Beyond the black box: Promoting mathematical collaborations for elucidating interactions in soil ecology

Alison E. Bennett; Katharine Preedy; Antonio Golubski; James Umbanhowar; Stuart R. Borrett; Loren Byrne; Kent Apostol; James D. Bever; Lori Biederman; Aimée T. Classen; Kim Cuddington; Marie Anne De Graaff; Karen A. Garrett; Lou Gross; Alan Hastings; Jason D. Hoeksema; Volodymyr Hrynkiv; Justine Karst; Miro Kummel; Charlotte T. Lee; Chao Liang; Wei Liao; Keenan Mack; Laura Miller; Bonnie Ownley; Claudia Rojas; Ellen L. Simms; Vonda K. Walsh; Matthew Warren; Jun Zhu

doi:10.1002/ecs2.2799

Beyond the black box: Promoting mathematical collaborations for elucidating interactions in soil ecology

Alison E. Bennett, Katharine Preedy, Antonio Golubski, James Umbanhowar, Stuart R. Borrett, Loren Byrne, Kent Apostol, James D. Bever, Lori Biederman, Aimée T. Classen, Kim Cuddington, Marie Anne De Graaff, Karen A. Garrett, Lou Gross, Alan Hastings, Jason D. Hoeksema, Volodymyr Hrynkiv, Justine Karst, Miro Kummel, Charlotte T. LeeChao Liang, Wei Liao, Keenan Mack, Laura Miller, Bonnie Ownley, Claudia Rojas, Ellen L. Simms, Vonda K. Walsh, Matthew Warren, Jun Zhu

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

3 Scopus citations

Abstract

Understanding soil systems is critical because they form the structural and nutritional foundation for plants and thus every terrestrial habitat and agricultural system. In this paper, we encourage increased use of mathematical models to drive forward understanding of interactions in soil ecological systems. We discuss several distinctive features of soil ecosystems and empirical studies of them. We explore some perceptions that have previously deterred more extensive use of models in soil ecology and some advances that have already been made using models to elucidate soil ecological interactions. We provide examples where mathematical models have been used to test the plausibility of hypothesized mechanisms, to explore systems where experimental manipulations are currently impossible, or to determine the most important variables to measure in experimental and natural systems. To aid in the development of theory in this field, we present a table describing major soil ecology topics, the theory previously used, and providing key terms for theoretical approaches that could potentially address them. We then provide examples from the table that may either contribute to important incremental developments in soil science or potentially revolutionize our understanding of plant-soil systems. We challenge scientists and mathematicians to push theoretical explorations in soil systems further and highlight three major areas for the development of mathematical models in soil ecology: Theory spanning scales and ecological hierarchies, processes, and evolution.

Original language	English (US)
Article number	e02779
Journal	Ecosphere
Volume	10
Issue number	7
DOIs	https://doi.org/10.1002/ecs2.2799
State	Published - Jul 2019
Externally published	Yes

Keywords

Ecological hierarchy
Evolution
Mathematical model
Plant-soil interactions
Soil ecology
Soil processes
Theory

ASJC Scopus subject areas

Ecology, Evolution, Behavior and Systematics
Ecology

Access to Document

10.1002/ecs2.2799

Cite this

Bennett, A. E., Preedy, K., Golubski, A., Umbanhowar, J., Borrett, S. R., Byrne, L., Apostol, K., Bever, J. D., Biederman, L., Classen, A. T., Cuddington, K., De Graaff, M. A., Garrett, K. A., Gross, L., Hastings, A., Hoeksema, J. D., Hrynkiv, V., Karst, J., Kummel, M., ... Zhu, J. (2019). Beyond the black box: Promoting mathematical collaborations for elucidating interactions in soil ecology. Ecosphere, 10(7), [e02779]. https://doi.org/10.1002/ecs2.2799

Beyond the black box : Promoting mathematical collaborations for elucidating interactions in soil ecology. / Bennett, Alison E.; Preedy, Katharine; Golubski, Antonio; Umbanhowar, James; Borrett, Stuart R.; Byrne, Loren; Apostol, Kent; Bever, James D.; Biederman, Lori; Classen, Aimée T.; Cuddington, Kim; De Graaff, Marie Anne; Garrett, Karen A.; Gross, Lou; Hastings, Alan; Hoeksema, Jason D.; Hrynkiv, Volodymyr; Karst, Justine; Kummel, Miro; Lee, Charlotte T.; Liang, Chao; Liao, Wei; Mack, Keenan; Miller, Laura; Ownley, Bonnie; Rojas, Claudia; Simms, Ellen L.; Walsh, Vonda K.; Warren, Matthew; Zhu, Jun.

In: Ecosphere, Vol. 10, No. 7, e02779, 07.2019.

