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Revealing our dynamic landscape through new high-resolution topographic data

ΒιΆΉΣ³»­ Bureau of Mines and Geology’s regional-scale lidar mapping provides novel insights into earthquake, flood and glacial history

Image of river basin developed through airborne lidar mapping technology

Lidar mapping of the Carson River near Dayton, ΒιΆΉΣ³»­, indicates flood history and helps inform planning by accurately defining what land could be inundated when flood waters rise.

Revealing our dynamic landscape through new high-resolution topographic data

ΒιΆΉΣ³»­ Bureau of Mines and Geology’s regional-scale lidar mapping provides novel insights into earthquake, flood and glacial history

Lidar mapping of the Carson River near Dayton, ΒιΆΉΣ³»­, indicates flood history and helps inform planning by accurately defining what land could be inundated when flood waters rise.

Image of river basin developed through airborne lidar mapping technology

Lidar mapping of the Carson River near Dayton, ΒιΆΉΣ³»­, indicates flood history and helps inform planning by accurately defining what land could be inundated when flood waters rise.

If you could pull back the vegetation and man-made structures and have a high definition view from above, what would you learn about the landscapes and valleys below? A lot, it turns out.

A significant recent effort by the at the ΒιΆΉΣ³»­ and the United States Geological Survey (USGS) utilized airborne lidar technology to produce high-resolution topographic maps of the Reno-Sparks-Carson City area. The data will benefit a number of in-progress ΒιΆΉΣ³»­ Bureau of Mines and Geology studies to understand earthquake and flood hazards, as well as natural resources.

Preliminary project findings include:

  • The discovery of more than two dozen, previously unknown earthquake faults, plus better understanding of many previously identified faults.
  • The extent of large and geologically young landslide deposits at the mouth of Ophir Creek in Washoe Valley.
  • Evidence for a large lake during the end of the last ice age in Lemon Valley.
  • The size and geologic history of ice-aged glaciers on Mount Rose.
Geologic lidar mapping image of ice-aged glacier

From Reno’s Bare Earth: Below the Neon, this image shows the path of ice-aged glaciers on Mount Rose with glacier moraines marked in pink and crossing ΒιΆΉΣ³»­ State Route 431.

Using Light Detection and Ranging technology, or lidar, the project collected data by bouncing light pulses off the surface of the earth. The result is a high-resolution, three-dimensional topographic map that allows improved identification of geologic features such as flood plains, glacial deposits and earthquake faults. This can also support the assessment of ecological systems, infrastructure planning and the identification of geothermal reserves to support clean-energy production.

A Collaborative Effort

Under the direction of ΒιΆΉΣ³»­ Bureau of Mines and Geology Director Jim Faulds and spearheaded by faculty member and Geologic Mapping Specialist Seth Dee, the project received initial funding through the USGS and Research & Innovation at the ΒιΆΉΣ³»­.

The many significant implications of this high quality dataset were quickly evident. Several entities and agencies recognized this potential and extended financial support to allow the lidar data to be expanded in areal coverage and acquired at a greater level of resolution. The Washoe County Regional Basemap Committee, the U.S. Forest Service, Lyon County, Storey County, City of Reno, City of Sparks and NV Energy are among those that provided additional support for the project and are now using the data for planning or hazard mitigation.

Exploring ΒιΆΉΣ³»­’s Wide-Open Spaces

Through the USGS’s 3D Elevation Program (3DEP), lidar mapping has been completed in many other states, though typically concentrated in urban or well-populated settings. The USGS 3DEP program requires a 1:1 funding match, which is easier to obtain for more populated areas with large amounts of private land. In the wide-open spaces of ΒιΆΉΣ³»­, where approximately 86 percent of the state is owned by the federal government, it is more difficult to obtain this match and thus lidar acquisitions have progressed more slowly compared to other regions. This presents opportunities for future work in the region and adds the element of discovery to nearly any lidar acquisition in the state. 

“ΒιΆΉΣ³»­ is still the wild west,” said Rachel Micander, a geographic information system analyst in the ΒιΆΉΣ³»­ Bureau of Mines and Geology. “There’s a lot going on in this state from the geographic and geologic perspectives. ΒιΆΉΣ³»­ is the second most mountainous state and the state with the most named mountain ranges.”

“ΒιΆΉΣ³»­ is still relatively unexplored; we are still figuring it out,” said Faulds. “We don’t know as much about our flood hazards compared to many other parts of the country, and we continue to find new earthquake faults. There’s a whole element of discovery here that isn’t happening in other areas.”

Seth Dee remarked that the new lidar data acquisition for the area “is the equivalent of getting a much better lens on a telescope. The best topography widely available 20 years ago was from contours every 40 feet on a topographic map. With lidar we get a grid of data with elevation measurements spaced at least every meter (~3 ft), accurate to 10 cm (4 inches) vertically. We can now quickly map sub-meter geologic features, in addition to countless applications in other disciplines.”

Understanding Hazards

It’s well known that ΒιΆΉΣ³»­ is a seismically active state. Faulds noted that understanding the geologic setting and finding new faults should not be a cause for concern, but rather recognized as valuable information in the effort to monitor seismic activity, mitigate hazards, aid in the planning of infrastructure and development, and guide future geologic exploration.

“These data can help us focus in on where to conduct our geologic work,” he said. “We see there is a fault scarp at a certain location; we now know we need to go there to learn more.”

The mapping data also informs flood planning by accurately defining what land could be inundated when flood waters rise. The Reno’s Bare Earth: Below the Neon online story map, which was developed by Micander and her fellow geographic information system analyst, Irene Seelye, shows the example of the Carson River near Dayton, ΒιΆΉΣ³»­.

The ΒιΆΉΣ³»­ Bureau of Mines and Geology team is understandably proud of the project and deeply appreciative of the support and engagement behind it.

“This demonstrates the University’s public service role and the role of statewide programs that are out there doing things for the public good,” said Faulds.  “This is a great example of partnership and what we strive to do to achieve really broad benefits.”

For more information about the ΒιΆΉΣ³»­ Bureau of Mines and Geology visit .

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