TY - JOUR
T1 - Concentration-Discharge Relations in the Critical Zone
T2 - Implications for Resolving Critical Zone Structure, Function, and Evolution
AU - Chorover, Jon
AU - Derry, Louis A.
AU - McDowell, William H.
N1 - Funding Information: The idea for a special section of Water Resources Research originated with a workshop held in July 2015 at University of New Hampshire that focused on the challenge of developing mechanistic interpretations of C-Q relations through an improved understanding of critical zone (CZ) structure and function, such as is underway at critical zone observatories worldwide. The ‘‘C/Q relations in the Critical Zone’’ workshop, funded by the National Science Foundation through the Critical Zone Observatories (CZO) National Office, brought together scientists working in a variety of CZ sites to present their approaches to resolving mechanistic controls over discharge-induced variation in hydrochemistry. Several of the papers initially presented at the workshop, as well as others that were subsequently submitted, are included in this special section. Funding Information: This work was supported by grants through the NSF Critical Zone Observatories program including EAR 13-31408 to J. Chorover, EAR 14-45246 to L. A. Derry, and ICER-13-31841 to W.H. McDowell. Publisher Copyright: © 2017. American Geophysical Union. All Rights Reserved.
PY - 2017/11
Y1 - 2017/11
N2 - Critical zone science seeks to develop mechanistic theories that describe critical zone structure, function, and long-term evolution. One postulate is that hydrogeochemical controls on critical zone evolution can be inferred from solute discharges measured down-gradient of reactive flow paths. These flow paths have variable lengths, interfacial compositions, and residence times, and their mixing is reflected in concentration-discharge (C-Q) relations. Motivation for this special section originates from a U.S. Critical Zone Observatories workshop that was held at the University of New Hampshire, 20–22 July 2015. The workshop focused on resolving mechanistic CZ controls over surface water chemical dynamics across the full range of lithogenic (e.g., nonhydrolyzing and hydrolyzing cations and oxyanions) and bioactive solutes (e.g., organic and inorganic forms of C, N, P, and S), including dissolved and colloidal species that may cooccur for a given element. Papers submitted to this special section on “concentration-discharge relations in the critical zone” include those from authors who attended the workshop, as well as others who responded to the open solicitation. Submissions were invited that utilized information pertaining to internal, integrated catchment function (relations between hydrology, biogeochemistry, and landscape structure) to help illuminate controls on observed C-Q relations.
AB - Critical zone science seeks to develop mechanistic theories that describe critical zone structure, function, and long-term evolution. One postulate is that hydrogeochemical controls on critical zone evolution can be inferred from solute discharges measured down-gradient of reactive flow paths. These flow paths have variable lengths, interfacial compositions, and residence times, and their mixing is reflected in concentration-discharge (C-Q) relations. Motivation for this special section originates from a U.S. Critical Zone Observatories workshop that was held at the University of New Hampshire, 20–22 July 2015. The workshop focused on resolving mechanistic CZ controls over surface water chemical dynamics across the full range of lithogenic (e.g., nonhydrolyzing and hydrolyzing cations and oxyanions) and bioactive solutes (e.g., organic and inorganic forms of C, N, P, and S), including dissolved and colloidal species that may cooccur for a given element. Papers submitted to this special section on “concentration-discharge relations in the critical zone” include those from authors who attended the workshop, as well as others who responded to the open solicitation. Submissions were invited that utilized information pertaining to internal, integrated catchment function (relations between hydrology, biogeochemistry, and landscape structure) to help illuminate controls on observed C-Q relations.
KW - concentration-discharge
KW - critical zone
KW - stream chemistry
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U2 - 10.1002/2017WR021111
DO - 10.1002/2017WR021111
M3 - Editorial
SN - 0043-1397
VL - 53
SP - 8654
EP - 8659
JO - Water Resources Research
JF - Water Resources Research
IS - 11
ER -