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DECADAL CLIMATE VARIABILITY IMPACTS ON CLIMATE AND CROP YIELDS

Published online by Cambridge University Press:  13 September 2018

THEEPAKORN JITHITIKULCHAI*
Affiliation:
World Bank Group, Bangkok, Thailand
BRUCE A. MCCARL
Affiliation:
Department of Agricultural Economics, Texas A&M University, College Station, Texas
XIMING WU
Affiliation:
Department of Agricultural Economics, Texas A&M University, College Station, Texas
*
*Corresponding author's e-mail: [email protected]
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Abstract

This article examines the effects of ocean-related decadal climate variability (DCV) phenomena on climate and the effects of both climate shifts and independent DCV events on crop yields. We address three DCV phenomena: the Pacific Decadal Oscillation (PDO), the Tropical Atlantic Sea-Surface Temperature Gradient (TAG), and the Western Pacific Warm Pool (WPWP). We estimate the joint effect of these DCV phenomena on the mean, variance, and skewness of crop yield distributions. We found regionally differentiated impacts of DCV phenomena on growing degree days, precipitation, and extreme weather events, which in turn alter distributions of U.S. regional crop yields.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s) 2018

1. Introduction

Ocean-related phenomena have been found to influence climatic conditions over land, and in turn crop yields. El Niño–Southern Oscillation (ENSO) is the most frequently examined case (e.g., see Adams et al., Reference Adams, Chen, McCarl and Weiher1999; Chen and McCarl, Reference Chen and McCarl2000; Hennessy, Reference Hennessy2009a, Reference Hennessy2009b; Mendez, Reference Mendez2013; Tack and Ubilava, Reference Tack and Ubilava2013, among many others). Although many ocean-related studies have been carried out, there are much less studied, longer-term ocean-related phenomena that influence crop yield and agricultural economics. The phenomena are collectively called decadal climate variability (DCV) and generally influence climate and crop yields on at least interdecadal time scales (Mehta, Reference Mehta1998; Mehta, Wang, and Mendoza, Reference Mehta, Wang and Mendoza2013; Murphy et al., Reference Murphy, Kattsov, Keenlyside, Kimoto, Meehl, Mehta, Pohlmann, Scaife and Smith2010; Wang and Mehta, Reference Wang and Mehta2008). Three prominent forms of DCV will be examined here: the Pacific Decadal Oscillation (PDO) (Mantua, Reference Mantua1999; Mantua and Hare, Reference Mantua and Hare2002, Mantua et al., Reference Mantua, Hare, Zhang, Wallace and Francis1997; Smith et al., Reference Smith, Legler, Remigio and O'Brien1999; Ting and Wang, 1997), the Tropical Atlantic Sea-Surface Temperature Gradient (TAG) (Hurrell, Kushnir, and Visbeck, Reference Hurrell, Kushnir and Visbeck2001; Mehta, Reference Mehta1998), and the Western Pacific Warm Pool (WPWP) (Wang and Enfield, Reference Wang and Enfield2001; Wang and Mehta, Reference Wang and Mehta2008; Wang et al., Reference Wang, Enfield, Lee and Landsea2006). The literature indicates that these long-term ocean-related phenomena influence weather patterns and crop yields in the United States.

Fundamentally, these phenomena are defined by general, persistent heat levels in regions of the ocean, which, in turn, affect climate over land. These phenomena also alter the air currents and weather system movement across the country, in turn influencing temperature and rainfall patterns. For example, Murphy et al. (Reference Murphy, Kattsov, Keenlyside, Kimoto, Meehl, Mehta, Pohlmann, Scaife and Smith2010) indicate that DCV phases have been associated with multiyear to multidecade droughts and changes in precipitation patterns.

To the best of our knowledge, there are no nationally scoped published U.S. studies on how the DCV phenomena alter crop yields. This study fills that gap by providing econometric estimates of the impacts of these climate phenomena on yields of corn, cotton, soybeans, and nonirrigated wheat based on U.S. county data. Our hypothesis is that the DCV phenomena directly influence climate, and indirectly crop yields. The null hypothesis addressed in this study is that DCV phenomena do not affect U.S. regional climate and crop yields. The alternative hypothesis is that DCV phenomena do alter climate and crop yields differentially across regions.

Because studies have shown that DCV phenomena influence climate, this means that in a crop yield regression that includes independent variables on climate attributes, part of the effects of the DCV phenomena would already be present in the shifted climate. Therefore, we concluded we would not accurately pick up the full DCV effect on crop yields if we estimated an equation with climate attributes and DCV phase indicators as independent variables. We thus first looked at how climate is displaced by DCV phenomena and then how yields are affected by climate, subsequently integrating the results into a total impact measure. Hence, the estimation is done in two phases. First, we estimate DCV effects on climate attributes where we model shifts in growing degree days, precipitation, drought incidence, hot days, and wet days. Then we proceed to estimate effects on crop yields combining both direct effects and the effects arising from DCV weather displacements. This study uses U.S. county-level crop yield and climate data over the period 1950–2015. The findings suggest that the DCV phenomena influence climate, and that this subsequently influences crop yields across the United States.

