The CLIM-MET stations are meteorological/geological stations that are designed to function in remote areas for long periods of time without human intervention. These stations measure meteorological and wind-erosion parameters under varying climatic and land-use conditions to detect and describe ongoing landscape changes. Combined with historic and other data, CLIM-MET data can provide inputs into regional climatic models that describe how the Southwest will respond to future climatic conditions.

These CLIM-MET stations are meteorological/geological stations that is designed to function in remote areas for long periods of time without human intervention. These stations measure meteorological and wind-erosion parameters under varying climatic and land-use conditions to detect and describe ongoing landscape changes. These data represent multiple years of local detailed landscape and environmental change observations. These data were collected at several discrete locations within southeastern California and in Mojave National Preserve, California, from 31 July 2016 to 23 March 2022. These data were collected by U.S. Geological Survey researchers utilizing site visits and automated data collection data loggers. These data can be used to inform studies of local and regional landscape change as well as to provide input into regional climatic models.

These CLIM-MET stations are meteorological/geological stations that is designed to function in remote areas for long periods of time without human intervention. These stations measure meteorological and wind-erosion parameters under varying climatic and land-use conditions to detect and describe ongoing landscape changes. These data represent multiple years of local detailed landscape and environmental change observations. These data were collected at several discrete locations within southeastern California and in Mojave National Preserve, California, from 31 July 2016 to 23 March 2022. These data were collected by U.S. Geological Survey researchers utilizing site visits and automated data collection data loggers. These data can be used to inform studies of local and regional landscape change as well as to provide input into regional climatic models.

These CLIM-MET stations are meteorological/geological stations that is designed to function in remote areas for long periods of time without human intervention. These stations measure meteorological and wind-erosion parameters under varying climatic and land-use conditions to detect and describe ongoing landscape changes. These data represent multiple years of local detailed landscape and environmental change observations. These data were collected in and close to Canyonlands National Park, Utah from 1 August 2016 to 31 December 2022. These data were collected by U.S. Geological Survey researchers utilizing site visits and automated data collection data loggers. These data can be used to inform studies of local and regional landscape change as well as to provide input into regional climatic models.

These CLIM-MET stations are meteorological/geological stations that is designed to function in remote areas for long periods of time without human intervention. These stations measure meteorological and wind-erosion parameters under varying climatic and land-use conditions to detect and describe ongoing landscape changes. These data represent multiple years of local detailed landscape and environmental change observations. These data were collected in and close to Canyonlands National Park, Utah from 1 August 2016 to 31 December 2022. These data were collected by U.S. Geological Survey researchers utilizing site visits and automated data collection data loggers. These data can be used to inform studies of local and regional landscape change as well as to provide input into regional climatic models.

These data were compiled from six automated weather stations that together provide several points in the meteorological record across a latitudinal and elevational gradient in southeastern Utah. Recorded data from these weather stations are associated with several different studies. Meteorological data are important for quantifying short term weather events as well as longer term climate trends. Spatially separated precipitation gauges allow for better characterization of the heterogeneity of precipitation events. These data were collected from six locations running from north to south in southeast Utah. All of the weather stations use Campbell Scientific data loggers and data are collected daily via telecommunications and stored on servers at the U.S Geological Survey-Southwest Biological Science Center office in Moab UT. Data, station, and sensor function are checked periodically by trained U.S. Geological Survey (USGS) personnel. The PPCUT_Wx station was set up in 2005 by USGS personnel and it is located adjacent to Porcupine Canyon at the base of Parriott Mesa near Castle Valley, UT. The KERBY_Wx station was set up in 2009 by USGS personnel and it is located at the east end of Kerby Lane near Moab, UT. Both the PPCUT_Wx and KERBY_Wx stations are part of a larger Department of Energy funded project concerning climate change on dryland systems (see Cross References). The GOLDB_Wx station was set up in 2010 by US Forest Service personnel for use by avalanche forecasters and winter recreationists. It is located at the south end of the Gold Basin Rd in the La Sal Mountains near Moab, UT. The LSL_Wx station was originally set up in 1991 by US Forest Service personnel for use by avalanche forecasters and winter recreationists, although only data from 2009 until present are included in this data set. The station is located on a ridge below Mount Laurel in the La Sal Mountains near Moab, UT. The farthest station to the south included in this data release is EDGUT_Wx. The EDGUT_Wx station was set up in 2015 by USGS personnel and it is located at the EDGE site near Needles District of Canyonlands National Park, Monticello, UT. The EDGUT_Wx station is part of a larger study on the effects of drought on dry land systems (Hoover et al. 2021). These data can be used to understand past meteorological events as well as longer term climatic trends within southeastern Utah.

