Comparing conservative and nonconservative tracers in karst and using them to estimate flow path geometry

Andrew J. Luhmann; Matthew D. Covington; Scott C. Alexander; Su Yi Chai; Benjamin F. Schwartz; Joel T. Groten; E. Calvin Alexander

doi:10.1016/j.jhydrol.2012.04.044

Comparing conservative and nonconservative tracers in karst and using them to estimate flow path geometry

Andrew J. Luhmann, Matthew D. Covington, Scott C. Alexander, Su Yi Chai, Benjamin F. Schwartz, Joel T. Groten, E. Calvin Alexander

Research output: Contribution to journal › Article › peer-review

59 Scopus citations

Abstract

A controlled recharge event was conducted with multiple tracers in a karst aquifer in southeastern Minnesota. A pool adjacent to a sinkhole was filled with approximately 13,000. L of water. After tracers were added and thoroughly mixed, the pool was emptied into the sinkhole. Data were collected at Freiheit Spring approximately 95. m north of the sinkhole to monitor spring responses.Flow peaked first at the spring, and suspended sediment peaked next. Then nearly identical uranine, chloride, and δD peaks occurred. Temperature was the last of the tracers to peak. The initial increase in flow at the spring recorded the time at which the water reached a submerged conduit, sending a pressure pulse to the spring at approximately the speed of sound in open water. The initial increase in uranine, chloride, and δD at the spring recorded the arrival of the recharge water. The initial change in temperature and its peak occurred later than the same features in the uranine, chloride, and δD breakthrough curves. As water flowed along this flow path, water exchanged heat with the aquifer, producing a lagged, damped thermal peak at the spring. The combination of hydraulic response and conservative and nonconservative tracers illustrates unique pressure, advective, and nonconservative processes.Geometrical properties of the flow system may be estimated using these tracers. By summing discharge between the time of the initial increase in stage produced by a pressure pulse in a fully phreatic flow path and the time of the chloride peak, the conduit volume is estimated as 47±10% m ³. Heat transport simulations were used to reproduce the modified thermal signal, and simulations with planar flow paths and hydraulic diameters of 7 and 8cm produced the best fits to the observed temperature breakthrough curve. These volume and hydraulic diameter estimates together predict a bedding plane flow path that is 3.5cm high by 9m wide or 4cm high by 8m wide. The different tracers provide complementary information, and the combination of parameters provides useful constraints on flow path geometry.

Original language	English (US)
Pages (from-to)	201-211
Number of pages	11
Journal	Journal of Hydrology
Volume	448-449
DOIs	https://doi.org/10.1016/j.jhydrol.2012.04.044
State	Published - Jul 2 2012
Externally published	Yes

Bibliographical note

Funding Information:
Funding for this project was provided by the Minnesota Environment and Natural Resources Trust Fund as recommended by the Legislative-Citizen Commission on Minnesota Resources (LCCMR). A.J.L. was supported by a Doctoral Dissertation Fellowship from the University of Minnesota Graduate School. M.D.C. acknowledges support from the National Science Foundation (NSF) under Earth Sciences Postdoctoral Fellowship 081647. The ongoing permission of Susan, Aaron, and Matt Kolling to access their property is gratefully acknowledged. Thank you to Martin Saar for providing a computer lab with COMSOL. Thank you also to two anonymous reviewers for helping us improve our manuscript.

Keywords

Heat transport
Hydrograph
Karst
Spring
Tracer breakthrough curve

Access

10.1016/j.jhydrol.2012.04.044

OpenUrl availability

Full text

Cite this

@article{888fb2deb55641649b477705e4856743,

title = "Comparing conservative and nonconservative tracers in karst and using them to estimate flow path geometry",

