Next Article in Journal
Methylmercury Exposure Induces Sexual Dysfunction in Male and Female Drosophila Melanogaster
Next Article in Special Issue
Dietary Inflammatory Index and Cardiometabolic Risk Parameters in Overweight and Sedentary Subjects
Previous Article in Journal
Association between Long-Term Exposure to Particulate Matter Air Pollution and Mortality in a South Korean National Cohort: Comparison across Different Exposure Assessment Approaches
Previous Article in Special Issue
Consumption of Energy Drinks among Undergraduate Students in Taiwan: Related Factors and Associations with Substance Use
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
IJERPH
Volume 14
Issue 10
10.3390/ijerph14101106
ijerph-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Agricultural Capacity to Increase the Production of Select Fruits and Vegetables in the US: A Geospatial Modeling Analysis

by
Zach Conrad
1,*,
Christian J. Peters
2,
Kenneth Chui
3,
Lisa Jahns
1 and
Timothy S. Griffin
2
1
Grand Forks Human Nutrition Research Center, US Department of Agriculture, Agricultural Research Service, 2420 2nd Avenue N, Grand Forks, ND 58203, USA
2
Friedman School of Nutrition Science and Policy, Tufts University, 150 Harrison Ave. Boston, MA 02111, USA
3
School of Medicine, Tufts University, 136 Harrison Ave. Boston, MA 02111, USA
*
Author to whom correspondence should be addressed.
Int. J. Environ. Res. Public Health 2017, 14(10), 1106; https://doi.org/10.3390/ijerph14101106
Submission received: 7 September 2017 / Revised: 18 September 2017 / Accepted: 22 September 2017 / Published: 23 September 2017
(This article belongs to the Special Issue Nutrition and Public Health)
Browse Figures
Versions Notes

Abstract

:
The capacity of US agriculture to increase the output of specific foods to accommodate increased demand is not well documented. This research uses geospatial modeling to examine the capacity of the US agricultural landbase to increase the per capita availability of an example set of nutrient-dense fruits and vegetables. These fruits and vegetables were selected based on nutrient content and an increasing trend of domestic production and consumption. Geographic information system models were parameterized to identify agricultural land areas meeting crop-specific growing requirements for monthly precipitation and temperature; soil depth and type; cropland availability; and proximity to existing production centers. The results of these analyses demonstrate that crop production can be expanded by nearly 144,000 ha within existing national production centers, generating an additional 0.05 cup-equivalents of fruits and vegetables per capita per day, representing a 1.7% increase above current total F&V availability. Expanding the size of national crop production centers can further increase the availability of all F&V by 2.5%–5.4%, which is still less than the recommended amount. Challenges to increasing F&V production in the US include lack of labor availability, barriers to adoption among producers, and threats to crop yields from environmental concerns.

