Consequences of gas flux model choice on the interpretation of metabolic balance across 15 lakes

Hilary A. Dugan; R. Iestyn Woolway; Arianto B. Santoso; Jessica R. Corman; Aline Jaimes; Emily R. Nodine; Vijay P. Patil; Jacob A. Zwart; Jennifer A. Brentrup; Amy L. Hetherington; Samantha K. Oliver; Jordan S. Read; Kirsten M. Winters; Paul C. Hanson; Emily K. Read; Luke A. Winslow; Kathleen C. Weathers

doi:10.1080/IW-6.4.836

Consequences of gas flux model choice on the interpretation of metabolic balance across 15 lakes

Hilary A. Dugan, R. Iestyn Woolway, Arianto B. Santoso, Jessica R. Corman, Aline Jaimes, Emily R. Nodine, Vijay P. Patil, Jacob A. Zwart, Jennifer A. Brentrup, Amy L. Hetherington, Samantha K. Oliver, Jordan S. Read, Kirsten M. Winters, Paul C. Hanson, Emily K. Read, Luke A. Winslow, Kathleen C. Weathers

School of Ocean Sciences

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

Abstract

Ecosystem metabolism and the contribution of carbon dioxide from lakes to the atmosphere can be estimated from free-water gas measurements through the use of mass balance models, which rely on a gas transfer coefficient (k) to model gas exchange with the atmosphere. Theoretical and empirically based models of k range in complexity from wind-driven power functions to complex surface renewal models; however, model choice is rarely considered in most studies of lake metabolism. This study used high-frequency data from 15 lakes provided by the Global Lake Ecological Observatory Network (GLEON) to study how model choice of k influenced estimates of lake metabolism and gas exchange with the atmosphere. We tested 6 models of k on lakes chosen to span broad gradients in surface area and trophic states; a metabolism model was then fit to all 6 outputs of k data. We found that hourly values for k were substantially different between models and, at an annual scale, resulted in significantly different estimates of lake metabolism and gas exchange with the atmosphere.

Original language	English
Pages (from-to)	581-592
Journal	INLAND WATERS
Volume	6
Issue number	4
DOIs	https://doi.org/10.1080/IW-6.4.836
Publication status	Published - 2 Nov 2016

Keywords

gas exchange
GLEON
lakes
lake models
metabolism
sensor network

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10.1080/IW-6.4.836

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Dugan, H. A., Woolway, R. I., Santoso, A. B., Corman, J. R., Jaimes, A., Nodine, E. R., Patil, V. P., Zwart, J. A., Brentrup, J. A., Hetherington, A. L., Oliver, S. K., Read, J. S., Winters, K. M., Hanson, P. C., Read, E. K., Winslow, L. A., & Weathers, K. C. (2016). Consequences of gas flux model choice on the interpretation of metabolic balance across 15 lakes. INLAND WATERS, 6(4), 581-592. https://doi.org/10.1080/IW-6.4.836

@article{d23c582b536c4e07a044c2a3109a59b7,

title = "Consequences of gas flux model choice on the interpretation of metabolic balance across 15 lakes",

abstract = "Ecosystem metabolism and the contribution of carbon dioxide from lakes to the atmosphere can be estimated from free-water gas measurements through the use of mass balance models, which rely on a gas transfer coefficient (k) to model gas exchange with the atmosphere. Theoretical and empirically based models of k range in complexity from wind-driven power functions to complex surface renewal models; however, model choice is rarely considered in most studies of lake metabolism. This study used high-frequency data from 15 lakes provided by the Global Lake Ecological Observatory Network (GLEON) to study how model choice of k influenced estimates of lake metabolism and gas exchange with the atmosphere. We tested 6 models of k on lakes chosen to span broad gradients in surface area and trophic states; a metabolism model was then fit to all 6 outputs of k data. We found that hourly values for k were substantially different between models and, at an annual scale, resulted in significantly different estimates of lake metabolism and gas exchange with the atmosphere.",

keywords = "gas exchange, GLEON, lakes, lake models, metabolism, sensor network",