2. DCV Background

As stated previously, there are three major DCV phenomena (PDO, TAG, and WPWP). The PDO is a Pacific Ocean phenomenon that has two phases: warm and cold. These are identified based on sea-surface temperatures in the North Pacific Ocean (Mantua et al., Reference Mantua, Hare, Zhang, Wallace and Francis1997; Zhang, Wallace, and Battisti, Reference Zhang, Wallace and Battisti1997). These PDO phases have persisted continuously for 20 to 30 years during the 20th century (Mantua and Hare, Reference Mantua and Hare2002). The PDO has been said to influence weather through heat transfer between the atmosphere and the ocean, and, in turn, this influences winds in the lower troposphere (Murphy et al., Reference Murphy, Kattsov, Keenlyside, Kimoto, Meehl, Mehta, Pohlmann, Scaife and Smith2010). In terms of weather, alternative PDO phases have been found to be associated with periods of prolonged dryness and wetness in the western United States and the Missouri River basin (MRB; Murphy et al., Reference Murphy, Kattsov, Keenlyside, Kimoto, Meehl, Mehta, Pohlmann, Scaife and Smith2010). PDO impacts have been found in Australia and South America (Mantua and Hare, Reference Mantua and Hare2002).

The TAG is a long-lived Atlantic Ocean phenomenon that persists for 12 to 13 years. The TAG has positive and negative phases that are identified through Atlantic sea-surface temperatures (Mehta, Reference Mehta1998). The TAG has been found to be associated with variability in many ocean, atmospheric, and weather items, such as heat transferred between the overlying atmosphere and the Atlantic Ocean; winds in the lower troposphere; and rainfall in the southern, central, and midwestern United States (Murphy et al., Reference Murphy, Kattsov, Keenlyside, Kimoto, Meehl, Mehta, Pohlmann, Scaife and Smith2010).

The WPWP is a western Pacific phenomenon, which changes on a 10- to 15-year period. It again has positive and negative phases that are identified through West Pacific and Indian Ocean surface temperatures (Mehta, Reference Mehta1998). The WPWP has been found to influence weather over the Great Plains and western Corn Belt (Wang and Mehta, Reference Wang and Mehta2008).

Each of these DCV phenomena has two phase combinations. Jointly, the simultaneous combination of the DCV phenomena phases has been found to affect drought and extreme weather events as reviewed in Latif and Barnett (Reference Latif and Barnett1994) and Mehta, Wang, and Mendoza (Reference Mehta, Wang and Mendoza2013). Mehta, Rosenberg, and Mendoza (Reference Mehta, Rosenberg and Mendoza2011) found that DCV phenomena explain 60% to 70% of the total variance in MRB annual precipitation and water supply. They also found that DCV has a large influence on maximum and minimum temperatures.

Simulation and statistical estimations have been carried out on DCV effects in selected regions to examine implications for crop yields, but national-scale statistical investigations have not been done (Ding and McCarl, Reference Ding and McCarl2014; Huang, Reference Huang2014; Mehta, Rosenberg, and Mendoza, Reference Mehta, Rosenberg and Mendoza2011, Reference Mehta, Rosenberg and Mendoza2012). Mehta, Rosenberg, and Mendoza (Reference Mehta, Rosenberg and Mendoza2012) in a simulation analysis found major DCV impacts on dryland corn and wheat yields in the MRB explaining as much as 40%–50% of the variation in average corn and wheat yields in some subregions, and they also found effects on basin-wide average crop yields. Ding and McCarl (Reference Ding and McCarl2014) estimated the yield and groundwater recharge impacts of DCV phase combinations in the Edwards Aquifer region of Texas. They found that DCV phases influence both regional crop yields and recharge, and that adaptive actions based on DCV information have substantial potential economic value.

3. Methods for Modeling DCV Impacts

Many studies have addressed climate impacts on crop yields using econometric or simulation approaches. These have mainly addressed the impacts of climate change or ENSO phases examining effects on means and variances (see Attavanich, Reference Attavanich2011; Attavanich and McCarl, Reference Attavanich and McCarl2014 and the reviews therein; Chen, McCarl, and Schimmelpfennig, Reference Chen, McCarl and Schimmelpfennig2004). Additionally, a few studies have examined effects on higher-order moments like skewness (see Du, Hennessy, and Yu, Reference Du, Hennessy and Yu2012; Hennessy, Reference Hennessy2009a, Reference Hennessy2009b; Tack, Harri, and Coble, Reference Tack, Harri and Coble2012). Consequently, to estimate DCV effects on crop yields, we will use a skew-normal regression approach that yields estimates of effects on mean, variance, and skewness (Azzalini and Capitanio, Reference Azzalini and Capitanio1999; Azzalini and Dalla Valle, Reference Azzalini and Dalla Valle1996; Gupta and Chen, Reference Gupta and Chen2001; Henze, Reference Henze1986).

The skew-normal distribution, denoted by SN(ξ, ω2, α), has the following density:

(1) $$\begin{equation} {f_{SN}}\left( {y;{\rm{\ }}\xi ,{\omega ^2},\alpha } \right) = 2{\rm{\ }}{\omega ^{ - 1}}\varphi \left( z \right)\Phi \left( {\alpha z} \right), \end{equation}$$

for y ∈ ( − ∞, ∞), where z = ω − 1(y − ξ), ξ ∈ ( − ∞, ∞) is a location parameter, ω > 0 is a scale parameter, φ(.) is the normal distribution probability density function, and Φ(.) is the cumulative normal distribution function. The distribution estimate will be skewed to the right when α > 0 and skewed to the left when α < 0. The distribution reduces to a normal distribution when α = 0.

We estimate a linear regression assuming skew-normal error terms,

(2) $$\begin{equation} y = {\beta _0} + {\beta _1}{x_1} + \ldots + {\beta _p}{x_p} + \varepsilon , \end{equation}$$

where x 1. . .xP are independent variables, β0. . .βp are regression coefficients to be estimated, and ε is a skew-normal error term ε ~ SN(0, ω2, α). It follows that the yield distribution is also skew-normal.