1. Introduction

American consumers depend almost entirely on imports for some of their favorite foods, like cocoa and coffee [1,2], yet despite the growing importance of international food markets, the US still produces most of the food that the population consumes [1,3]. Therefore, increased consumer demand for many types of food, particularly perishables, would likely spur increased domestic production of agricultural goods. However, the capacity of US agriculture to increase the output of specific foods to accommodate increased demand is not well documented.
One way that shifts in consumer food demand may occur is if Americans improved their diet quality. Adequate fruit and vegetable (F&V) consumption is now a mainstay of the Dietary Guidelines for Americans [4] because of the relationship between regular consumption and the reduced risk of chronic disease [5]. Despite routine public health messaging and an ongoing national campaign [6] to increase F&V consumption, there has not been a meaningful improvement in consumption patterns for decades [7]. Yet, although Americans continue to fall far short of meeting recommended daily F&V consumption amounts [8], modest increases have recently been documented [8,9].
If Americans consumed more F&V, domestic production would likely increase to some degree because nearly one-half of the fruits and two-thirds of the vegetables consumed in the US are produced domestically [1,3]. While yield improvements from technological innovations (e.g., improved disease and pest resistance and improved fruit set) and the adoption of intensive management practices (e.g., high density planting and global positioning systems) are largely responsible for recent increases in F&V production, the viability of these approaches is dependent on the availability of suitable agricultural land [10,11]. Because many F&V crops require highly specific growing conditions, identifying suitable agricultural sites is of primary importance to increasing production.
A growing body of research has examined the connection between F&V demand (actual and potential), agricultural land use, and food production at different spatial scales. Giombolini et al. [12] found that the Willamette Valley in Oregon produced enough food to meet approximately 20%–30% and 10%–30% of the Willamette Valley population’s fruit and vegetable recommendations, respectively, as part of a complete diet. Kremer and Shrueder [13] estimated that the Philadelphia foodshed (which represents 37 counties around Philadelphia that have farms that supply food to the city’s residents) produces more than enough F&V to meet the current and recommended consumption amounts of the city’s residents. In Detroit (MI), Colasanti and Hamm [14] found that vacant land areas could produce enough F&V to meet 42% and 76% of current fresh fruit and vegetable consumption, respectively, of the city’s residents, using food storage and season extension technologies. Peters et al. [15] estimated that if the share of the population in New York State consuming local food increased, it was more likely that land in the state would be allocated to higher value crops like F&V at the expense of grains and dairy. At the national level, Young and Kantor [16] estimated that an additional 5–7 million acres (2–2.8 million hectares) of land would be need to be cultivated in order for the population to meet F&V consumption recommendations; later, Buzby et al. [17] updated this estimate to 13 million acres (5.3 million hectares). These studies present useful methodologies for estimating the agricultural capacity to increase the production of F&V for the general population at different spatial scales, but there remains is limited information on the agricultural capacity to increase the production of specific F&V that provide nutrients of public health concern. This research is needed to identify specific sites for viable crop production, and to better understand how crop growth requirements and geospatial land use constraints (i.e., availability of zoned agricultural land not currently cultivated) may impact the availability of food and nutrients for consumers.
The goal of this study was to examine the capacity of the US agricultural land base to increase the per capita availability of selected F&V. We chose a specific set of F&V as an example based on their contribution of nutrients of public health importance. Our approach is innovative in that it uses a series of geospatial models that are parameterized for precipitation, temperature, soil depth, soil type, and land availability. In addition, we recognize that supply chain infrastructure is needed to accommodate increased agricultural production, so we focus on areas in and around current production centers because these co-locate with the requisite supply chain infrastructure.

2. Materials and Methods

2.1. Identifying Nutrient Dense Fruits and Vegetables

The F&V used in this example were identified using an indexing method that computed a nutrient density score for each of 407 F&V [18] on the basis of fiber, calcium, magnesium, and potassium, all nutrients of public health concern [19], per serving. In order to represent F&V most likely to be adopted by consumers and agricultural producers, F&V were further restricted to those with positive trends of consumption [20] and production [21] over the most recent five year period, based on the slope of a simple regression equation that plotted consumption or production amount against time. F&V were further categorized by MyPlate subgroups [22]. In total, two fruits (dates and kiwis) and five vegetables (broccoli, lima beans, sweet potatoes, Great Northern beans, and mushrooms) were included in this analysis.

2.2. Identifying Production Centers

The complex and specialized nature of F&V supply chains means that supply chain enterprises co-locate with areas of high agricultural production [23] (hereafter, production centers).We therefore recognize that increased cultivation of F&V is most likely to occur near current production centers, so we focused our analysis on these areas. For each crop included in this analysis, we identified production centers as counties that represented at least 10% of mean (2002–2012) national acreage [21]. In cases where eligible counties abutted one another, the counties were considered to be a single production center. The seven crops included in this analysis were associated with 11 national production centers located in six states (Table 1).

2.3. Geospatial Modeling

For each F&V in each production center, a site suitability geographic information system (GIS) model was created to identify suitable land areas for crop production in and around each production center (ArcGIS 10.1, Esri, Redlands, CA, USA). Site suitability analyses use crop growing requirements and characteristics of a given land parcel to predict future suitability for crop production in that locale [24]. A key feature of a geospatial site suitability model is the ability to visually overlay multiple maps, with each map depicting a distinct geospatial parameter such as precipitation, temperature, and soil characteristics. A site suitability model allows the user to identify specific locations that simultaneously meet pre-specified conditions for each parameter. For each crop model, data were mapped using a State Plane North American Datum 1983 projected coordinate system that was specific to the locale of each production center. All data were analyzed in raster format with a resolution of 30 m × 30 m.
Land areas were considered to be suitable for the production of a given crop if all of the crop-specific growing conditions were satisfied. Growing conditions for each crop were identified through published reports [25,26,27,28,29,30,31,32,33,34] and subsequently verified by personal communication with farm advisors and plant scientists from the USDA Cooperative Extension System. The following growing conditions were included in this analysis: mean monthly (1981–2010) precipitation and mean monthly (1981–2010) surface temperature (minimum and maximum) were collected from the Parameter-elevation Regressions on Independent Slopes Model, maintained by the PRISM Climate Group at Orgon State University [35,36]; soil depth (minimum) and texture class (particle size) were collected from the Gridded Soil Survey Geographic database, maintained by US Department of Agriculture (USDA) Natural Resources Conservation Service [37]; and land use (fallow agricultural land) was collected from the Cropland Data Layer, maintained by USDA National Agricultural Statistics Service [38]. Only the growing conditions relevant to a given crop were included in a given crop model (Supplementary Tables S1–S10).
In cases where geospatial data lacked sufficient resolution to be parameterized according to the information provided by published reports and personal communication with experts, the range of values for the production center of a given crop were used to represent the growing conditions for that crop. For example, monthly lower and upper temperature bounds for each crop in each production center were established by adopting the monthly minimum and maximum temperature readings, respectively, in that production center. In cases where high resolution geospatial data on crop-specific land use were available [38], we identified clusters of land within counties in which at least 95% of a given crop was cultivated, and used these clusters to establish the monthly lower and upper temperature bounds for that crop.

