Coupled Gas-Exchange Model for C<sub>4</sub> Leaves Comparing Stomatal Conductance Models

Coupled Gas-Exchange Model for C<sub>4</sub> Leaves Comparing Stomatal Conductance Models

Plant simulation models are abstractions of plant physiological processes that are useful for investigating the responses of plants to changes in the environment. Because photosynthesis and transpiration are fundamental processes that drive plant growth and water relations, a leaf gas-exchange model...

Full description

Bibliographic Details
Main Authors: Kyungdahm Yun, Dennis Timlin, Soo-Hyung Kim
Format: Article
Language:English
Published: MDPI AG 2020-10-01
Series:Plants
Subjects:
gas-exchange
C<sub>4</sub> photosynthesis
stomatal conductance
Ball–Berry
Medlyn
Online Access:https://www.mdpi.com/2223-7747/9/10/1358
id doaj-c5303385836b47b3abd4ce49617b99d1
record_format Article
spelling doaj-c5303385836b47b3abd4ce49617b99d12020-11-25T02:41:59ZengMDPI AGPlants2223-77472020-10-0191358135810.3390/plants9101358Coupled Gas-Exchange Model for C<sub>4</sub> Leaves Comparing Stomatal Conductance ModelsKyungdahm Yun0Dennis Timlin1Soo-Hyung Kim2School of Environmental and Forest Sciences, College of the Environment, University of Washington, Seattle, WA 98195, USAAdaptive Cropping Systems Laboratory, Agricultural Research Service, U.S. Department of Agriculture, Beltsville, MD 20705, USASchool of Environmental and Forest Sciences, College of the Environment, University of Washington, Seattle, WA 98195, USAPlant simulation models are abstractions of plant physiological processes that are useful for investigating the responses of plants to changes in the environment. Because photosynthesis and transpiration are fundamental processes that drive plant growth and water relations, a leaf gas-exchange model that couples their interdependent relationship through stomatal control is a prerequisite for explanatory plant simulation models. Here, we present a coupled gas-exchange model for <inline-formula><math display="inline"><semantics><msub><mi>C</mi><mn>4</mn></msub></semantics></math></inline-formula> leaves incorporating two widely used stomatal conductance submodels: Ball–Berry and Medlyn models. The output variables of the model includes steady-state values of <inline-formula><math display="inline"><semantics><mrow><mi>C</mi><msub><mi>O</mi><mn>2</mn></msub></mrow></semantics></math></inline-formula> assimilation rate, transpiration rate, stomatal conductance, leaf temperature, internal <inline-formula><math display="inline"><semantics><mrow><mi>C</mi><msub><mi>O</mi><mn>2</mn></msub></mrow></semantics></math></inline-formula> concentrations, and other leaf gas-exchange attributes in response to light, temperature, <inline-formula><math display="inline"><semantics><mrow><mi>C</mi><msub><mi>O</mi><mn>2</mn></msub></mrow></semantics></math></inline-formula>, humidity, leaf nitrogen, and leaf water status. We test the model behavior and sensitivity, and discuss its applications and limitations. The model was implemented in Julia programming language using a novel modeling framework. Our testing and analyses indicate that the model behavior is reasonably sensitive and reliable in a wide range of environmental conditions. The behavior of the two model variants differing in stomatal conductance submodels deviated substantially from each other in low humidity conditions. The model was capable of replicating the behavior of transgenic <inline-formula><math display="inline"><semantics><msub><mi>C</mi><mn>4</mn></msub></semantics></math></inline-formula> leaves under moderate temperatures as found in the literature. The coupled model, however, underestimated stomatal conductance in very high temperatures. This is likely an inherent limitation of the coupling approaches using Ball–Berry type models in which photosynthesis and stomatal conductance are recursively linked as an input of the other.https://www.mdpi.com/2223-7747/9/10/1358gas-exchangeC<sub>4</sub> photosynthesisstomatal conductanceBall–BerryMedlyn