abstract = "A controlled recharge event was conducted with multiple tracers in a karst aquifer in southeastern Minnesota. A pool adjacent to a sinkhole was filled with approximately 13,000. L of water. After tracers were added and thoroughly mixed, the pool was emptied into the sinkhole. Data were collected at Freiheit Spring approximately 95. m north of the sinkhole to monitor spring responses.Flow peaked first at the spring, and suspended sediment peaked next. Then nearly identical uranine, chloride, and δD peaks occurred. Temperature was the last of the tracers to peak. The initial increase in flow at the spring recorded the time at which the water reached a submerged conduit, sending a pressure pulse to the spring at approximately the speed of sound in open water. The initial increase in uranine, chloride, and δD at the spring recorded the arrival of the recharge water. The initial change in temperature and its peak occurred later than the same features in the uranine, chloride, and δD breakthrough curves. As water flowed along this flow path, water exchanged heat with the aquifer, producing a lagged, damped thermal peak at the spring. The combination of hydraulic response and conservative and nonconservative tracers illustrates unique pressure, advective, and nonconservative processes.Geometrical properties of the flow system may be estimated using these tracers. By summing discharge between the time of the initial increase in stage produced by a pressure pulse in a fully phreatic flow path and the time of the chloride peak, the conduit volume is estimated as 47±10% m 3. Heat transport simulations were used to reproduce the modified thermal signal, and simulations with planar flow paths and hydraulic diameters of 7 and 8cm produced the best fits to the observed temperature breakthrough curve. These volume and hydraulic diameter estimates together predict a bedding plane flow path that is 3.5cm high by 9m wide or 4cm high by 8m wide. The different tracers provide complementary information, and the combination of parameters provides useful constraints on flow path geometry.",

keywords = "Heat transport, Hydrograph, Karst, Spring, Tracer breakthrough curve",

author = "Luhmann, {Andrew J.} and Covington, {Matthew D.} and Alexander, {Scott C.} and Chai, {Su Yi} and Schwartz, {Benjamin F.} and Groten, {Joel T.} and Alexander, {E. Calvin}",

note = "Funding Information: Funding for this project was provided by the Minnesota Environment and Natural Resources Trust Fund as recommended by the Legislative-Citizen Commission on Minnesota Resources (LCCMR). A.J.L. was supported by a Doctoral Dissertation Fellowship from the University of Minnesota Graduate School. M.D.C. acknowledges support from the National Science Foundation (NSF) under Earth Sciences Postdoctoral Fellowship 081647. The ongoing permission of Susan, Aaron, and Matt Kolling to access their property is gratefully acknowledged. Thank you to Martin Saar for providing a computer lab with COMSOL. Thank you also to two anonymous reviewers for helping us improve our manuscript. ",

year = "2012",

month = jul,

day = "2",

doi = "10.1016/j.jhydrol.2012.04.044",

language = "English (US)",

volume = "448-449",

pages = "201--211",

journal = "Journal of Hydrology",

issn = "0022-1694",

publisher = "Elsevier",

}

TY - JOUR

T1 - Comparing conservative and nonconservative tracers in karst and using them to estimate flow path geometry

AU - Luhmann, Andrew J.

AU - Covington, Matthew D.

AU - Alexander, Scott C.

AU - Chai, Su Yi

AU - Schwartz, Benjamin F.

AU - Groten, Joel T.

AU - Alexander, E. Calvin

N1 - Funding Information: Funding for this project was provided by the Minnesota Environment and Natural Resources Trust Fund as recommended by the Legislative-Citizen Commission on Minnesota Resources (LCCMR). A.J.L. was supported by a Doctoral Dissertation Fellowship from the University of Minnesota Graduate School. M.D.C. acknowledges support from the National Science Foundation (NSF) under Earth Sciences Postdoctoral Fellowship 081647. The ongoing permission of Susan, Aaron, and Matt Kolling to access their property is gratefully acknowledged. Thank you to Martin Saar for providing a computer lab with COMSOL. Thank you also to two anonymous reviewers for helping us improve our manuscript.