The estimation will employ a panel regression model. We follow previous studies in choice of independent variables (Attavanich, Reference Attavanich2011; Attavanich and McCarl, Reference Attavanich and McCarl2014; Chen, McCarl, and Schimmelpfennig, Reference Chen, McCarl and Schimmelpfennig2004; McCarl, Villavicencio, and Wu, Reference McCarl, Villavicencio and Wu2008; Schlenker and Roberts, Reference Schlenker and Roberts2009; Schlenker, Hanemann, and Fisher, Reference Schlenker, Hanemann and Fisher2007). In particular, we include weather variables on growing degree days, precipitation, drought incidence, counts of hot days, and counts of wet days, plus a polynomial time trend as a proxy for technological progress. We also include dummy variables for ENSO state as in Attavanich and McCarl (Reference Attavanich and McCarl2014) and Tack and Ubilava (Reference Tack and Ubilava2013). Finally, we include a series of dummy variables for the joint DCV phase combinations.

Because the literature clearly identifies that climate alters crop yields and that DCV phases alter climate attributes, we wanted first to look at climate effects and then in turn at how they influence crop yield. This led us to estimate DCV effects on climate attributes—growing degree days, precipitation amounts, drought incidence, counts of hot days, and counts of high precipitation days—which in turn influence crop yields. Then we estimated climate and DCV phase effects directly on regional yields. Consequently, to get total effects we used a three-stage procedure where we first estimated regression models for the impacts of DCV phase combinations on the climate descriptors. Then, second, we used regression models for the effects of the DCV phase combinations and realized climate directly on yields. Finally, we calculated the total DCV effects on yields by combining estimates from both the DCV to climate regression models and climate and DCV phase to crop yield regression models.

We addressed DCV phase effects on higher moments of crop yield distributions by applying standard generalized-least square panel regression as in Tack, Harri, and Coble (Reference Tack, Harri and Coble2012). The skewness in crop yields is illustrated in Figure A1 in the online supplementary appendix.

4. Data

We estimated U.S. county-level crop yields for corn, cotton, soybeans, and nonirrigated (dryland) wheat using data from the years 1950–2015. These data came from U.S. Department of Agriculture's National Agricultural Statistics Service (USDA-NASS, 2017) Quick Stats database. The data are summarized in Table A1 in the online supplementary appendix. Note the number of observations varies across crops because of crop incidence and data availability. Most of the county-level climate data came from National Oceanic and Atmospheric Administration (NOAA). This included the following:

  • Station-level temperature and precipitation data were drawn from the NOAA Global Historical Climatology Network Daily (GHCND) database (NOAA, National Climatic Data Center [NCDC], 2017). Historical daily station-level cumulative growing degree days (with temperature in degrees Celsius) and precipitation (in tenths of millimeters) were added up for use in the model. The threshold temperature for a growing degree day for corn and soybeans is 10°C, and for cotton and nonirrigated wheat is 5.5°C. Any temperature below the threshold temperature is set to the threshold temperature before calculating the average. Likewise, the maximum temperature is truncated at 30°C. The growing season weather variables are calculated based on the 6-month period from March through August for corn and soybeans, and the 7-month period April through October for cotton and nonirrigated wheat, following the USDA's usual planting and harvesting dates for major crops (USDA, Economics, Statistics and Market Information System, 2017). We also constructed variables that gave incidence on extremes: (1) the count of hot days during the growing season (i.e., those with maximum temperature greater than 32.22°C [equivalently, 90°F]) and (2) the count of wet days (i.e., the number with more than an inch (25 mm) of precipitation). In turn, county-level data were constructed as a weighted average across all weather stations in that county with the weights being the inverse of the distance to the county centroid.

  • State-level monthly Palmer Drought Severity Index (PDSI) data for the growing season were drawn from the NOAA GHCND database. Values range from −6.0 (extreme drought) to +6.0 (extreme wet conditions) and were averaged across the months in the growing season.

  • The ENSO phase information was drawn from NOAA identifications of ENSO phases determined by the NOAA Oceanic Niño Index (ONI), and we identified the ENSO phases (El Niño, Neutral, and La Niña) present during the sample years. In particular, the NOAA National Centers for Environmental Prediction (2017) classifies a year as an El Niño event when the ONI index is at or above +0.5 for five consecutive months, and La Niña when the index is at or below −0.5 for five consecutive months, with the other years designated as Neutral. We use dummy variables for the El Niño and La Niña phases with Neutral phase as the base case.

  • Allocation of years to the PDO phases was done following Mantua et al. (Reference Mantua, Hare, Zhang, Wallace and Francis1997) using data from NOAA-NCDC. The TAG and WPWP indices were assigned to years using data from NOAA's Extended Reconstructed Sea Surface Temperature (NOAA, Earth System Research Laboratory, 2017) following Reynolds et al. (Reference Reynolds, Rayner, Smith, Stokes and Wang2002).

  • Joint DCV phase combination dummy variables were formed based on the simultaneous combinations of the three individual DCV phenomena phases (as listed in Table 1) following Mehta, Rosenberg, and Mendoza (Reference Mehta, Rosenberg and Mendoza2011, Reference Mehta, Rosenberg and Mendoza2012). This resulted in each year being assigned to one of eight phase combinations (as listed in Table A2 in the online supplementary appendix). These phase combinations were designated as the PDO phase followed by the TAG and WPWP phases, resulting in combinations like (PDO+,TAG−,WPWP−), which refers to the year having a positive phase of PDO and negative phases of TAG and WPWP. Dummy variables were defined for each such combination, excepting (PDO−,TAG−,WPWP−), which became the base case. The least common phase combination occurred 5 years out of 66, and the most common 14 years.

