2. Literature Review

Droughts, which account for 14% of extreme weather damages, are particularly damaging to agriculture and have led to large supply shocks in agricultural production (Dhoubhadel, Azzam, and Stockton, Reference Dhoubhadel, Azzam and Stockton2015; Kuwayama et al., Reference Kuwayama, Thompson, Bernknopf, Zaitchik and Vail2019; Leister, Paarlberg, and Lee, Reference Leister, Paarlberg and Lee2015). NOAA NCDC (2020) estimate that in the U.S., each drought costs $9.4 billion on average, primarily due to wasted input for agricultural production and insurance payouts of failed crops. However, most of the analysis on drought cost has focused on damages to agricultural producers. Downstream costs, especially in developed countries with lengthy food production chains, have often been overlooked in drought damage estimation by researchers and policy makers.

The literature has shown that changes in commodity crop prices can lead to retail price changes of processed food products (Berck et al., Reference Berck, Leibtag, Solis and Villas-Boas2009; Richards and Pofahl, Reference Richards and Pofahl2009). The transmitted impact of the 2011 drought on retail peanut butter prices was highlighted by popular press due to the severity of the drought and the drastic increase in both peanut and peanut butter prices (Henry, Reference Henry2011; O’Toole, Reference O’Toole2011). Furthermore, positive asymmetric price transmission after exogenous shocks is commonly found in the empirical literature (Saghaian, Özertan, and Spaulding, Reference Saghaian, Özertan and Spaulding2008). Peltzman (Reference Peltzman2000) establishes positive asymmetric price transmission as the norm rather than the exception for most products. In a meta-analysis, Bakucs, Fałkowski, and Fertő (Reference Bakucs, Fałkowski and Fertő2014) find positive asymmetric price transmission to be more common in agricultural sectors with more governmental support, which is true of the U.S. peanut sector with governmental peanut marketing loans and income support programs (Schnepf, Reference Schnepf2016).

Some of the main theoretical explanations behind positive asymmetric price transmission have been market power (Borenstein, Cameron, and Gilbert, Reference Borenstein, Cameron and Gilbert1997; Meyer and von Cramon-Taubadel, Reference Meyer and von Cramon-Taubadel2004) and menu cost (Ball and Mankiw, Reference Ball and Mankiw1994; Loy, Weiss, and Glauben, Reference Loy, Weiss and Glauben2016; Meyer and von Cramon-Taubadel, Reference Meyer and von Cramon-Taubadel2004). Unlike most food commodities, peanuts operate in a “thin market” with no public futures markets and prices are often set by private contracts between grower and buyers. Thin markets can lead to less competitive and more opaque markets with significant market power throughout the production chain. At the farm level, 80% of peanuts are purchased by two peanut shellers from growers (Schnepf, Reference Schnepf2016), potentially exerting considerable market power for the first stage of peanut butter production. Finally, U.S. food retailers are highly concentrated and exert considerable market and pricing power (Hovhannisyan, Cho, and Bozic, Reference Hovhannisyan, Cho and Bozic2019). The considerable market power throughout the peanut processing chain and other potential factors such menu costs and uncertainty likely lead to positive asymmetric price transmission under which a shock in input costs can lead to persistently heightened final retail prices.Footnote ⁹

This article provides evidence of positive asymmetric price transmission in retail food products after drastic weather-induced supply shocks, an understudied area of the current literature. From a policy perspective, the results further highlight how both the magnitude and duration of retail price changes from the drought can result in significant economic implications for consumers beyond the end of the drought itself.

3. Data

The data set for this article comes from the Information Resources, Inc. (IRI) Consumer Network longitudinal panel data.Footnote ¹⁰ The IRI company provides households with a handheld in-home scanning device and other incentives to record all UPC-based consumer product purchases and tracks the prices and quantity of each item purchased along with household demographics. The purchase information includes quantities, prices, discounts, and coupons used, and household information includes demographic information such as household size, household income, age of household head, ethnicity, race, and presence of children. The households are a representative sample of the whole U.S. and provide comprehensive coverage of U.S. retail prices among different retail channels where consumers shop.Footnote ¹¹ The consumer panel data provide comprehensive prices of retail peanut butter at a wide array of outlets and also contain data on coupons, discounts, and the actual out-of-pocket price paid by consumers.Footnote ¹² The unit of observation in the data set is the product purchased by a specific household at a specific date in a specific store chain in a specific geographic market.

Table 1 shows the average price of peanut butter per pound for the eight different possible retail channels. Retail peanut butter items are cheapest in club stores followed by supercenters and are most expensive in convenience stores. In terms of expenditures, 60% of peanut butter items are purchased at grocery stores followed by 16% of supercenters. At the other end, convenience stores are only responsible for 0.1% of peanut butter products sold.

