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GENERAL COMMENTARY article

Front. For. Glob. Change, 30 September 2020
Sec. Forest Hydrology

Commentary: What We Know About Stemflow's Infiltration Area

\nDarryl E. Carlyle-Moses
Darryl E. Carlyle-Moses1*Shin&#x;ichi IidaShin'ichi Iida2Sonja GermerSonja Germer3Pilar LlorensPilar Llorens4Beate MichalzikBeate Michalzik5Kazuki NankoKazuki Nanko2Tadashi TanakaTadashi Tanaka6Alexander TischerAlexander Tischer5Delphis F. Levia,Delphis F. Levia7,8
  • 1Department of Geography and Environmental Studies, Thompson Rivers University, Kamloops, BC, Canada
  • 2Department of Disaster Prevention, Meteorology and Hydrology, Forestry and Forest Products Research Institute (FFPRI), Ibaraki, Japan
  • 3Department of Technology Assessment and Substance Cycles, Leibniz Institute for Agricultural Engineering and Bioeconomy, Potsdam, Germany
  • 4Institute of Environmental Assessment and Water Research, Spanish National Research Council (IDAEA-CSIC), Barcelona, Spain
  • 5Soil Science, Institute of Geography, Friedrich Schiller University Jena, Jena, Germany
  • 6University of Tsukuba, Ibaraki, Japan
  • 7Department of Geography & Spatial Sciences, University of Delaware, Newark, DE, United States
  • 8Department of Plant & Soil Sciences, University of Delaware, Newark, DE, United States

A Commentary on
What We Know About Stemflow's Infiltration Area

by Van Stan, J. T. II., and Allen, S. T. (2020). Front. For. Glob. Change 3:61. doi: 10.3389/ffgc.2020.00061

Introduction

Stemflow represents the portion of precipitation routed by vegetation to the base of tree boles or plants stems. Van Stan and Allen (2020) (herein referred to as VS&A) is a mini review of studies that have attempted to quantify the infiltration area of stemflow once it has reached the soil surface, IT. More specifically, VS&A provide an overview of: (i) the ability of vegetation canopies to funnel rainfall; (ii) the various approaches used to estimate or measure the size of IT; (iii) the different soil properties that may influence the magnitude of IT, and (iv) the potential for and limitations to using dye and stable isotope tracers in IT research. The objectives of this commentary are to: (i) highlight and expand upon important points raised by VS&A in order to advance the understanding of the controls regulating the size of IT, and (ii) provide corrections to and clarification of prior IT results presented in VS&A.

Advancement of the Scientific Understanding of Stemflow Infiltration Area, IT

VS&A state the importance of stemflow in the hydrology and biogeochemistry of vegetated environments is dependent upon IT size. These authors rightfully note that there is a need for further research, especially in natural forest systems, to characterize the size of IT. Previous studies (e.g., Iida et al., 2005; Chinen, 2007) have estimated the magnitude of IT using litter marks (the displacement of leaf litter) or soil scour marks caused by the excess overland flow of stemflow. As VS&A state, litter and scour marks are difficult to interpret quantitatively as they neither represent mean nor maximum IT for a given storm. As such, litter and scour marks have little utility estimating IT.

VS&A correctly state that factors, such as soil hydrophobicity, could influence stemflow infiltrability in certain environments. Nonetheless, the methodology of Herwitz (1986), in which IT values are derived by dividing the stemflow volumetric input rate by the infiltration capacity of the surface soil (i.e., the saturated hydraulic conductivity, Ksat), remains a theoretically sound approach. What is important to highlight is that in situ measurements of Ksat, as a surrogate for stemflow infiltrability in the proximal bole/stem area that include the effect of macropore flow (i.e., Ksat measured with no tension; hydraulic head = 0 cm) are likely to be more representative of the actual infiltrability of stemflow than Ksat measured using tension or Ksat values derived from pedotransfer functions [e.g., ROSETTA model—Schaap et al. (2001)], which estimate soil matrix Ksat.

Critique of Reported Formula and Findings of Previous Research

VS&A (page 1) suggest that the following equation (Equation 1 in VS&A) is the funneling ratio derived by Herwitz (1986):

F=STP·IT    (1)

where F is the funneling ratio (dimensionless), ST represents stemflow volume (L tree−1), P is precipitation depth (mm), and IT is the stemflow infiltration area (m2 tree−1).

