Research Topics Include:
The Changing Impact of El Niño on US Winter Temperatures, Geophysical Research Letters. Geophysical Research Letters.. 2012.
Antarctic grounding line mapping from differential satellite radar interferometry. GEOPHYSICAL RESEARCH LETTERS. 38. 2011.
Precipitation response to land subsurface hydrologic processes in atmospheric general circulation model simulations. Journal of Geophysical Research-Atmospheres. 116. 2011.
Subsurface ocean temperature indices for Central-Pacific and Eastern-Pacific types of El Nio and La Nia events. Theoretical and Applied Climatology. 103:337-344.. 2011.
Acceleration of the contribution of the Greenland and Antarctic ice sheets to sea level rise. Geophysical Research Letters. 38. 2011.
Relationships between Extratropical Sea Level Pressure Variations and the Central Pacific and Eastern Pacific Types of ENSO. Journal of Climate. 24:708-720.. 2011.
The Glacier and Land Ice Surface Topography Interferometer: An Airborne Proof-of-Concept Demonstration of High-Precision Ka-Band Single-Pass Elevation Mapping. Ieee Transactions on Geoscience and Remote Sensing. 49:827-842.. 2011.
|Research Lab||Description||Links to more information|
|Hydrology & Climate Research Group and the UCCHM (Famiglietti)||
Jay Famiglietti's Hydrology & Climate Research Group investigates how the water cycle and freshwater resources are being impacted by climate change. The group has developed advanced computer models and use satellite remote sensing to track water availability around the globe. They have pioneered methods using data from NASA’s Gravity Recovery and Climate Experiment (GRACE) mission to identify groundwater depletion in the world’s major aquifers.
|Johnson Research Group||
The Johnson Research Group's primary research goal is to reconstruct past climate (paleoclimate) over the past several glacial-interglacial cycles at seasonal to millennial resolution and to compare these records with other paleoclimate data and model output. Specifically, the lab utilizes geochemical variations preserved in natural calcium carbonate archives such as speleothems (cave deposits) to construct well-dated records of past precipitation, temperature, vegetation, and/or atmospheric circulation in the tropical Indo-Pacific, the Asian monsoon region, and California.
|Magnusdottir Modeling Lab||
The Magnusdottir Modeling Lab focuses on atmospheric and climate dynamics. Gudrun Magnusdottir and her team use observations, as well as a hierarchy of numerical models, to study dynamical processes in the atmosphere and climate variability. The lab investigates feedback mechanisms influencing the unprecedented high-latitude trends in several climate variables over recent decades, tropical-extratropical and troposphere-stratosphere dynamical interactions, and the Intertropical Convergence Zone (ITCZ) -- its variability on different timescales and what controls it in the climate system.
Our goal is to understand the role that ocean dynamics and thermodynamics plays on the climate system.
In particular, we study how phenomena that are well localized in space and time (as tropical cyclones, deep convection, oceanic eddies) globally influence the distribution of energy on our planet. Once those mechanisms and their feedbacks on the climate system are understood, their relevance can be quantified and their role can be parameterized in larger scale models. Our main focus is on the physical characteristics of the ocean and climate system.
|Claudia Pasquero Homepage|
|Primeau Modeling Lab||
The Primeau Research Group is interested in the ocean's role in the climate of the Earth. The ocean plays a determining role in the variability of the climate system on inter-annual to millennial timescales. The lab uses global observations and a hierarchy of ocean models together with advanced computational and mathematical techniques to study the ocean. Francois Primeau and his team’s current research is directed in three broad areas: 1) the surface-to-surface transport and ventilation of ocean water masses; 2) inter-annual to decadal variability of the ocean's wind-driven circulation; and 3) global ocean biogeochemical cycles.
|Randerson Research Group||
The Randerson Research Group seeks to improve our understanding of global change in terrestrial ecosystems. They use remote sensing data, atmospheric trace gas observations, field measurements, and models in new ways to study feedbacks between terrestrial ecosystems and climate.
|Rignot Research Group||
The primary interest of the Rignot Research Group is to understand the interactions of ice and climate, in particular to determine how the ice sheets in Antarctica and Greenland will respond to climate change in the coming century and how they will affect global sea level. Glaciology mixes a variety of scientific and engineering disciplines. Eric Rignot and his team combine satellite remote sensing techniques (imaging radar, laser altimetry, radio echo sounding) airborne geophysical surveys, field surveys (GPR, GPS) and numerical modeling (ice sheet motion and ocean circulation near glaciers). In May 2013, the Rignot Research Group recieved a NASA award for "Ice Velocity Mapping of the Antarctic Ice Sheet," a five-year project funded that will extend funding at UC Irvine for ten years to map ice motion in Antarctica and deliver the products to the science community.
|Velicogna Research Group||
The focus of the Velicogna Research Group is to study the cryospheric components of the water cycle and their response to climate forcing. In particular, Isabella Velicogna and her team study the Greenland and Antarctic ice sheets, their contribution to sea level rise and the evolution of the Arctic water cycle in response to climate change.
|Yu Modeling Lab||
Research Topics Include:
|Zender Research Group||
The Zender Research Group studies the microphysics of trace gas, aerosol, and surface interactions with Earth's radiative, thermodynamic, and chemical processes. Charles Zender and his team develop and refine the representation of these processes to improve climate prediction. Model simulations, combined with lab, field, and satellite data, help them predict and attribute features of climate and climate change. Current research includes mineral dust and carbonaceous aerosols, snow lifecycle and albedo, aerosol impacts on ocean biogeochemistry, wind-driven surface energy/mass exchange, climate-disease links, and super-dooper-big-scale data analysis. The team's aerosol, radiative transfer, and data processing models are freely available and are used by geoscientists world-wide.
The Pritchard Lab's expertise is in next generation climate simulation, focusing on the physics of cloud-related processes in the virtual atmosphere. Mike Pritchard and his team apply a range of traditional and experimental new approaches to study the global atmosphere in a virtual laboratory. These include conventional global climate models and experimental approaches such as "superparameterized" prototype global models.
|Morlighem Research Group|