PY - 2012/7/2

Y1 - 2012/7/2

N2 - A controlled recharge event was conducted with multiple tracers in a karst aquifer in southeastern Minnesota. A pool adjacent to a sinkhole was filled with approximately 13,000. L of water. After tracers were added and thoroughly mixed, the pool was emptied into the sinkhole. Data were collected at Freiheit Spring approximately 95. m north of the sinkhole to monitor spring responses.Flow peaked first at the spring, and suspended sediment peaked next. Then nearly identical uranine, chloride, and δD peaks occurred. Temperature was the last of the tracers to peak. The initial increase in flow at the spring recorded the time at which the water reached a submerged conduit, sending a pressure pulse to the spring at approximately the speed of sound in open water. The initial increase in uranine, chloride, and δD at the spring recorded the arrival of the recharge water. The initial change in temperature and its peak occurred later than the same features in the uranine, chloride, and δD breakthrough curves. As water flowed along this flow path, water exchanged heat with the aquifer, producing a lagged, damped thermal peak at the spring. The combination of hydraulic response and conservative and nonconservative tracers illustrates unique pressure, advective, and nonconservative processes.Geometrical properties of the flow system may be estimated using these tracers. By summing discharge between the time of the initial increase in stage produced by a pressure pulse in a fully phreatic flow path and the time of the chloride peak, the conduit volume is estimated as 47±10% m 3. Heat transport simulations were used to reproduce the modified thermal signal, and simulations with planar flow paths and hydraulic diameters of 7 and 8cm produced the best fits to the observed temperature breakthrough curve. These volume and hydraulic diameter estimates together predict a bedding plane flow path that is 3.5cm high by 9m wide or 4cm high by 8m wide. The different tracers provide complementary information, and the combination of parameters provides useful constraints on flow path geometry.

AB - A controlled recharge event was conducted with multiple tracers in a karst aquifer in southeastern Minnesota. A pool adjacent to a sinkhole was filled with approximately 13,000. L of water. After tracers were added and thoroughly mixed, the pool was emptied into the sinkhole. Data were collected at Freiheit Spring approximately 95. m north of the sinkhole to monitor spring responses.Flow peaked first at the spring, and suspended sediment peaked next. Then nearly identical uranine, chloride, and δD peaks occurred. Temperature was the last of the tracers to peak. The initial increase in flow at the spring recorded the time at which the water reached a submerged conduit, sending a pressure pulse to the spring at approximately the speed of sound in open water. The initial increase in uranine, chloride, and δD at the spring recorded the arrival of the recharge water. The initial change in temperature and its peak occurred later than the same features in the uranine, chloride, and δD breakthrough curves. As water flowed along this flow path, water exchanged heat with the aquifer, producing a lagged, damped thermal peak at the spring. The combination of hydraulic response and conservative and nonconservative tracers illustrates unique pressure, advective, and nonconservative processes.Geometrical properties of the flow system may be estimated using these tracers. By summing discharge between the time of the initial increase in stage produced by a pressure pulse in a fully phreatic flow path and the time of the chloride peak, the conduit volume is estimated as 47±10% m 3. Heat transport simulations were used to reproduce the modified thermal signal, and simulations with planar flow paths and hydraulic diameters of 7 and 8cm produced the best fits to the observed temperature breakthrough curve. These volume and hydraulic diameter estimates together predict a bedding plane flow path that is 3.5cm high by 9m wide or 4cm high by 8m wide. The different tracers provide complementary information, and the combination of parameters provides useful constraints on flow path geometry.

KW - Heat transport

KW - Hydrograph

KW - Karst

KW - Spring

KW - Tracer breakthrough curve

UR - http://www.scopus.com/inward/record.url?scp=84861999159&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=84861999159&partnerID=8YFLogxK

U2 - 10.1016/j.jhydrol.2012.04.044

DO - 10.1016/j.jhydrol.2012.04.044

M3 - Article

AN - SCOPUS:84861999159

SN - 0022-1694

VL - 448-449

SP - 201

EP - 211

JO - Journal of Hydrology

JF - Journal of Hydrology

ER -

Comparing conservative and nonconservative tracers in karst and using them to estimate flow path geometry

Abstract

Bibliographical note

Keywords

Access

OpenUrl availability

Other files and links

Fingerprint

Cite this