  • We incorporated time trends and region-specific dummy variables following Pinheiro and Bates (Reference Pinheiro and Bates2000), McCarl, Villavicenio, and Wu (Reference McCarl, Villavicencio and Wu2008), Attavanich (Reference Attavanich2011), Attavanich and McCarl (Reference Attavanich and McCarl2014), and Ding and McCarl (Reference Ding and McCarl2014).

Table 1. Variables in Regression Analysis

5. Model Specification

Our panel estimation included both time trend and fixed effects for U.S. counties. Table 1 summarizes the main variables used in regression.

5.1. DCV Effects on Weather

The generalized least squares approach was used for estimating the DCV effects on the continuous climate variables (temperature, precipitation, and the PDSI) under the assumption of a normal error term:

(3a) $$\begin{equation} w = g({X^w},{\alpha ^w}) + u, \end{equation}$$

where w is the dependent climate variable; g(.) is the function to estimate; Xw is a vector of explanatory variables (which are time and its square), dummy variables for ENSO phase as they interact with dummy variables for agricultural regions, interactions of dummy variables for the DCV phase combinations and dummy variables for agricultural regions, and U.S. state dummy variables; αw represents the estimated parameters; and u is a normally distributed error term, which is assumed to have a mean of zero. We then obtain estimates on how much the climate variables are altered under each DCV phase combination, ΔgDCV , which we will use in deriving total effects.

For the climate variables that are count data (i.e., the number of hot days and wet days), we estimate:

(3b) $$\begin{equation} \log({w^*}) = {g^*}({X^{({w^*})}},{\alpha ^{({w^*})}}) + v, \end{equation}$$

where w* is the dependent climate item; g*(.) is a the generalized linear model following Nelder and Wedderburn (Reference Nelder and Wedderburn1972); X w* is a vector of explanatory variables, which are the same as those used in the previous model; αw* is the vector of estimated parameters; and v is assumed to be an asymptotically distributed normal disturbance term with mean of zero. In turn, the estimation yields a measure of the influence of the DCV phase combinations on the count data climate variables (Δg*/ΔDCV) on a regional basis. Again, we use the estimated influence from this later in estimating the total effects on crop yields.

5.2. DCV Effects on Yield

For the crop yields, we estimate a skew-normal regression that relates crop yields to all explanatory variables, including time trend and its square, temperature and its square, precipitation and its square, PDSI and its square, interactions of the ENSO dummy variables and the dummy variables for agricultural regions, and interactions between the dummy variables for DCV phase combinations and the dummy variables for region:

(4) $$\begin{equation} y = f\left( {X,\beta } \right) + \varepsilon , \end{equation}$$

where y is the crop yield; f(.) is the function to estimate; X is a vector of all explanatory variables, which are listed previously and in Table 1; β is the vector of estimated parameters; and ε is the skew-normal distributed disturbance term with zero mean, ε $\scriptsize \begin{array}{@{}*{1}{c}@{}} {{\rm{i}}{\rm{.i}}{\rm{.d}}{\rm{.}}}\\ \sim\\ {} \end{array}{\rm{\ }}SN( {0,{\omega ^2},\alpha } )$. Statistical inference for estimated coefficients is based on their cluster-robust standard errors allowing for intragroup correlation at the state-level, so the approach is made robust to heteroskedasticity and spatially correlated errors. After this estimation, we have ΔfDCV as the regional “direct” effects of DCV on crop yields, which will be combined with the regional DCV effects (“indirect” effects) on climate variables (ΔgDCV) and (Δg*/ΔDCV) in the next section.

5.3. Deriving Total Effects

In the final step, we use the estimated climate and yield effects to determine the total marginal effect of DCV phase combinations considering both the direct yield effects and the indirect effects of DCV phase combination on climate factored in with the effects of climate on yields. Given equations (3a), (3b), and (4), we develop a total marginal effects measure combining the estimated parameters as follows:

(5) $$\begin{equation} \frac{{\Delta y}}{{\Delta DCV}} = \frac{{\Delta f\left( {\hat{y}} \right)}}{{\Delta DCV}} + \mathop \sum \limits_{\forall w} \left( {\frac{{\Delta f\left( {\hat{y}} \right)}}{{\Delta w}}} \right)\left( {\frac{{\Delta g\left( {\hat{w}} \right)}}{{\Delta DCV}}} \right) + \mathop \sum \limits_{\forall {w^*}} \left( {\frac{{\Delta f\left( {\hat{y}} \right)}}{{\Delta {w^*}}}} \right)\left( {\frac{{\Delta {g^*}\left( {{{\hat{w}}^*}} \right)}}{{\Delta DCV}}} \right). \end{equation}$$

Therefore, we have $\Delta f (\hat{y})/\Delta DCV$ as the direct DCV effects, whereas the rest of the right-hand side of equation (5) includes the indirect DCV effects arising through effects on the continuous (w) and discrete (w*) climate variables, respectively. The impacts are evaluated at the regional level by associating them with interactions of regional dummy variables and DCV phase combination variables. We then use a block bootstrap (Tack, Harri, and Coble, Reference Tack, Harri and Coble2012) where whole years are sampled with replacement and the full model—including marginal effects—is estimated within each bootstrapped sample to take into account the cross-equation dependence.

6. Estimation Results and Discussion

6.1. DCV Effects on Climate

The DCV phase combinations are found to significantly affect the climate variables on a regional basis as summarized in Table 2. For example, for the Central U.S. region, which is the largest corn producing region, the (PDO+,TAG−,WPWP−) phase combination increases growing degree days, precipitation, count of hot days (Day Temp>90°), and count of wet days (Day Precip>01). However, the (PDO−,TAG+,WPWP−) increases growing degree days and hot days while decreasing precipitation, drought, and wet days, especially for the MRB and Corn Belt regions. The (PDO−,TAG−,WPWP+) is also found to increase temperature, precipitation, hot days, and wet days in the Central region. We find that in several cases the DCV phase combinations tend to have differing magnitudes of regional effects including changes in sign.