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

Bennett, AE, Preedy, K, Golubski, A, Umbanhowar, J, Borrett, SR, Byrne, L, Apostol, K, Bever, JD, Biederman, L, Classen, AT, Cuddington, K, De Graaff, MA, Garrett, KA, Gross, L, Hastings, A, Hoeksema, JD, Hrynkiv, V, Karst, J, Kummel, M, Lee, CT, Liang, C, Liao, W, Mack, K, Miller, L, Ownley, B, Rojas, C, Simms, EL, Walsh, VK, Warren, M & Zhu, J 2019, 'Beyond the black box: Promoting mathematical collaborations for elucidating interactions in soil ecology', Ecosphere, vol. 10, no. 7, e02779. https://doi.org/10.1002/ecs2.2799

Bennett, Alison E. ; Preedy, Katharine ; Golubski, Antonio ; Umbanhowar, James ; Borrett, Stuart R. ; Byrne, Loren ; Apostol, Kent ; Bever, James D. ; Biederman, Lori ; Classen, Aimée T. ; Cuddington, Kim ; De Graaff, Marie Anne ; Garrett, Karen A. ; Gross, Lou ; Hastings, Alan ; Hoeksema, Jason D. ; Hrynkiv, Volodymyr ; Karst, Justine ; Kummel, Miro ; Lee, Charlotte T. ; Liang, Chao ; Liao, Wei ; Mack, Keenan ; Miller, Laura ; Ownley, Bonnie ; Rojas, Claudia ; Simms, Ellen L. ; Walsh, Vonda K. ; Warren, Matthew ; Zhu, Jun. / Beyond the black box : Promoting mathematical collaborations for elucidating interactions in soil ecology. In: Ecosphere. 2019 ; Vol. 10, No. 7.

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title = "Beyond the black box: Promoting mathematical collaborations for elucidating interactions in soil ecology",

abstract = "Understanding soil systems is critical because they form the structural and nutritional foundation for plants and thus every terrestrial habitat and agricultural system. In this paper, we encourage increased use of mathematical models to drive forward understanding of interactions in soil ecological systems. We discuss several distinctive features of soil ecosystems and empirical studies of them. We explore some perceptions that have previously deterred more extensive use of models in soil ecology and some advances that have already been made using models to elucidate soil ecological interactions. We provide examples where mathematical models have been used to test the plausibility of hypothesized mechanisms, to explore systems where experimental manipulations are currently impossible, or to determine the most important variables to measure in experimental and natural systems. To aid in the development of theory in this field, we present a table describing major soil ecology topics, the theory previously used, and providing key terms for theoretical approaches that could potentially address them. We then provide examples from the table that may either contribute to important incremental developments in soil science or potentially revolutionize our understanding of plant-soil systems. We challenge scientists and mathematicians to push theoretical explorations in soil systems further and highlight three major areas for the development of mathematical models in soil ecology: Theory spanning scales and ecological hierarchies, processes, and evolution.",

keywords = "Ecological hierarchy, Evolution, Mathematical model, Plant-soil interactions, Soil ecology, Soil processes, Theory",

author = "Bennett, {Alison E.} and Katharine Preedy and Antonio Golubski and James Umbanhowar and Borrett, {Stuart R.} and Loren Byrne and Kent Apostol and Bever, {James D.} and Lori Biederman and Classen, {Aim{\'e}e T.} and Kim Cuddington and {De Graaff}, {Marie Anne} and Garrett, {Karen A.} and Lou Gross and Alan Hastings and Hoeksema, {Jason D.} and Volodymyr Hrynkiv and Justine Karst and Miro Kummel and Lee, {Charlotte T.} and Chao Liang and Wei Liao and Keenan Mack and Laura Miller and Bonnie Ownley and Claudia Rojas and Simms, {Ellen L.} and Walsh, {Vonda K.} and Matthew Warren and Jun Zhu",

note = "Funding Information: National Institute for Mathematical and Biological Synthesis, sponsored by the National Science Foundation through NSFAward #DBI-1300426, with additional support from The University of Tennessee, Knoxville. Alison Bennett and Katharine Preedy were supported by Scottish Government Rural and Environment Science and Analytical Services Division. Antonio J. Golubski was supported by National Science Foundation award DEB-1456927. Jason Hoeksema was supported by National Science Foundation award DEB-1119865. Ellen L. Simms was supported by National Science Foundation award DEB-0645791. Funding Information: This work was assisted through participation in the “Strategies for the Black Box: Mathematical tools for plant–soil interactions” Investigative Workshop at the National Institute for Mathematical and Biological Synthesis, sponsored by the National Science Foundation through NSF Award #DBI-1300426, with additional support from The University of Tennessee, Knoxville. Alison Bennett and Katharine Preedy were supported by Scottish Government Rural and Environment Science and Analytical Services Division. Antonio J. Golubski was supported by National Science Foundation award DEB-1456927. Jason Hoeksema was supported by National Science Foundation award DEB-1119865. Ellen L. Simms was supported by National Science Foundation award DEB-0645791. The authors would also like to thank Glenn Marion, Christine Hackett, and Philip Smith for comments on the manuscript. Alison E. Bennett, Katharine Preedy, Antonio Golubski, James Umbanhowar, Stuart R. Bor-rett, and Loren Byrne led the writing process. All authors, except Katharine Preedy, attended the “Strategies for the Black Box: Mathematical tools for plant– soil interactions” Investigative Workshop at the National Institute for Mathematical and Biological Synthesis organized by Alison E. Bennett and James Umbanhowar. All authors contributed to the development of Table 1 and helped in writing. Publisher Copyright: {\textcopyright} 2019 The Authors.",

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doi = "10.1002/ecs2.2799",

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AU - Preedy, Katharine

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AU - Umbanhowar, James

AU - Borrett, Stuart R.