Table 1. Average retail peanut butter prices and share of expenditures by retail channel

For the first component of the empirical analysis examining retail peanut butter prices, we aggregate the data set to the average price of a specific retail peanut butter item in a specific store chain in a specific geographic market during a specific month (e.g., the average price of a 16 ounce private label’s creamy peanut butter sold at a particular grocery store in the Pittsburgh, PA market during January 2012). The data set contains prices for 2,209 UPC-level peanut butter products at 518 different chains nationwide in 61 markets spanning 11 years for a total of 982,974 observations. For the second part of the empirical analysis examining the impact on consumers, we aggregate the data to total peanut butter expenditure for each household in a specific month.

Table 2 presents the average total expenditure and volume purchased of peanut butter for each household each month broken down by income brackets and shows the average household spends $5.18 per month on peanut butter with higher-income households spending slightly more.

Table 2. Average monthly household peanut butter expenditure and volume by income

4. Methodology

The exogenous and drastic nature of the severe drought presents a quasi-natural experiment framework to causally identify and estimate the short-term (during) and long-term (after) effects of the drought-induced commodity price spike.Footnote ¹³ Specifically, we model the 2011 drought as a discrete treatment and examine the change in retail peanut butter prices during and after the price spike to identify the effect of the drought on retail peanut butter prices. Both Figures 2 and 3 show that farm peanut prices were relatively stable except for the tremendous spike starting in 2011, evidence in support of modeling the drought as a discrete change.

First, we provide further visual evidence on the changes in both farm peanut prices and retail peanut butter prices corresponding to the occurrence of the drought. In Figure 5, we plot the residuals of the log of farm peanut prices after controlling for month fixed effects and the residuals of the log of peanut butter prices after controlling for fixed effects associated with months, store chain, market, and product. Farm peanut prices were generally stable, spiked after October 2011, and stayed high for over a year. Farm peanut prices started to fall in October 2012 but remained higher than pre-shock prices. Around October 2013, 2 years after the start of the price hike, prices dropped back to pre-shock prices and relatively stabilized, with a minor dip, until the end of data set. Farm peanut prices correspond with the drought conditions in 2011, which was drastically higher until a full harvest in 2012, which allowed farm peanut prices to drop back to normal.

Figure 5. Residual plot for farm peanut prices and retail peanut butter prices.

Based on these trends, we separate the data into three periods: pre-shock (January 2008 to September 2011), shock (October 2011 to September 2013), and post-shock (October 2013 to December 2018). We select two full year cycles of peanut production for the shock period as the typical harvest season for peanuts begins in October.Footnote ¹⁴ Examining the prices of peanut butter in Figure 5, we can see that peanut butter prices correspondingly increased with the increase in farm peanut prices. However, the fall in peanut butter prices is much more gradual and does not return to pre-shock levels significantly after peanut prices returned to pre-shock levels. Table 3 separates the average retail peanut butter prices and farm peanut prices into the three periods and presents additional preliminary evidence of the long-term effects of the shock. Farm peanut prices between the pre-shock and post-shock periods are relatively similar, with post-shock period prices even slightly lower. However, post-stock peanut butter prices are higher on average than pre-shock.

Table 3. Average retail peanut butter and farm peanut prices by period

With the preliminary indicators for these periods, we provide further evidence for the period designations by regressing the log of farm peanut prices on indicators of the period designations using equation (1).

(1) $$\log \left( {PeanutFarmPric{e_t}} \right) = {\beta _0} + {\beta _1}shockY{1_t} + {\beta _1}shockY{2_t} + {\beta _3}postshoc{k_t} + t + {\varepsilon _t}$$