Table 2. Signs of Decadal Climate Variability (DCV) Effects on Climate Attributes for U.S. Study Regions

Notes: Evaluated by comparing with PDO−,TAG−,WPWP− phase as the base case using regression coefficients (P < 0.05) from Table A3 in the online supplementary appendix. CT, Central; MT, Mountains; NE, Northeast; NP, Northern Plains; P, Pacific; SE, Southeast; SP, Southern Plains.

To check the validity of our results, we compare our estimates of DCV effects with those from Mehta, Rosenberg, and Mendoza (Reference Mehta, Rosenberg and Mendoza2012) for the MRB region. They found strong DCV phenomena associations with regional temperature and precipitation. They found that during PDO+, precipitation was above average almost everywhere in the MRB and temperature was lower than average. In the TAG+ phase, they found precipitation was below average almost everywhere and temperature was increased almost everywhere. In terms of WPWP, they found the MRB effects varied geographically and generally had less impact than PDO and TAG. To compare the results, we examine the regions that overlap with the MRB, which are R1: Central (IA, IL, IN, MI, MN, MO, OH, and WI); R2: Mountains (AZ, CO, ID, MT, NM, NV, UT, and WY); and R4: Northern Plains (KS, ND, NE, and SD). We have essentially the same results as in Mehta, Rosenberg, and Mendoza (Reference Mehta, Rosenberg and Mendoza2012), with almost all of our statistically significant terms having the same sign of effects.

Furthermore, we also found our results are not sensitive to the usage of county- or state-level data. The reported results are quantitatively similar to our earlier results obtained using state-level data, as reported in Jithitikulchai (Reference Jithitikulchai2014). The full estimation results using county-level data are reported in Table A3 in the online supplementary appendix.

6.2. Effects on Mean Yields

When we examine effects on mean yields, we get climate and the direct DCV effect results. The results are provided in Tables A4–A5 in the online supplementary appendix. The results on time trend (which is a proxy for technological progress) in Table A4 (in the online supplementary appendix) are consistent with the finding of upward but diminishing trends in U.S. crop yields as found in McCarl, Villavicenio, and Wu (Reference McCarl, Villavicencio and Wu2008) and McCarl et al. (Reference McCarl, Villavicencio, Wu and Huffman2013), among others.

Table 3. Regional Decadal Climate Variability (DCV) Effects on U.S. Crop Yield Distribution Moments

Notes: Evaluated by comparing with PDO−,TAG−,WPWP− phase as the base case using total DCV effect coefficients from Table 4 and Tables A7 and A10 in the online supplementary appendix. CT, Central; MT, Mountains; NE, Northeast; NP, Northern Plains; P, Pacific; SE, Southeast; SP, Southern Plains.

Table 4. Total Decadal Climate Variability (DCV) Impacts on Average Crop Yields by Region

Notes: Yields of all crops are in bushels/harvested acre, except for cotton yield, which is in pounds/harvested acre. Coefficients estimated by Delta method with the cluster-robust P values in parentheses (*P < 0.05; ** P < 0.01; ***P < 0.001). Blanks in some regions imply no significant impacts at 95% statistical confidence.

We find that amounts of higher growing degree day generally have significant linear increasing effects on corn and soybean yields. We find a negative term for growing degree days squared, implying a plateau and then a decrease in yields as the growing degree days rise yet further, as also found for temperature in Schlenker and Roberts (Reference Schlenker and Roberts2009), Attavanich (Reference Attavanich2011), and Attavanich and McCarl (Reference Attavanich and McCarl2014).

The PDSI (which is positive when conditions are wetter) has a significantly positive regressor for nonirrigated wheat, which implies yield decreases when droughts occur (as the index becomes negative). For the effect of extreme high temperature, the frequency of hot days decreases the crop yield of corn and soybeans. The count of wet days has no effects on crop yields except a small positive influence on nonirrigated wheat. In conclusion, for direct effects on crop yield, we find negative impacts of extreme drought events and the growing degree day quadratic term. The results confirm previous findings from McCarl, Villavicencio, and Wu (Reference McCarl, Villavicencio and Wu2008), Attavanich (Reference Attavanich2011), and Attavanich and McCarl (Reference Attavanich and McCarl2014).

