Peak grain forecasts for the US High Plains amid withering waters

Assaad Mrad; Gabriel G. Katul; Delphis F. Levia; Andrew J. Guswa; Elizabeth W. Boyer; Michael Bruen; Darryl E. Carlyle-Moses; Rachel Coyte; Irena F. Creed; Nick Van De Giesen; Domenico Grasso; David M. Hannah; Janice E. Hudson; Vincent Humphrey; Shin'Ichi Iida; Robert B. Jackson; Tomo'Omi Kumagai; Pilar Llorens; Beate Michalzik; Kazuki Nanko; Catherine A. Peters; John S. Selker; Doerthe Tetzlaff; MacIej Zalewski; Bridget R. Scanlon

doi:10.1073/pnas.2008383117

Peak grain forecasts for the US High Plains amid withering waters

Assaad Mrad^*, Gabriel G. Katul, Delphis F. Levia, Andrew J. Guswa, Elizabeth W. Boyer, Michael Bruen, Darryl E. Carlyle-Moses, Rachel Coyte, Irena F. Creed, Nick Van De Giesen, Domenico Grasso, David M. Hannah, Janice E. Hudson, Vincent Humphrey, Shin'Ichi Iida, Robert B. Jackson, Tomo'Omi Kumagai, Pilar Llorens, Beate Michalzik, Kazuki NankoCatherine A. Peters, John S. Selker, Doerthe Tetzlaff, MacIej Zalewski, Bridget R. Scanlon

^*Corresponding author for this work

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

Abstract

Irrigated agriculture contributes 40% of total global food production. In the US High Plains, which produces more than 50 million tons per year of grain, as much as 90% of irrigation originates from groundwater resources, including the Ogallala aquifer. In parts of the High Plains, groundwater resources are being depleted so rapidly that they are considered nonrenewable, compromising food security. When groundwater becomes scarce, groundwater withdrawals peak, causing a subsequent peak in crop production. Previous descriptions of finite natural resource depletion have utilized the Hubbert curve. By coupling the dynamics of groundwater pumping, recharge, and crop production, Hubbert-like curves emerge, responding to the linked variations in groundwater pumping and grain production. On a state level, this approach predicted when groundwater withdrawal and grain production peaked and the lag between them. The lags increased with the adoption of efficient irrigation practices and higher recharge rates. Results indicate that, in Texas, withdrawals peaked in 1966, followed by a peak in grain production 9 y later. After better irrigation technologies were adopted, the lag increased to 15 y from 1997 to 2012. In Kansas, where these technologies were employed concurrently with the rise of irrigated grain production, this lag was predicted to be 24 y starting in 1994. In Nebraska, grain production is projected to continue rising through 2050 because of high recharge rates. While Texas and Nebraska had equal irrigated output in 1975, by 2050, it is projected that Nebraska will have almost 10 times the groundwater-based production of Texas.

Original language	English
Pages (from-to)	26145-26150
Number of pages	6
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	117
Issue number	42
DOIs	https://doi.org/10.1073/pnas.2008383117
Publication status	Published - 20 Oct 2020

Keywords

Crop production
Groundwater
Hubbert curve
Ogallala aquifer
Peak water

ASJC Scopus subject areas

General

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1073/pnas.2008383117

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Mrad, A., Katul, G. G., Levia, D. F., Guswa, A. J., Boyer, E. W., Bruen, M., Carlyle-Moses, D. E., Coyte, R., Creed, I. F., Van De Giesen, N., Grasso, D., Hannah, D. M., Hudson, J. E., Humphrey, V., Iida, SI., Jackson, R. B., Kumagai, TO., Llorens, P., Michalzik, B., ... Scanlon, B. R. (2020). Peak grain forecasts for the US High Plains amid withering waters. Proceedings of the National Academy of Sciences of the United States of America, 117(42), 26145-26150. https://doi.org/10.1073/pnas.2008383117

@article{ff9eda91ce2f4095b5a8cfe3c370c18c,

title = "Peak grain forecasts for the US High Plains amid withering waters",

abstract = "Irrigated agriculture contributes 40% of total global food production. In the US High Plains, which produces more than 50 million tons per year of grain, as much as 90% of irrigation originates from groundwater resources, including the Ogallala aquifer. In parts of the High Plains, groundwater resources are being depleted so rapidly that they are considered nonrenewable, compromising food security. When groundwater becomes scarce, groundwater withdrawals peak, causing a subsequent peak in crop production. Previous descriptions of finite natural resource depletion have utilized the Hubbert curve. By coupling the dynamics of groundwater pumping, recharge, and crop production, Hubbert-like curves emerge, responding to the linked variations in groundwater pumping and grain production. On a state level, this approach predicted when groundwater withdrawal and grain production peaked and the lag between them. The lags increased with the adoption of efficient irrigation practices and higher recharge rates. Results indicate that, in Texas, withdrawals peaked in 1966, followed by a peak in grain production 9 y later. After better irrigation technologies were adopted, the lag increased to 15 y from 1997 to 2012. In Kansas, where these technologies were employed concurrently with the rise of irrigated grain production, this lag was predicted to be 24 y starting in 1994. In Nebraska, grain production is projected to continue rising through 2050 because of high recharge rates. While Texas and Nebraska had equal irrigated output in 1975, by 2050, it is projected that Nebraska will have almost 10 times the groundwater-based production of Texas.",

keywords = "Crop production, Groundwater, Hubbert curve, Ogallala aquifer, Peak water",

author = "Assaad Mrad and Katul, {Gabriel G.} and Levia, {Delphis F.} and Guswa, {Andrew J.} and Boyer, {Elizabeth W.} and Michael Bruen and Carlyle-Moses, {Darryl E.} and Rachel Coyte and Creed, {Irena F.} and {Van De Giesen}, Nick and Domenico Grasso and Hannah, {David M.} and Hudson, {Janice E.} and Vincent Humphrey and Shin'Ichi Iida and Jackson, {Robert B.} and Tomo'Omi Kumagai and Pilar Llorens and Beate Michalzik and Kazuki Nanko and Peters, {Catherine A.} and Selker, {John S.} and Doerthe Tetzlaff and MacIej Zalewski and Scanlon, {Bridget R.}",

