Data from a flume investigation using Fiber Optic Distributed Temperature Sensing (FO-DTS), U.S. Geological Survey Geomorphology and Sediment Transport Laboratory, Golden, Colorado, spring 2018

Dates

Publication Date: 2018-09-07
Start Date: 2018-03-12
End Date: 2018-04-27

Citation

Kinzel, P.J., 2018, Data from a flume investigation using Fiber Optic Distributed Temperature Sensing (FO-DTS), U.S. Geological Survey Geomorphology and Sediment Transport Laboratory, Golden, Colorado, spring 2018: U.S. Geological Survey data release, https://doi.org/10.5066/P9N0G43H.

Summary

Evaluating technologies and approaches to detect the infiltration of fines into coarser materials has implications for monitoring the condition of habitat restoration sites. This goal motivated testing the efficacy of Fiber Optic Distributed Temperature Sensing (FO-DTS) as a technique for detecting the infiltration of fine sediment into gravels. Experiments were conducted in a laboratory flume at the USGS Geomorphology and Sediment Transport Laboratory (GSTL) in Golden, Colorado. A 10 meter fiber optic cable was placed in the flume with one half of the cable buried approximately 6 centimeters in a substrate (gravel, sand, and mixtures of the two) along the length of the flume, while the other half was placed at the sediment/water interface. [...]

Summary

Evaluating technologies and approaches to detect the infiltration of fines into coarser materials has implications for monitoring the condition of habitat restoration sites. This goal motivated testing the efficacy of Fiber Optic Distributed Temperature Sensing (FO-DTS) as a technique for detecting the infiltration of fine sediment into gravels. Experiments were conducted in a laboratory flume at the USGS Geomorphology and Sediment Transport Laboratory (GSTL) in Golden, Colorado. A 10 meter fiber optic cable was placed in the flume with one half of the cable buried approximately 6 centimeters in a substrate (gravel, sand, and mixtures of the two) along the length of the flume, while the other half was placed at the sediment/water interface. The gravel had a median grain size of approximately 10 millimeters and the sand 0.6 millimeters. In order to differentiate the halves of the cable we adopted the convention of referring to the cable at the sediment-water interface being located on the left side of the flume and the buried section on the right side. The terms left and right are taken from the viewpoint of an observer facing in the direction of flow in the flume. Water in the tail tank was heated for 12 hours and then the heater was shut off for 12 hours. Water from the tank was circulated through the flume during this cycle and a temperature profile was recorded with a Silixa XT-DTS along the entire length of the FO cable once every minute . This data set contains the results of 6 experiments conducted at GSTL during the spring of 2018. The first experiment is referred to as a "control" wherein both the left and right side of the cable were exposed with no substrate present. A gravel only and sand only substrate were used in experiments 2 and 3 respectively. Experiments 4 through 6 consisted of a mixture of gravel with progressively greater volumes of sand added for each successive experiment. These are referred to as mixture 1, mixture 2, and mixture 3 respectively.

Contacts

Point of Contact :: Paul J Kinzel
Originator :: Paul J Kinzel
Metadata Contact :: Paul J Kinzel
Publisher :: U.S. Geological Survey
Distributor :: U.S. Geological Survey - ScienceBase
USGS Mission Area :: Water Resources
SDC Data Owner :: Office of the Chief Operating Officer

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Figure1_a.jpg “Photograph showing gravel substrate used in experiment”		3.73 MB	image/jpeg
Figure1_b.jpg “Photograph showing sand substrate used in experiment”		1.94 MB	image/jpeg
Figure1_c.jpg “Photograph showing mixed sand/gravel substrate used in experiment”		2.1 MB	image/jpeg
FO-DTS_Experiments.xlsx “Data from FO-DTS experiments”		2.29 MB	application/vnd.openxmlformats-officedocument.spreadsheetml.sheet
FO-DTS_Experiments_meta.xml Original FGDC Metadata	View	27.84 KB	application/fgdc+xml

Material Request Instructions

For any questions regarding these data, please contact: Paul Kinzel - pjkinzel@usgs.gov, 303-278-7941
Geomorphology and Sediment Transport Laboratory
United States Geological Survey
4620 Technology Drive, Suite 400 Golden, CO 80403

Purpose

The efficacy of Fiber Optic Distributed Temperature Sensing (DTS) as a technique for detecting the infiltration of fine sediment into gravels was investigated in a laboratory flume. Evaluating technologies and approaches to detect the infiltration of fines into coarser materials has implications for monitoring the condition of habitat restoration sites.

Data from a flume investigation using Fiber Optic Distributed Temperature Sensing (FO-DTS), U.S. Geological Survey Geomorphology and Sediment Transport Laboratory, Golden, Colorado, spring 2018

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