We separate the entire time period into: pre-shock, shock, and post-shock, and we further divide the shock period into the first year of the shock, ${shockY{1_t}}$ and second year of the shock, ${shockY{2_t}}$ for a total of 4 time periods: pre-shock, shock year 1, shock year 2, and post-shock.Footnote ¹⁵ ${shockY{1_t}{\rm{\;is\;a\;dummy\;variable\;where\;}}shockY{1_t}}$ is equal to 1 during the first year of the shock, and equal to 0 otherwise. Similarly, ${shockY{2_t}}$ is a dummy variable where ${shockY{2_t}}$ is equal to 1 during the second year of the shock, and equal to 0 otherwise. We use ${postshoc{k_t}}$ as the indicator for the post-shock period, where ${postshoc{k_t}}$ is equal to 1 during the after the shock, and equal to 0 otherwise. Finally, we include a linear time trend to control for any general price increase over time such as inflation. For equation (1), the dependent variable is the national average farm peanut prices at the month level from USDA NASS in Figure 2 with 132 observations. In Table 4, results from the model specified in equation (1) indicate a significant increase in farm peanut prices during both years of the shock period. During the post-shock period, farm peanut prices returned to pre-shock levels given that the coefficient on ${postshoc{k_t}}$ is not significantly different than zero. As we cannot directly interpret the regression coefficient on a dummy variable in a semilogarithmic regression as percentage change (Halvorsen and Palmquist, Reference Halvorsen and Palmquist1980), we use the percentage estimator, ${\Delta \% = \exp \left( \beta \right) - 1}$ , from Halvorsen and Palmquist (Reference Halvorsen and Palmquist1980) to convert the raw estimate results to percentage change. Table 4 shows that compared to the pre-shock period, farm peanut prices were 51% higher during the first year of the shock period and 32% higher during the second year of the shock period. After 2 years, there is no significant difference between pre-shock and post-shock peanut prices. The results of Table 4 provide further evidence that the spike in drought-induced farm peanut prices ended after 2 years.

Table 4. Price change in farm peanuts due to 2011 drought

*** P < 0.01, ** P < 0.05, * P < 0.1.

Notes: Robust standard errors in parentheses. Panel A is the raw estimates of equation (1) examining the percentage difference in prices of farm peanut prices between the pre-shock, shock year 1, shock year 2, and post-shock periods. Panel B converts the estimates to percentage change using Δ ${\% = \exp \left( \beta \right) - 1}$ and reports the percentage change.

For our main specification analyzing the impact of the price spike on retail peanut butter prices, we use the average price at the UPC level for each retail peanut butter item at each store chain at a specific month. We use equation (2) where p indexes UPC-level individual products,Footnote ¹⁶ ${s}$ indexes store chain, ${m}$ indexes geographic markets (similar to Metropolitan Statistical Area), and ${t}$ indexes month.

(2) ${$$\log \left( {PBPric{e_{psmt}}} \right) = {\beta _0} + {\beta _1}shoc{k_t} + {\beta _2}postshoc{k_t} + Seasona{l_t} + UP{C_p} + Chai{n_s} + Marke{t_m} + {\varepsilon _{psmt}}$$}$

The dependent variable ${{\rm{log}}(PBPric{e_{psmt}})}$ is the log of the deflated retail peanut butter price of product ${p}$ in store chain ${s}$ in market ${m}$ during month ${t}$ .Footnote ¹⁷ As discussed in the previous section, we divide the time span into three separate periods of pre-shock, shock, and post-shock with the period shock ranging between October 2011 and September 2013 and post-shock period ranging from October 2013 until the end of the data set. We use ${shoc{k_t}}$ as the indicator for the shock period and ${postshoc{k_t}}$ as the indicator for the post-shock period.

We control for individual UPC product fixed effects, store chain fixed effects, geographical market fixed effects, and seasonal fixed effects at the month of year level. Seasonal fixed effects control for seasonal variation constant across all stores, such as seasonal changes in consumer preferences for peanut butter and seasonal differences in input cost of labor or other peanut butter ingredients. The geographic market fixed effects control for any time constant, market-specific attributes including spatial market powering, regional variation in consumer preferences for peanut butter, and other geographic cost differences. Store chain fixed effects control for any time constant store chain-specific attributes including store chain pricing decisions, or unique bargaining agreements with manufacturers or producers.

Finally, individual UPC product fixed effects control for any product-specific attributes such as unique composition of different peanut butter products and unique pricing strategies for specific peanut butter items. The inclusion of individual product fixed effects also allows our specification to examine the change in the retail prices within a specific peanut butter item, eliminating potential endogeneity from sources such as the unobserved product quality of a peanut butter item, where higher quality peanut butter items are typically priced higher. The coefficients, ${{\beta _1}}$ and ${{\beta _2}}$ , are estimates of interest that measure the changes in retail peanut butter prices during the shock and post-shock periods, respectively.

Furthermore, prices can differ substantially between chains and retail channels, which are typically located in different socioeconomic areas (Bitler and Haider, Reference Bitler and Haider2011). Different chains and retail channels cater to consumers of different demographics and can have different levels of bargaining power with wholesalers. The price transmission to final retail prices can be heterogenous across chains or retail channels with varying degrees of market power and facing different price elasticities. To estimate the heterogenous impact on different retail channels, we extend equation (2) by interacting ${shoc{k_t}}$ and ${postshoc{k_t}}$ with the different retail channels as seen in equation (3).