These data were compiled from six automated weather stations that together provide several points in the meteorological record across a latitudinal and elevational gradient in southeastern Utah. Recorded data from these weather stations are associated with several different studies. Meteorological data are important for quantifying short term weather events as well as longer term climate trends. Spatially separated precipitation gauges allow for better characterization of the heterogeneity of precipitation events. These data were collected from six locations running from north to south in southeast Utah. All of the weather stations use Campbell Scientific data loggers and data are collected daily via telecommunications and stored on servers at the U.S Geological Survey-Southwest Biological Science Center office in Moab UT. Data, station, and sensor function are checked periodically by trained U.S. Geological Survey (USGS) personnel. The PPCUT_Wx station was set up in 2005 by USGS personnel and it is located adjacent to Porcupine Canyon at the base of Parriott Mesa near Castle Valley, UT. The KERBY_Wx station was set up in 2009 by USGS personnel and it is located at the east end of Kerby Lane near Moab, UT. Both the PPCUT_Wx and KERBY_Wx stations are part of a larger Department of Energy funded project concerning climate change on dryland systems (see Cross References). The GOLDB_Wx station was set up in 2010 by US Forest Service personnel for use by avalanche forecasters and winter recreationists. It is located at the south end of the Gold Basin Rd in the La Sal Mountains near Moab, UT. The LSL_Wx station was originally set up in 1991 by US Forest Service personnel for use by avalanche forecasters and winter recreationists, although only data from 2009 until present are included in this data set. The station is located on a ridge below Mount Laurel in the La Sal Mountains near Moab, UT. The farthest station to the south included in this data release is EDGUT_Wx. The EDGUT_Wx station was set up in 2015 by USGS personnel and it is located at the EDGE site near Needles District of Canyonlands National Park, Monticello, UT. The EDGUT_Wx station is part of a larger study on the effects of drought on dry land systems (Hoover et al. 2021). These data can be used to understand past meteorological events as well as longer term climatic trends within southeastern Utah.

This dataset provides sub-daily, high-resolution, climate data inputs including temperature, precipitation, near surface specific humidity, incoming short-wave radiation, and near-surface wind speed over 11 states of the western USA. States included are Arizona, California, Colorado, Idaho, Montana, Nevada, New Mexico, Oregon, Utah, Washington, and Wyoming. These data were derived for use in the Community Land Model (CLM v4.5) and are at 3-hourly temporal and 4 x 4 km spatial resolutions for the 1979 through 2015 time period. The source for observational data was METDATA (now called GRIDMET), at a daily resolution. Modeling efforts using these data estimated annual carbon stocks, fluxes, and productivity across the western United States.

Our goal for this work is to place better constraints on aeolian atmospheric-surface interactions through long-term monitoring of an active, bi-modal dune field located near Grand Falls, Arizona. This dune field has been monitored since 2013 by the USGS, and data from each collection year are released as USGS Data Release products. Data described here is the meteorological component of the Imagery, sediment collection, photogrammetry, and meteorological data from April 2023 to July 2023, Grand Falls Dune Field, Arizona Data Release. Our instruments are set up near an active ripple field in the Grand Falls Dune Field. The instrument array includes a meteorological weather station that records temperature, barometric pressure, relative humidity, wind direction, wind speed, solar radiation, and precipitation every 15 minutes , three BlazeVideo cameras situated surrounding the ripple field that take images every 10 minutes to capture ripple migration, and a suite of passive sediment catchers. In addition to the deployed instruments, each time we visit the field site we also image the ripple field using a Nikon D750 (35 mm) camera. This data is processed using the software Agisoft Metashape Professional to create digital elevation models of the ripple field.

Our goal for this work is to place better constraints on aeolian atmospheric-surface interactions through long-term monitoring of an active, bi-modal dune field located near Grand Falls, Arizona. This dune field has been monitored since 2013 by the USGS, and data from each collection year are released as USGS Data Release products. Data described here is the meteorological component of the Imagery, sediment collection, photogrammetry, and meteorological data from April 2023 to July 2023, Grand Falls Dune Field, Arizona Data Release. Our instruments are set up near an active ripple field in the Grand Falls Dune Field. The instrument array includes a meteorological weather station that records temperature, barometric pressure, relative humidity, wind direction, wind speed, solar radiation, and precipitation every 15 minutes , three BlazeVideo cameras situated surrounding the ripple field that take images every 10 minutes to capture ripple migration, and a suite of passive sediment catchers. In addition to the deployed instruments, each time we visit the field site we also image the ripple field using a Nikon D750 (35 mm) camera. This data is processed using the software Agisoft Metashape Professional to create digital elevation models of the ripple field.