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month = oct,

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doi = "10.1073/pnas.2008383117",

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journal = "Proceedings of the National Academy of Sciences of the United States of America",

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Mrad, A, Katul, GG, Levia, DF, Guswa, AJ, Boyer, EW, Bruen, M, Carlyle-Moses, DE, Coyte, R, Creed, IF, Van De Giesen, N, Grasso, D, Hannah, DM, Hudson, JE, Humphrey, V, Iida, SI, Jackson, RB, Kumagai, TO, Llorens, P, Michalzik, B, Nanko, K, Peters, CA, Selker, JS, Tetzlaff, D, Zalewski, M & Scanlon, BR 2020, 'Peak grain forecasts for the US High Plains amid withering waters', Proceedings of the National Academy of Sciences of the United States of America, vol. 117, no. 42, pp. 26145-26150. https://doi.org/10.1073/pnas.2008383117

TY - JOUR

T1 - Peak grain forecasts for the US High Plains amid withering waters

AU - Mrad, Assaad

AU - Katul, Gabriel G.

AU - Levia, Delphis F.

AU - Guswa, Andrew J.

AU - Boyer, Elizabeth W.

AU - Bruen, Michael

AU - Carlyle-Moses, Darryl E.

AU - Coyte, Rachel

AU - Creed, Irena F.

AU - Van De Giesen, Nick

AU - Grasso, Domenico

AU - Hannah, David M.

AU - Hudson, Janice E.

AU - Humphrey, Vincent

AU - Iida, Shin'Ichi

AU - Jackson, Robert B.

AU - Kumagai, Tomo'Omi

AU - Llorens, Pilar

AU - Michalzik, Beate

AU - Nanko, Kazuki

AU - Peters, Catherine A.

AU - Selker, John S.

AU - Tetzlaff, Doerthe

AU - Zalewski, MacIej

AU - Scanlon, Bridget R.

PY - 2020/10/20

Y1 - 2020/10/20

N2 - Irrigated agriculture contributes 40% of total global food production. In the US High Plains, which produces more than 50 million tons per year of grain, as much as 90% of irrigation originates from groundwater resources, including the Ogallala aquifer. In parts of the High Plains, groundwater resources are being depleted so rapidly that they are considered nonrenewable, compromising food security. When groundwater becomes scarce, groundwater withdrawals peak, causing a subsequent peak in crop production. Previous descriptions of finite natural resource depletion have utilized the Hubbert curve. By coupling the dynamics of groundwater pumping, recharge, and crop production, Hubbert-like curves emerge, responding to the linked variations in groundwater pumping and grain production. On a state level, this approach predicted when groundwater withdrawal and grain production peaked and the lag between them. The lags increased with the adoption of efficient irrigation practices and higher recharge rates. Results indicate that, in Texas, withdrawals peaked in 1966, followed by a peak in grain production 9 y later. After better irrigation technologies were adopted, the lag increased to 15 y from 1997 to 2012. In Kansas, where these technologies were employed concurrently with the rise of irrigated grain production, this lag was predicted to be 24 y starting in 1994. In Nebraska, grain production is projected to continue rising through 2050 because of high recharge rates. While Texas and Nebraska had equal irrigated output in 1975, by 2050, it is projected that Nebraska will have almost 10 times the groundwater-based production of Texas.

AB - Irrigated agriculture contributes 40% of total global food production. In the US High Plains, which produces more than 50 million tons per year of grain, as much as 90% of irrigation originates from groundwater resources, including the Ogallala aquifer. In parts of the High Plains, groundwater resources are being depleted so rapidly that they are considered nonrenewable, compromising food security. When groundwater becomes scarce, groundwater withdrawals peak, causing a subsequent peak in crop production. Previous descriptions of finite natural resource depletion have utilized the Hubbert curve. By coupling the dynamics of groundwater pumping, recharge, and crop production, Hubbert-like curves emerge, responding to the linked variations in groundwater pumping and grain production. On a state level, this approach predicted when groundwater withdrawal and grain production peaked and the lag between them. The lags increased with the adoption of efficient irrigation practices and higher recharge rates. Results indicate that, in Texas, withdrawals peaked in 1966, followed by a peak in grain production 9 y later. After better irrigation technologies were adopted, the lag increased to 15 y from 1997 to 2012. In Kansas, where these technologies were employed concurrently with the rise of irrigated grain production, this lag was predicted to be 24 y starting in 1994. In Nebraska, grain production is projected to continue rising through 2050 because of high recharge rates. While Texas and Nebraska had equal irrigated output in 1975, by 2050, it is projected that Nebraska will have almost 10 times the groundwater-based production of Texas.

KW - Crop production

KW - Groundwater

KW - Hubbert curve

KW - Ogallala aquifer

KW - Peak water

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U2 - 10.1073/pnas.2008383117

DO - 10.1073/pnas.2008383117

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AN - SCOPUS:85093817934

SN - 0027-8424

VL - 117

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EP - 26150

JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

IS - 42

ER -

Peak grain forecasts for the US High Plains amid withering waters

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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