AU - Byrne, Loren

AU - Apostol, Kent

AU - Bever, James D.

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AU - De Graaff, Marie Anne

AU - Garrett, Karen A.

AU - Gross, Lou

AU - Hastings, Alan

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AU - Rojas, Claudia

AU - Simms, Ellen L.

AU - Walsh, Vonda K.

AU - Warren, Matthew

AU - Zhu, Jun

N1 - Funding Information: National Institute for Mathematical and Biological Synthesis, sponsored by the National Science Foundation through NSFAward #DBI-1300426, with additional support from The University of Tennessee, Knoxville. Alison Bennett and Katharine Preedy were supported by Scottish Government Rural and Environment Science and Analytical Services Division. Antonio J. Golubski was supported by National Science Foundation award DEB-1456927. Jason Hoeksema was supported by National Science Foundation award DEB-1119865. Ellen L. Simms was supported by National Science Foundation award DEB-0645791. Funding Information: This work was assisted through participation in the “Strategies for the Black Box: Mathematical tools for plant–soil interactions” Investigative Workshop at the National Institute for Mathematical and Biological Synthesis, sponsored by the National Science Foundation through NSF Award #DBI-1300426, with additional support from The University of Tennessee, Knoxville. Alison Bennett and Katharine Preedy were supported by Scottish Government Rural and Environment Science and Analytical Services Division. Antonio J. Golubski was supported by National Science Foundation award DEB-1456927. Jason Hoeksema was supported by National Science Foundation award DEB-1119865. Ellen L. Simms was supported by National Science Foundation award DEB-0645791. The authors would also like to thank Glenn Marion, Christine Hackett, and Philip Smith for comments on the manuscript. Alison E. Bennett, Katharine Preedy, Antonio Golubski, James Umbanhowar, Stuart R. Bor-rett, and Loren Byrne led the writing process. All authors, except Katharine Preedy, attended the “Strategies for the Black Box: Mathematical tools for plant– soil interactions” Investigative Workshop at the National Institute for Mathematical and Biological Synthesis organized by Alison E. Bennett and James Umbanhowar. All authors contributed to the development of Table 1 and helped in writing. Publisher Copyright: © 2019 The Authors.

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N2 - Understanding soil systems is critical because they form the structural and nutritional foundation for plants and thus every terrestrial habitat and agricultural system. In this paper, we encourage increased use of mathematical models to drive forward understanding of interactions in soil ecological systems. We discuss several distinctive features of soil ecosystems and empirical studies of them. We explore some perceptions that have previously deterred more extensive use of models in soil ecology and some advances that have already been made using models to elucidate soil ecological interactions. We provide examples where mathematical models have been used to test the plausibility of hypothesized mechanisms, to explore systems where experimental manipulations are currently impossible, or to determine the most important variables to measure in experimental and natural systems. To aid in the development of theory in this field, we present a table describing major soil ecology topics, the theory previously used, and providing key terms for theoretical approaches that could potentially address them. We then provide examples from the table that may either contribute to important incremental developments in soil science or potentially revolutionize our understanding of plant-soil systems. We challenge scientists and mathematicians to push theoretical explorations in soil systems further and highlight three major areas for the development of mathematical models in soil ecology: Theory spanning scales and ecological hierarchies, processes, and evolution.

AB - Understanding soil systems is critical because they form the structural and nutritional foundation for plants and thus every terrestrial habitat and agricultural system. In this paper, we encourage increased use of mathematical models to drive forward understanding of interactions in soil ecological systems. We discuss several distinctive features of soil ecosystems and empirical studies of them. We explore some perceptions that have previously deterred more extensive use of models in soil ecology and some advances that have already been made using models to elucidate soil ecological interactions. We provide examples where mathematical models have been used to test the plausibility of hypothesized mechanisms, to explore systems where experimental manipulations are currently impossible, or to determine the most important variables to measure in experimental and natural systems. To aid in the development of theory in this field, we present a table describing major soil ecology topics, the theory previously used, and providing key terms for theoretical approaches that could potentially address them. We then provide examples from the table that may either contribute to important incremental developments in soil science or potentially revolutionize our understanding of plant-soil systems. We challenge scientists and mathematicians to push theoretical explorations in soil systems further and highlight three major areas for the development of mathematical models in soil ecology: Theory spanning scales and ecological hierarchies, processes, and evolution.

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Beyond the black box: Promoting mathematical collaborations for elucidating interactions in soil ecology

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