author = "Dugan, {Hilary A.} and Woolway, {R. Iestyn} and Santoso, {Arianto B.} and Corman, {Jessica R.} and Aline Jaimes and Nodine, {Emily R.} and Patil, {Vijay P.} and Zwart, {Jacob A.} and Brentrup, {Jennifer A.} and Hetherington, {Amy L.} and Oliver, {Samantha K.} and Read, {Jordan S.} and Winters, {Kirsten M.} and Hanson, {Paul C.} and Read, {Emily K.} and Winslow, {Luke A.} and Weathers, {Kathleen C.}",

year = "2016",

month = nov,

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doi = "10.1080/IW-6.4.836",

language = "English",

volume = "6",

pages = "581--592",

journal = "INLAND WATERS",

issn = "2044-2041",

publisher = "Freshwater Biological Association",

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Dugan, HA, Woolway, RI, Santoso, AB, Corman, JR, Jaimes, A, Nodine, ER, Patil, VP, Zwart, JA, Brentrup, JA, Hetherington, AL, Oliver, SK, Read, JS, Winters, KM, Hanson, PC, Read, EK, Winslow, LA & Weathers, KC 2016, 'Consequences of gas flux model choice on the interpretation of metabolic balance across 15 lakes', INLAND WATERS, vol. 6, no. 4, pp. 581-592. https://doi.org/10.1080/IW-6.4.836

TY - JOUR

T1 - Consequences of gas flux model choice on the interpretation of metabolic balance across 15 lakes

AU - Dugan, Hilary A.

AU - Woolway, R. Iestyn

AU - Santoso, Arianto B.

AU - Corman, Jessica R.

AU - Jaimes, Aline

AU - Nodine, Emily R.

AU - Patil, Vijay P.

AU - Zwart, Jacob A.

AU - Brentrup, Jennifer A.

AU - Hetherington, Amy L.

AU - Oliver, Samantha K.

AU - Read, Jordan S.

AU - Winters, Kirsten M.

AU - Hanson, Paul C.

AU - Read, Emily K.

AU - Winslow, Luke A.

AU - Weathers, Kathleen C.

PY - 2016/11/2

Y1 - 2016/11/2

N2 - Ecosystem metabolism and the contribution of carbon dioxide from lakes to the atmosphere can be estimated from free-water gas measurements through the use of mass balance models, which rely on a gas transfer coefficient (k) to model gas exchange with the atmosphere. Theoretical and empirically based models of k range in complexity from wind-driven power functions to complex surface renewal models; however, model choice is rarely considered in most studies of lake metabolism. This study used high-frequency data from 15 lakes provided by the Global Lake Ecological Observatory Network (GLEON) to study how model choice of k influenced estimates of lake metabolism and gas exchange with the atmosphere. We tested 6 models of k on lakes chosen to span broad gradients in surface area and trophic states; a metabolism model was then fit to all 6 outputs of k data. We found that hourly values for k were substantially different between models and, at an annual scale, resulted in significantly different estimates of lake metabolism and gas exchange with the atmosphere.

AB - Ecosystem metabolism and the contribution of carbon dioxide from lakes to the atmosphere can be estimated from free-water gas measurements through the use of mass balance models, which rely on a gas transfer coefficient (k) to model gas exchange with the atmosphere. Theoretical and empirically based models of k range in complexity from wind-driven power functions to complex surface renewal models; however, model choice is rarely considered in most studies of lake metabolism. This study used high-frequency data from 15 lakes provided by the Global Lake Ecological Observatory Network (GLEON) to study how model choice of k influenced estimates of lake metabolism and gas exchange with the atmosphere. We tested 6 models of k on lakes chosen to span broad gradients in surface area and trophic states; a metabolism model was then fit to all 6 outputs of k data. We found that hourly values for k were substantially different between models and, at an annual scale, resulted in significantly different estimates of lake metabolism and gas exchange with the atmosphere.

KW - gas exchange

KW - GLEON

KW - lakes

KW - lake models

KW - metabolism

KW - sensor network

U2 - 10.1080/IW-6.4.836

DO - 10.1080/IW-6.4.836

M3 - Article

SN - 2044-2041

VL - 6

SP - 581

EP - 592

JO - INLAND WATERS

JF - INLAND WATERS

IS - 4

ER -

Consequences of gas flux model choice on the interpretation of metabolic balance across 15 lakes

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Keywords

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