6.3. Total Effects of DCV Phase Combinations

Now we combine the direct and climate displacement indirect effects of DCV phase combinations to get total effects. The results (Tables 3–4) indicate that DCV phase combinations have regionally differentiated effects on mean crop yields with both increases and decreases found. Compared with the PDO−,TAG−,WPWP− base case, yield reductions are found for the following: corn in the Central, Northern Plains, and Southern Plains regions for most DCV phase combinations; cotton in the Mountains and Southeast regions especially for (PDO+,TAG−,WPWP−), (PDO+,TAG−,WPWP+), and (PDO+,TAG+,WPWP−); soybeans in the Central, Northern Plains, and Southern Plains regions for almost all DCV phase combinations; and nonirrigated wheat in the Northern Plains and Pacific regions especially for (PDO−,TAG−,WPWP+), (PDO+,TAG+,WPWP−), and (PDO+,TAG+,WPWP+). On the other hand, there are also major positive impacts such as for corn in the Central region under (PDO−,TAG−,WPWP+) and in the Southern Plains under (PDO+,TAG−,WPWP−), (PDO+,TAG−,WPWP+), and (PDO+,TAG+,WPWP−). We also find the direct DCV effects are mostly larger than the indirect DCV effects as presented in Tables A5, A8, and A11 in the online supplementary appendix. Figures A3–A6 (in the online supplementary appendix) illustrate the regional impacts on crop yields. Finally, where our analysis overlaps the Mehta, Rosenberg, and Mendoza (Reference Mehta, Rosenberg and Mendoza2012) MRB studies, we examine the consistency between our and their results and find they are similar. For example, we both find the (PDO+,TAG−,WPWP−) and (PDO−,TAG+,WPWP−) phase combinations associate with decreased corn yields in Central and Northern Plains regions, while the (PDO−,TAG−,WPWP+) phase has positive impacts in the Central region and negative impacts in the Northern Plains region. For nonirrigated wheat, we both find the (PDO+,TAG−,WPWP−) phase increases yields in the Mountains region and the (PDO−,TAG−,WPWP+) phase increases in the Northern Plains region.

6.4. Regional Effects of DCV Phase Combinations on Higher Moments

We also examine DCV phase combination effects on variance and skewness and find that DCV phase combinations alter these in a number of important cases (Table 3). The full results are reported in Tables A6−A11 in the online supplementary appendix. Namely, they have crop yield effects on corn production in the Central, Northern Plains, and Southern Plains regions; cotton in the Mountains, Southeast, and Southern Plains regions; soybeans in the Central, Northern Plains, and Southern Plains regions; and nonirrigated wheat in Mountains, Northern Plains, and Pacific regions.

More specifically for corn, we find that the (PDO+,TAG−,WPWP−), (PDO−,TAG+,WPWP−), and (PDO+,TAG−,WPWP+) phase combinations increase yield variability in the Central region. However, the (PDO−,TAG−,WPWP+) and (PDO+,TAG+,WPWP+) phases decrease yield variance in the Central, Northern Plains, and Southern Plains regions.

For cotton, the (PDO+,TAG−,WPWP−) phase increases variability in the Southeast region, while the (PDO+,TAG−,WPWP+) and (PDO+,TAG+,WPWP+) phases increase it in the Southern Plains region. Additionally, the (PDO+,TAG−,WPWP−), (PDO−,TAG−,WPWP+), (PDO+,TAG−,WPWP+), and (PDO+,TAG+,WPWP−) phase combinations decrease variability in the Mountains region.

For soybeans, all the DCV combinations increase yield variability in the Northern Plains or Southern Plains region. For nonirrigated wheat, the (PDO−,TAG+,WPWP+) and (PDO+,TAG+,WPWP+) phases increase yield variability in the Northern Plains region but decrease variability in Mountains and Pacific regions.

In term of skewness, a positive effect means there is a longer right tail and more concentrated mass of distribution on the left side of the distribution; thus there are relatively more low (below the mean) yield outcomes. For corn, we find that (PDO−,TAG−,WPWP+) and (PDO+,TAG+,WPWP+) phases both increase skewness in the Central region, the principal corn growing region. All DCV phases but (PDO−,TAG+,WPWP−) and (PDO+,TAG−,WPWP+) also increase skewness in the Northern Plains region, another major corn growing region.

For cotton, the (PDO+,TAG−,WPWP−), (PDO−,TAG+,WPWP−), (PDO+,TAG+,WPWP−), and (PDO−,TAG+,WPWP+) phases increase skewness in the Southern Plains region. The (PDO+,TAG−,WPWP+), (PDO+,TAG+,WPWP−), (PDO−,TAG+,WPWP+), and (PDO+,TAG+, WPWP+) phases also increase skewness in the Southeast region.

For soybeans, the (PDO−,TAG−,WPWP+) and (PDO+,TAG+,WPWP+) combinations are found to increase skewness in the Central region, the major soybean producing region. On the other hand, all DCV combinations excepting the (PDO+,TAG+,WPWP+) phase combination decrease soybean yield skewness in the Northern Plains region, another major soybean producing region. For nonirrigated wheat, we find that (PDO−,TAG+,WPWP−) increases skewness in the Mountains region.

7. Conclusion

This study investigates how combinations of DCV phenomena affect climate and crop yields across the United States. We find that DCV phase combinations exert regionally differentiated influences on both climate and crop yields. In terms of yields, large effects are found on corn, cotton, soybeans, and nonirrigated wheat in major producing areas such as the Central, Northern Plains, and Southern Plains regions for corn; the Mountains, Southeast, and Southern Plains regions for cotton; the Central and Northern Plains regions for soybeans; and the Central, Mountains, Northern Plains, and Pacific regions for nonirrigated wheat. Thus, we recommend that developing and disseminating estimates of DCV effects on climate and yield along with preplanting announcements on phase combinations would be of value to farmers and policy makers. Such information could stimulate management and enterprise mix alterations increasing crop productivity, given that DCV phenomena are found to have regionally and crop-differentiated effects on climate and crop yield distributions.

This study is subject to some limitations. A limited set of years were used, and better estimates might arise under a longer period of study. Future research can also include the effects of many other climate-related items such as anthropogenic-forced climate change, variation in solar radiation, and dynamics of jet streams. In addition, the analysis does not distinguish yield effects on irrigated and nonirrigated crops, except for nonirrigated wheat. Finally, although extensions are possible, we feel our findings of significant, regionally differentiated DCV effects merit further work on better forecasting yields and on providing forecast information to support potential producer adjustments in planting along with changes in insurance provisions and policy.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/aae.2018.25

Footnotes

This research was funded by the U.S. Department of Agriculture (USDA), National Institute of Food and Agriculture under Grant 2011-67003-30213 in the NSF-USDA-DOE Earth System Modelling Program, and by the National Oceanic and Atmospheric Administration, Climate Programs Office, Sectoral Applications Research Program under grant NA12OAR4310097. The views expressed in this article are only those of the authors and do not necessarily represent the official views of the grantors or any affiliated organizations.