The funneling ratio proposed by Herwitz (1986), however, differs from that of Equation (1) in that the basal area of the tree bole, B (m2), rather than IT, is multiplied by P in the denominator of the equation:

F=STP·B    (2)

VS&A (page 2) also suggest that “… Herwitz's (1986) equation for F employs the concept of IT…”; however, Herwitz (1986) never advocated that B was a surrogate for IT or that B played any role in IT size. Instead, and as aforementioned, Herwitz (1986) derived IT by taking the stemflow input rate and the infiltration capacity of the surface soil into account, and the derived values of ITwere markedly different than B.

VS&A (page 3) cite various studies supporting their claim that “there are pieces of evidence that suggest that IT is larger, 10−1 to 101 m2, than the areas assumed elsewhere, e.g., 10−4-10−1 m2 (Iida et al., 2016; McKee and Carlyle-Moses, 2017; Carlyle-Moses et al., 2018)”. Iida et al. (2016) make no mention of IT (or stemflow) and it is unclear why this study was cited. Furthermore, the range of IT provided by Carlyle-Moses et al. (2018) is for conditions of average rainfall / stemflow input rates within mature, natural forests. They are not representative of extreme precipitation events (e.g., Herwitz, 1986) nor orchards or agricultural fields (e.g., Keen et al., 2010) where soil compaction may reduce stemflow infiltrability.

Table 1 of this commentary expands on Table 1 of VS&A to illustrate a fuller range of IT reported in the literature and provides corrections and / or clarifying statements to some of the results presented in that table. Table 1 of this commentary shows that assessments of IT under a variety of rainfall, soil, and plant morphological conditions are lacking. The majority of prior studies report the maximum extent of IT (e.g., Voigt, 1960; Pressland, 1973) or use “litter marks” or erosional soil scouring for estimating IT (e.g., Iida et al., 2005; Chinen, 2007) which simply do not provide reliable quantitative evidence of average IT. Litter marks may be seasonal and are at least episodic phenomena persisting across events (e.g., Iida et al., 2005). Litter marks are not created during low intensity events (as stated by VS&A) but rather during peak periods of heavier rain with high stemflow funneling. What does emerge from Table 1 is that studies conducted thus far using in situ dye experiments and direct observations of stemflow infiltration or studies utilizing physically-based approaches such as dividing the stemflow input rate by the soil Ksat suggest that IT associated with average rainfall and stemflow rates are limited <1 m2 tree−1 in environments (e.g., mature, natural forests) where the soil infiltrability can be expected to have a magnitude of order of 1 x 102 or 1 x 103 mm h−1. Additionally, the findings presented in Table 1 suggest that IT ≥ 1 m2 tree−1 may sometimes arise during large / extreme rainfalls and stemflow rates in these forest environments and under relatively smaller rainfall and stemflow rates in environments (e.g., agricultural plantations, orchards, agroforestry areas, and urban environments) where infiltrability is likely <1 x 102 mm h−1.

TABLE 1
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Table 1. Stemflow infiltration areas (IT) from previous research.

Author Contributions

DC-M was the primary author of the manuscript and a co-originator of the commentary. SI contributed to the text and was a major contributor to the table. SG and PL contributed to the text of the paper, making several editorial changes and suggestions. SG also played a major role in the revision, reconfiguring the table into final form. BM contributed to the text and to the table. KN contributed ideas to the text. AT contributed ideas to the text and contributed to the table. TT contributed to the text. DL contributed to the text, the table and was a co-originator of the commentary. All authors contributed to the article and approved the submitted version.

Conflict of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Acknowledgments

This commentary was written in conjunction with Project LinkA20045 of the international scientific collaboration program i-LINK+ 2018 funded by the Spanish National Research Council (CSIC).

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Keywords: stemflow, infiltration, dye tracer, forest hydrology, funneling ratio

Citation: Carlyle-Moses DE, Iida S, Germer S, Llorens P, Michalzik B, Nanko K, Tanaka T, Tischer A and Levia DF (2020) Commentary: What We Know About Stemflow's Infiltration Area. Front. For. Glob. Change 3:577247. doi: 10.3389/ffgc.2020.577247

Received: 29 June 2020; Accepted: 17 August 2020;
Published: 30 September 2020.

Edited by:

David Findlay Scott, University of British Columbia Okanagan, Canada

Reviewed by:

Georgianne W. Moore, Texas A&M University, United States

Copyright © 2020 Carlyle-Moses, Iida, Germer, Llorens, Michalzik, Nanko, Tanaka, Tischer and Levia. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Darryl E. Carlyle-Moses, dcarlyle@tru.ca

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