relativistic electrons by large amplitude EMIC waves
- Modeling the dynamic variability of sub-relativistic outer radiation belt electron fluxes using machine learning
- Machine learning based discovery of missing physical processes in radiation belt modeling
- Investigation of the response of the ionospheric current to upstream solar wind and magnetospheric activity: a neural network approach
- Implementation of Recurrent Neural Network in Constructing Global Electron Density in the Earths Magnetosphere
- Global Survey of Electron Precipitation due to Whistler-Mode Waves in the Earths Inner Magnetosphere
- Forecasting Radiation Belt Electron Flux Using Machine-learned Parameters for Radial Transport Equation
- First Results from VIPER The VLF Trans-Ionospheric Propagation Experiment Rocket Campaign
- Exploring the Potential of Unsupervised Machine Learning and Satellite Measurements to Derive Climate Zones in the USA
- Detecting Tsunami-related Gravity Waves in Earth's Ionosphere with Convolutional Neural Networks
- Data-driven discovery of the governing equations describing radiation belt dynamics
- Comparing POES and Van Allen Probes electron flux measurements during magnetic conjunctions
- A statistical study of EMIC (Electromagnetic Ion Cyclotron) wave-particle interactions in the magnetosphere using Arase observations
- A Statistical Analysis of the Erosion and Refilling of the Plasmasphere Using Neural Network-Based DEN3D Model
- A Neural Network Based Model of the Relativistic Electrons in the Outer Radiation Belt
Linked Co-Authors
- A. Kumamoto
- A. W. Smith
- Adam Kellerman
- Alexander Drozdov
- Alexander Norton
- Allison Jaynes
- Andrew J. Maguire
- C. Forsyth
- Chae‐Woo Jun
- Chao Yue
- Chih‐Ping Wang
- Chrystal Moser
- D. Malaspina
- David R. Bowling
- Donglai Ma
- E. R. Sánchez
- Enrico Camporeale
- Ercha Aa
- F. Tsuchiya
- G. B. Hospodarsky
- G. D. Reeves
- H. K. Connor
- Harlan E. Spence
- Homayon Aryan
- Hong Zhao
- I. Shinohara
- J Bernard Blake
- J. C. Green
- J. M. Albert
- J. M. Weygand
- J. Stutz
- J. W. Bonnell
- Jerry Goldstein
- Jinxing Li
- Joseph Hughes
- K. Keika
- K. Zhang
- Karthik Venkataramani
- Katja Großmann
- Kazushi Asamura
- L. Capannolo
- L. G. Ozeke
- L. M. Kistler
- L. Olifer
- L. R. Lyons
- Laura H. Thapa
- M. B. Cohen
- M. Gołkowski
- M. Kitahara
- M. Samara
- Man Hua
- Naomi Maruyama
- Nicholas C. Parazoo
- Nigel P. Meredith
- Oleksiy Agapitov
- P. A. Bernhardt
- Pablo Reyes
- Piyush M. Mehta
- Q. Ma
- R. E. Denton
- R. H. Varney
- Richard B. Horne
- Rong Fu
- Ryan McGranaghan
- S. G. Claudepierre
- S. R. Kaeppler
- S. Tian
- Sandeep Kumar
- Satoko Nakamura
- Satoshi Kasahara
- Sheng Huang
- Shoya Matsuda
- Sunny Wing-Yee Tam
- Tomoaki Hori
- Troy S. Magney
- Vassilis Angelopoulos
- W. Kent Tobiska
- W. Li
- Wei Xu
- X. Cao
- Xiangning Chu
- Xiaochen Shen
- Xiaofei Shi
- Xiaojia Zhang
- Xin An
- Yasumasa Kasaba
- Yoshiya Kasahara
- Yoshizumi Miyoshi
- Zoe Pierrat
- А. V. Artemyev
Linked Collaborating Institutions
- Aerospace Corporation, California
- Atmospheric & Space Technology Research Associates (ASTRA)
- Auburn University, Alabama
- Beijing University of Aeronautics and Astronautics, China
- Boston University, Massachusetts
- British Antarctic Survey
- Catholic University, Washington DC
- Clemson University, South Carolina
- Colorado School of Mines
- Dartmouth College, New Hampshire
- Direction des Applications Militaires, Ile-de-France
- Georgia Institute of Technology
- Haystack Observatory
- JAXA Japan Aerospace Exploration Agency
- JAXA, Institute of Space and Astronautical Science
- Jet Propulsion Laboratory
- Kanazawa University, Japan
- Kyoto University, Japan
- Los Alamos National Laboratory, New Mexico
- NASA Goddard Space Flight Center, Maryland
- Nagoya University, Japan
- Nagoya University, Solar Terrestrial Environment Laboratory
- National Cheng Kung University, Taiwan
- Northwest Agriculture and Forestry University, Yangling
- Osaka University, Japan
- Peking University, China
- RAS, Institute of Applied Physics, Novgorod
- RAS, Space Research Institute, Moscow
- Ruprecht-Karls University of Heidelberg, Germany
- Sapienza University, Rome, Italy
- Southwest Research Institute, Texas
- Stanford Research Institute, California
- Stanford University, California
- Tohoku University, Japan
- University College London, Mullard Space Science Laboratory
- University College London, UK
- University of Alaska, Fairbanks
- University of Alberta, Canada
- University of Calgary, Canada
- University of California, Berkeley
- University of California, Davis
- University of California, Los Angeles
- University of Colorado, Boulder
- University of Colorado, Boulder, Laboratory for Atmospheric and Space Physics
- University of Colorado, Denver
- University of Iowa
- University of New Hampshire
- University of Saskatchewan, Canada
- University of Sheffield, UK
- University of Tokyo, Japan
- University of Utah
- Wuhan University, China
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