References

Adams, R.M., Chen, C.C., McCarl, B.A., and Weiher, R.F.. “The Economic Consequences of ENSO Events for Agriculture.” Climate Research 13,3(1999):165–72.Google Scholar
Attavanich, W. “Essays on the Effect of Climate Change on Agriculture and Agricultural Transportation.” Ph.D. dissertation, Texas A&M University, College Station, 2011.Google Scholar
Attavanich, W., and McCarl, B.A.. “How Is CO2 Affecting Yields and Technological Progress? A Statistical Analysis.” Climatic Change 124,4(2014):747–62.Google Scholar
Azzalini, A., and Capitanio, A.. “Statistical Applications of the Multivariate Skew Normal Distribution.” Journal of the Royal Statistical Society 61,3(1999):579602.Google Scholar
Azzalini, A., and Dalla Valle, A.. “The Multivariate Skew-Normal Distribution.” Biometrika 83,4(1996):715–26.Google Scholar
Chen, C.-C., and McCarl, B.A.. “The Value of ENSO Information to Agriculture: Consideration of Event Strength and Trade.” Journal of Agricultural and Resource Economics 25,2(2000):368–85.Google Scholar
Chen, C.‐C., McCarl, B.A., and Schimmelpfennig, D.E.. “Yield Variability as Influenced by Climate: A Statistical Investigation.” Climatic Change 66,2(2004):239–61.Google Scholar
Ding, J., and McCarl, B.A.. “Inter-Decadal Climate Variability in the Edwards Aquifer: Regional Impacts of DCV on Crop Yields and Water Use.” Paper presented at the AAEA's Annual Meeting, Minneapolis, MN, July 27–29, 2014.Google Scholar
Du, X., Hennessy, D.A., and Yu, L.. “Testing Day's Conjecture That More Nitrogen Decreases Crop Yield Skewness.” American Journal of Agricultural Economics 94,1(2012):225–37.Google Scholar
Gupta, A.K., and Chen, T.. “Goodness-of-Fit Tests for the Skew-Normal Distribution.” Communications in Statistics-Simulation and Computation 30,4(2001):907–30.Google Scholar
Hennessy, D.A.Crop Yield Skewness and the Normal Distribution.” Journal of Agricultural and Resource Economics 34,1(2009a):3452.Google Scholar
Hennessy, D.A.Crop Yield Skewness under Law of the Minimum Technology.” American Journal of Agricultural Economics 91,1(2009b):197208.Google Scholar
Henze, N.A Probabilistic Representation of the Skew-Normal Distribution.” Scandinavian Journal of Statistics 13,4(1986):271–75.Google Scholar
Huang, P. “Three Essays on Economic and Societal Implications of Decadal Climate Variability and Fishery Management.” Ph.D. dissertation, Texas A&M University, College Station, 2014.Google Scholar
Hurrell, J.W., Kushnir, Y., and Visbeck, M.. “The North Atlantic Oscillation.” Science 291,5504(2001):603–5.Google Scholar
Jithitikulchai, T. “Essays on Applied Economics and Econometrics: Decadal Climate Variability Impacts on Cropping and Sugar-Sweetened Beverage Demand of Low-Income Families.” Ph.D. dissertation, Texas A&M University, College Station, 2014.Google Scholar
Latif, M., and Barnett, T.P.. “Causes of Decadal Climate Variability over the North Pacific and North America.” Science 266,5185(1994):634–37.Google Scholar
Mantua, N.J.The Pacific Decadal Oscillation and Climate Forecasting for North America.” Climate Risk Solutions 1,1(1999):1013.Google Scholar
Mantua, N.J., and Hare, S.R.. “The Pacific Decadal Oscillation.” Journal of Oceanography 58,1(2002):3544.Google Scholar
Mantua, N.J., Hare, S.R., Zhang, Y., Wallace, J.M., and Francis, R.C.. “A Pacific Interdecadal Climate Oscillation with Impacts on Salmon Production.” Bulletin of the American Meteorological Society 78,6(1997):1069–79.Google Scholar
McCarl, B.A., Villavicencio, X., and Wu, X.. “Climate Change and Future Analysis: Is Stationarity Dying?American Journal of Agricultural Economics 90,5(2008):1241–47.Google Scholar
McCarl, B.A., Villavicencio, X., Wu, X., and Huffman, W.E.. “Climate Change Influences on Agricultural Research Productivity.” Climatic Change 119,3–4(2013):815–24.Google Scholar
Mehta, V.M.Variability of the Tropical Ocean Surface Temperatures at Decadal-Multidecadal Timescales. Part I: The Atlantic Ocean.” Journal of Climate 11,9(1998):2351–75.Google Scholar
Mehta, V.M., Rosenberg, N. J., and Mendoza, K.. “Simulated Impacts of Three Decadal Climate Variability Phenomena on Water Yields in the Missouri River Basin.” Journal of the American Water Resources Association 47,1(2011):126–35.Google Scholar
Mehta, V.M., Rosenberg, N. J., and Mendoza, K.. “Simulated Impacts of Three Decadal Climate Variability Phenomena on Dryland Corn and Wheat Yields in the Missouri River Basin.” Agricultural and Forest Meteorology 152(January 2012):109–24.Google Scholar
Mehta, V.M., Wang, H., and Mendoza, K.. “Decadal Predictability of Tropical Basin Average and Global Average Sea Surface Temperatures in CMIP5 Experiments with the HadCM3, GFDL‐CM2.1, NCAR‐CCSM4, and MIROC5 Global Earth System Models.” Geophysical Research Letters 40,11(2013):2807–12.Google Scholar
