B33H-07
The University of Utah Urban Undertaking (U4)

Wednesday, 16 December 2015: 15:20
2004 (Moscone West)
John C Lin1, Logan Mitchell1, Ryan Bares2, Daniel L Mendoza3, Ben Fasoli1, David R Bowling4, Maria A. Garcia4, Martin Buchert3, Diane E Pataki3, Erik Crosman3, John Horel3, Douglas Catharine1, Courtenay Strong3 and James R Ehleringer5, (1)University of Utah, Department of Atmospheric Sciences, Salt Lake City, UT, United States, (2)University of Utah, Atmospheric Sciences, Salt Lake City, UT, United States, (3)University of Utah, Salt Lake City, UT, United States, (4)University of Utah, Department of Biology, Salt Lake City, UT, United States, (5)Univ Utah, Salt Lake City, UT, United States
Abstract:
The University of Utah is leading efforts to understand the spatiotemporal patterns in both emissions and concentrations of greenhouse gases (GHG) and criteria pollutants within urban systems. The urbanized corridor in northern Utah along the Wasatch Front, anchored by Salt Lake City, is undergoing rapid population growth that is projected to double in the next few decades. The Wasatch Front offers multiple advantages as an unique “urban laboratory”: urban regions in multiple valleys spanning numerous orders of magnitude in population, each with unique airsheds, well-defined boundary conditions along deserts and tall mountains, strong signals during cold air pool events, seasonal contrasts in pollution, and a legacy of productive partnerships with local stakeholders and governments.

We will show results from GHG measurements from the Wasatch Front, including one of the longest running continuous CO2 records in urban areas. Complementing this record are comprehensive meteorological observations and GHG/pollutant concentrations on mobile platforms: light rail, helicopter, and research vans.

Variations in the GHG and pollutant observations illustrate human behavior and the resulting “urban metabolism” taking place on hourly, weekly, and seasonal cycles, resulting in a coupling between GHG and criteria pollutants. Moreover, these observations illustrate systematic spatial gradients in GHG and pollutant distributions between and within urban areas, traced to underlying gradients in population, energy use, terrain, and land use. Over decadal time scales the observations reveal growth of the “urban dome” due to expanding urban development.

Using numerical models of the atmosphere, we further link concentrations of GHG and air quality-relevant pollutants to underlying emissions at the neighborhood scale as well as urban planning considerations.