(3) ${$$\hskip22\log \left( {PBPric{e_{psmt}}} \right) = {\beta _0} + \mathop \sum \limits_{c = 1}^8 {\beta _c}channe{l_s}*shoc{k_t} + \mathop \sum \limits_{k = 9}^{16} {\beta _k}channe{l_s}*postshoc{k_t} + Seasona{l_t} + UP{C_p} + Chai{n_s} + Marke{t_m} + {\varepsilon _{psmt}}$$}$

To estimate if there is a trend in retail prices after the shock and the rate at which prices fall back to pre-shock levels, in equation (4), we replace ${shoc{k_t}}$ and ${postshoc{k_t}}$ with indicators for each year (measured from October to September) during and after the shock, where ${shockY{1_t}}$ and ${shockY{2_t}}$ are the 2 years during the shock period, and ${PostshockY{1_t}}$ , ${PostshockY{2_t}}$ , ${PostshockY{3_t}}$ are year 1, year 2, year 3 after the end of the shock period, respectively.Footnote ¹⁸

(4) ${$$\log \left( {PBPric{e_{psmt}}} \right) = {\beta _0} + {\beta _1}shockY{1_t} + {\beta _2}shockY{2_t} + {\beta _3}PostshockY{1_t} + {\beta _4}PostshockY{2_t} + {\beta _5}PostshockY{3_t} + {\beta _6}PostshockY{4_t}\; + {\beta _7}Postshock{5_t} + Seasona{l_t} + UP{C_p} + Chai{n_s} + Marke{t_m} + {\varepsilon _{psmt}}$$}$

Finally, for equation (5), we extend equation (4) by interacting each year indicator with retail channels to estimate the heterogenous retail price changes in each year.

(5) ${$$\log \left( {PBPric{e_{psmt}}} \right) = {\beta _0} + \mathop \sum \limits_{c = 1}^8 {\beta _c}channe{l_s}*shockY{1_t} + \mathop \sum \limits_{c = 9}^{16} {\beta _c}channe{l_s}*shockY{2_t} + \mathop \sum \limits_{k = 17}^{24} {\beta _k}channe{l_s}*postshockY{1_t} + \mathop \sum \limits_{k = 25}^{32} {\beta _k}channe{l_s}*postshockY{2_t}\mathop \sum \limits_{k = 33}^{40} {\beta _k}channe{l_s}*postshockY{3_t} + \mathop \sum \limits_{k = 41}^{48} {\beta _k}channe{l_s}*postshockY{4_t} + \mathop \sum \limits_{k = 49}^{56} {\beta _k}channe{l_s}*postshockY{5_t} + Seasona{l_t} + UP{C_p} + Chai{n_s} + Marke{t_m} + {\varepsilon _{psmt}}$$}$

To estimate the impact on consumers, we use the data set aggregated to the peanut butter expenditure at the household level. We use equations (6) and (7) to examine the change during the shock and post-shock periods on the deflated total expenditure, ${PBEx{p_{imt}}}$ and total purchased volume of peanut butter, ${\;Totvo{l_{imt}}}$ where ${i}$ indexes households. We control for individual household demographics, ${household\;dem{o_i}}$ , and seasonal and market fixed effects.Footnote ¹⁹ For equation (8), we extend equation (6) by interacting the variables ${shoc{k_t}}$ and ${postshoc{k_t}}$ with the variables ${incom{e_i}}$ to examine the heterogenous impact on households with varying income levels.

(6) ${$$\hskip22\log \left( {PBEx{p_{imt}}} \right) = {\beta _0} + {\beta _1}shoc{k_t} + {\beta _2}postshoc{k_t} + household\;dem{o_i} + Seasona{l_t} + Marke{t_m} + {\varepsilon _{imt}}$$}$

(7) ${$$\hskip22\log \left( {Totvo{l_{imt}}} \right) = {\beta _0} + {\beta _1}shoc{k_t} + {\beta _2}postshoc{k_t} + household\;dem{o_i} + Seasona{l_t} + Marke{t_m} + {\varepsilon _{imt}}$$}$

(8) ${$$\hskip22\log \left( {PBEx{p_{imt}}} \right) = {\beta _0} + \mathop \sum \limits_{c = 1}^{12} {\beta _c}incom{e_i}*shoc{k_t} + \mathop \sum \limits_{c = 13}^{24} {\beta _c}incom{e_i}*postshoc{k_t} + household\;dem{o_i} + Seasona{l_t} + Marke{t_m} + {\varepsilon _{imt}}$$}$