Mendez, R.F. “Three Essays on Prequential Analysis, Climate Change, and Mexican Agriculture.” Ph.D. dissertation, Texas A&M University, College Station, 2013.Google Scholar
Murphy, J., Kattsov, V., Keenlyside, N., Kimoto, M., Meehl, G., Mehta, V.M., Pohlmann, H., Scaife, A., and Smith, D.. “Towards Prediction of Decadal Climate Variability and Change.” Procedia Environmental Sciences 1(2010):287304.Google Scholar
National Oceanic and Atmospheric Administration, Earth System Research Laboratory. “NOAA Extended Reconstructed Sea Surface Temperature (SST) V4.” Internet site: http://www.esrl.noaa.gov/psd/data/gridded/data.noaa.ersst.html (Accessed 2017).Google Scholar
National Oceanic and Atmospheric Administration, National Centers for Environmental Prediction. “NOAA Center for Weather and Climate Prediction. Changes to the Oceanic Niño Index (ONI).” Internet site: http://origin.cpc.ncep.noaa.gov/products/analysis_monitoring/ensostuff/ONI_v5.php (Accessed 2017).Google Scholar
National Oceanic and Atmospheric Administration, National Climatic Data Center (NOAA-NCDC). “Monthly Summaries Global Historical Climatology Network (GHCND).” Internet site: https://www.ncdc.noaa.gov/ghcnd-data-access (Accessed 2017).Google Scholar
Nelder, J.A., and Wedderburn, R.W.M.. “Generalized Linear Models.” Journal of the Royal Statistical Society 135,3(1972):370–84.Google Scholar
Pinheiro, J.C., and Bates, D.M.. Linear Mixed-Effects Models: Basic Concepts and Examples. New York: Springer, 2000.Google Scholar
Reynolds, R.W., Rayner, N.A., Smith, T.M., Stokes, D.C., and Wang, W.. “An Improved in Situ and Satellite SST Analysis for Climate.” Journal of Climate 15,13(2002):1609–25.Google Scholar
Schlenker, W., Hanemann, W.M., and Fisher, A.C.. “Water Availability, Degree Days, and the Potential Impact of Climate Change on Irrigated Agriculture in California.” Climatic Change 81,1(2007):1938.Google Scholar
Schlenker, W., and Roberts, M. J.. “Nonlinear Temperature Effects Indicate Severe Damages to US Crop Yields under Climate Change.” Proceedings of the National Academy of Sciences of the United States of America 106,37(2009):15594–98.Google Scholar
Smith, S.R., Legler, D.M., Remigio, M.J., and O'Brien, J.J.. “Comparison of 1997–98 U.S. Temperature and Precipitation Anomalies to Historical ENSO Warm Phases.” Journal of Climate 12,12(1999):3507–15.Google Scholar
Tack, J.B., Harri, A., and Coble, K.. “More than Mean Effects: Modeling the Effect of Climate on the Higher Order Moments of Crop Yields.” American Journal of Agricultural Economics 94,5(2012):1037–54.Google Scholar
Tack, J.B., and Ubilava, D.. “The Effect of El Niño Southern Oscillation on U.S. Corn Production and Downside Risk.” Climatic Change 121,4(2013):689700.Google Scholar
Ting, M., and Wang, H.. “Summertime US Precipitation Variability and Its Relation to Pacific Sea Surface Temperature.” Journal of Climate 10,8(1997):1853–73.Google Scholar
U.S. Department of Agriculture, Economics, Statistics and Market Information System. “Usual Planting and Harvesting Dates for U.S. Field Crops.” Internet site: http://usda.mannlib.cornell.edu/MannUsda/viewDocumentInfo.do?documentID=1251 (Accessed 2017).Google Scholar
U.S. Department of Agriculture, National Agricultural Statistics Service (USDA-NASS). “Data and Statistics: Quick Stats.” Internet site: http://www.nass.usda.gov/Quick_Stats/index.php (Accessed 2017).Google Scholar
Wang, C., and Enfield, D.B.The Tropical Western Hemisphere Warm Pool.” Geophysical Research Letters 28,8(2001):1635–38.Google Scholar
Wang, C., Enfield, D.B., Lee, S., and Landsea, C.W.. “Influences of the Atlantic Warm Pool on Western Hemisphere Summer Rainfall and Atlantic Hurricanes.” Journal of Climate 19,12(2006):3011–28.Google Scholar
Wang, H., and Mehta, V.M.. “Decadal Variability of the Indo-Pacific Warm Pool and Its Association with Atmospheric and Oceanic Variability in the NCEP-NCAR and SODA Reanalyses.” Journal of Climate 21,21(2008):5545–65.Google Scholar
Zhang, Y., Wallace, J.M., and Battisti, D.S.. “ENSO-Like Interdecadal Variability: 1900–93.” Journal of Climate 10,5(1997):1004–20.Google Scholar
Figure 0

Table 1. Variables in Regression Analysis

Figure 1

Table 2. Signs of Decadal Climate Variability (DCV) Effects on Climate Attributes for U.S. Study Regions

Figure 2

Table 3. Regional Decadal Climate Variability (DCV) Effects on U.S. Crop Yield Distribution Moments

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Table 4. Total Decadal Climate Variability (DCV) Impacts on Average Crop Yields by Region

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