collection DOAJ
language English
format Article
sources DOAJ
author Kyungdahm Yun
Dennis Timlin
Soo-Hyung Kim
spellingShingle Kyungdahm Yun
Dennis Timlin
Soo-Hyung Kim
Coupled Gas-Exchange Model for C<sub>4</sub> Leaves Comparing Stomatal Conductance Models
Plants
gas-exchange
C<sub>4</sub> photosynthesis
stomatal conductance
Ball–Berry
Medlyn
author_facet Kyungdahm Yun
Dennis Timlin
Soo-Hyung Kim
author_sort Kyungdahm Yun
title Coupled Gas-Exchange Model for C<sub>4</sub> Leaves Comparing Stomatal Conductance Models
title_short Coupled Gas-Exchange Model for C<sub>4</sub> Leaves Comparing Stomatal Conductance Models
title_full Coupled Gas-Exchange Model for C<sub>4</sub> Leaves Comparing Stomatal Conductance Models
title_fullStr Coupled Gas-Exchange Model for C<sub>4</sub> Leaves Comparing Stomatal Conductance Models
title_full_unstemmed Coupled Gas-Exchange Model for C<sub>4</sub> Leaves Comparing Stomatal Conductance Models
title_sort coupled gas-exchange model for c<sub>4</sub> leaves comparing stomatal conductance models
publisher MDPI AG
series Plants
issn 2223-7747
publishDate 2020-10-01
description Plant simulation models are abstractions of plant physiological processes that are useful for investigating the responses of plants to changes in the environment. Because photosynthesis and transpiration are fundamental processes that drive plant growth and water relations, a leaf gas-exchange model that couples their interdependent relationship through stomatal control is a prerequisite for explanatory plant simulation models. Here, we present a coupled gas-exchange model for <inline-formula><math display="inline"><semantics><msub><mi>C</mi><mn>4</mn></msub></semantics></math></inline-formula> leaves incorporating two widely used stomatal conductance submodels: Ball–Berry and Medlyn models. The output variables of the model includes steady-state values of <inline-formula><math display="inline"><semantics><mrow><mi>C</mi><msub><mi>O</mi><mn>2</mn></msub></mrow></semantics></math></inline-formula> assimilation rate, transpiration rate, stomatal conductance, leaf temperature, internal <inline-formula><math display="inline"><semantics><mrow><mi>C</mi><msub><mi>O</mi><mn>2</mn></msub></mrow></semantics></math></inline-formula> concentrations, and other leaf gas-exchange attributes in response to light, temperature, <inline-formula><math display="inline"><semantics><mrow><mi>C</mi><msub><mi>O</mi><mn>2</mn></msub></mrow></semantics></math></inline-formula>, humidity, leaf nitrogen, and leaf water status. We test the model behavior and sensitivity, and discuss its applications and limitations. The model was implemented in Julia programming language using a novel modeling framework. Our testing and analyses indicate that the model behavior is reasonably sensitive and reliable in a wide range of environmental conditions. The behavior of the two model variants differing in stomatal conductance submodels deviated substantially from each other in low humidity conditions. The model was capable of replicating the behavior of transgenic <inline-formula><math display="inline"><semantics><msub><mi>C</mi><mn>4</mn></msub></semantics></math></inline-formula> leaves under moderate temperatures as found in the literature. The coupled model, however, underestimated stomatal conductance in very high temperatures. This is likely an inherent limitation of the coupling approaches using Ball–Berry type models in which photosynthesis and stomatal conductance are recursively linked as an input of the other.
topic gas-exchange
C<sub>4</sub> photosynthesis
stomatal conductance
Ball–Berry
Medlyn
url https://www.mdpi.com/2223-7747/9/10/1358
work_keys_str_mv AT kyungdahmyun coupledgasexchangemodelforcsub4subleavescomparingstomatalconductancemodels
AT dennistimlin coupledgasexchangemodelforcsub4subleavescomparingstomatalconductancemodels
AT soohyungkim coupledgasexchangemodelforcsub4subleavescomparingstomatalconductancemodels
_version_ 1724776097007009792

Similar Items