Tracking Magnetic Fields
• A Field Guide to the Magnetic Solar System
• The Herky-Jerky Weirdness of Earth’s Magnetic Field
• Habitability and the Evolution of Life Under Our Magnetic Shield
• Modeling Earth’s Ever-Shifting Magnetism
• Do Uranus’s Moons Have Subsurface Oceans?
• Measuring Massive Magnetic Meteorites
• A Robust Proxy for Geomagnetic Reversal Rates in Deep Time
Reimagining the Geosciences
• An Unfought Geoscience Battle in U.S. Prisons
• The Two-Year On-Ramp
• Ten Steps to Protect BIPOC Scholars in the Field
• Reframing the Language of Retreat
• Accessibility and Fieldwork in the Time of Coronavirus
• Mentorship During a Pandemic: Transitions from Lab and Sea to Virtual
• The Challenges of Fieldwork for LGBTQ+ Geoscientists
• Perspectives on Parenting While Researching (During a Pandemic)
• Students Learn New Skills with Scientist-in-Training Programs
• Collaborative Graduate Student Training in a Virtual World
• A Pandemic Pivot in Earth Science Outreach and Education
• Opportunities and Challenges of Virtual Meetings
• Shaping the Future of Science
Studying the Critical Zone
• Critical Zone Science Comes of Age
• Critical Agents of Change at Earth’s Surface
• Life Teems Below the Surface
• Linking Critical Zone Water Storage and Ecosystems
• Soil Signals Tell of Landscape Disturbances
• Demystifying Critical Zone Science to Make It More Inclusive
• Next Steps for the Critical Zone
Bringing Satellite Observations Down to Earth
• Satellite Sleuthing Detects Underwater Eruptions
• Earth Observations Inform Cities’ Operations and Planning
• Eyes in the Sky Improve Pollen Tracking
• AquaSat Gives Water Quality Researchers New Eyes in the Sky
• Five Things Spy Satellites Have Taught Us About Earth
• Bringing Satellite Observations Down to Earth
The Rise of Machine Learning
• Earth System Modeling Must Become More Energy Efficient
• Weathering Environmental Change Through Advances in AI
• Are Cosmic Rays a Key to Forecasting Volcanic Eruptions?
• Combining AI and Analog Forecasting to Predict Extreme Weather
• How Machine Learning Redraws the Map of Ocean Ecosystems
• Teaching Machines to Detect Climate Extremes
• The Rise of Machine Learning
Revealing Earth’s Secrets Under Pressure
• Earth’s Core Is in the Hot Seat
• Reflecting on a Half Century of Mineral and Rock Physics at AGU
• Remaking a Planet One Atom at a Time
• Venus Exploration Starts in the Lab
• A Dive into the Deep Earth
Making Geosciences Antiracist
• Geoscience Commits to Racial Justice. Now We’ve Got Work to Do
• Deep Biases Prevent Diverse Talent from Advancing
• What’s in a Seminar?
• Scientific Meetings for All
• Promoting Racial Diversity in Geoscience Through Transparency
• Laying Proper Foundations for Diversity in the Geosciences
• #GeoGRExit: Why Geosciences Programs Are Dropping the GRE
• AGU’s Bridge Program Creates Opportunities for Underrepresented Students
The Carbon Cycle: A Balancing Act
• The Future of the Carbon Cycle in a Changing Climate
• Microbial Influences on Subduction Zone Carbon Cycling
• Basalts Turn Carbon into Stone for Permanent Storage
• Mountain Streams Exhale More Than Their Share of CO2
• A Whole World View
Lightning Science Strikes
• Lightning Research Flashes Forward
• Planetary Lightning: Same Physics, Distant Worlds
• Studying Earth’s Double Electrical Heartbeat
• Catching Elves in Argentina
• Returning Lightning Data to the Cloud
• Understanding High-Energy Physics in Earth’s Atmosphere
• Mapping Lightning Strikes from Space
• Investigating the Spark
Earth Day 2020
• Eight Lessons from COVID-19 to Guide Our Climate Response
• How to Turn Our Cities Into Treetopias
• Basalts Turn Carbon into Stone for Permanent Storage
• Shaping Water Management with Planetary Boundaries
• How Financial Markets Can Grow More Climate Savvy
• A Tribe’s Uphill Battle Against Climate Change
• Photography Focuses on Sea Level Rise and Eroding Communities
Geoscience During COVID-19
• The Seismic Hush of the Coronavirus
• Accessibility and Fieldwork in the Time of Coronavirus
• Will COVID’s Cleaner Skies Muddy Climate Models?
• When Natural Disasters Cross the Path of COVID-19
• Six Ways Satellites Tracked COVID-19
• How COVID-19 Is Affecting Undergraduate Research Experiences
• How Routine Monitors Weather the Pandemic Storm
• Fieldwork in the Experimental Lakes Area Adapts to COVID-19
• Geoscientists Help Map the Pandemic
• The Coronavirus Hurts Some of Science’s Most Vulnerable
• Geohealth: Science’s First Responders
• Atmospheric Scientists Show Resilience in the Face of Lockdowns
• Coronavirus Lockdown Brings Clean Air to Spanish Cities
• During a Pandemic, Is Oceangoing Research Safe?
• Air Pollution Can Worsen the Death Rate from COVID-19
A Decade of Science Since Deepwater Horizon
• Modeling Under Pressure
• Deepwater Horizon and the Rise of the Omics
• Why Sunlight Matters for Marine Oil Spills
• Thirty Years, $500 Million, and a Scientific Mission in the Gulf
• Leveraging Satellite Sensors for Oil Spill Detection
• Deepwater Horizon’s Legacy of Science
Thwaites Glacier
• Diagnosing Thwaites
• What Lies Beneath Is Important for Ice Sheets
• Controlled Explosions Pave the Way for Thwaites Glacier Research
• “Glacial Earthquakes” Spotted for the First Time on Thwaites
• Erin Pettit: Glaciologist, Artist, Mentor
• The Threat at Thwaites
Wildfire Emissions
• Firing Up Climate Models
• What Is Left in the Air After a Wildfire Depends on Exactly What Burned
• A Global Perspective on Wildfires
• Amazon Fires Contribute to Andean Glacier Melting
• Five Environmental Consequences of Australia’s Fires
• Podcast: Discovering Europe’s History Through Its Timbers
• What Do You Get When You Cross a Thunderstorm with a Wildfire?
• Finding Wildfire’s Fingerprint in the Atmosphere
• Wildfire Research in AGU Journals