2.4. Modeling Scenarios

In order to examine the potential to increase food production under scenarios of increased cultivated land area, we constructed a series of buffer areas around each production center that extended 5, 10, 15 and 20 km from all sides of each production center (in other words, increasing the area while maintaining the shape). This resulted in five distinct scenarios: (1) no cropland expansion, (2) 5 km expansion, (3) 10 km expansion, (4) 15 km expansion, and (5) 20 km expansion.

2.5. Estimating Current and Potential Food Availability

State-level crop yield data were collected from USDA Census of Agriculture [21]. Yield data were applied to the land area data generated from the site suitability analysis in order to estimate potential production in and around each production center, on a farm-weight basis. These data were then adjusted for food losses and waste that occur as food moves through the supply chain [20], and were converted to cup-equivalents using the conversion factors provided by the USDA Loss-adjusted Food Availability (LAFA) data series [20]. For the purposes of this analysis, we assumed that all potential food availability would be equally distributed amongst all Americans. Therefore, data on total food availability were divided by the total US population [39] in order to estimate per capita consumption.

3. Results

Figure 1, Figure 2, Figure 3, Figure 4, Figure 5, Figure 6 and Figure 7 display the geospatial results of the site suitability models, and Table 2 displays the tabular results. For each crop, additional suitable cropland was identified within the existing production centers, and the amount of suitable land increased with every 5 km expansion of the production centers. In total, nearly 144,000 ha of suitable land was identified for increased production of dates, kiwis, broccoli, lima beans, sweet potatoes, Great Northern beans, and mushrooms within existing production centers. This increased by 210,000 ha, 281,000 ha, 345,000 ha, and 412,000 ha when production centers were expanded by 5, 10, 15, and 20 km, respectively.
Table 3 displays the daily per capita availability of dates, kiwis, broccoli, lima beans, sweet potatoes, Great Northern beans, and mushrooms if suitable agricultural land circumjacent to each production center were brought into production. Approximately 0.04 additional cups of F&V could be made available to each individual in the US every day without any expansion of existing production centers. This increased by 0.06 cups, 0.09 cups, 0.11 cups, and 0.14 cups per person per day when production centers expanded by 5 km, 10 km, 15 km, and 20 km, respectively.
Nearly all Agaricus mushrooms produced in Chester County (PA) are grown in indoor, climate-controlled environments, thus limiting the parameters used in the geospatial analysis for this crop compared to other crops which are produced in the open. Post hoc sensitivity analyses were therefore conducted by omitting mushrooms from estimates of total suitable agricultural land area and per capita availability of nutrient dense fruits and vegetables. Omitting mushrooms from these analyses reduced total agricultural land area estimates by <1% for each modeling scenario, and attenuated per capita fruit and vegetable availability estimates by 3%–14% for each modeling scenario (data not shown).

4. Discussion

In this national geospatial analysis, we identified enough suitable cropland within existing F&V production centers to moderately increase the daily per capita availability of select F&V in the US. We also identified additional suitable cropland with every 5 km expansion of the production centers. Within existing production centers a total of nearly 144 thousand additional ha of cropland could be brought into production, resulting in an additional 0.04 cup-equivalents of F&V per capita per day. This represents a 1.7% increase over the 2.6 total daily per-capita cup equivalents of all F&V consumed by individuals in the US (Conrad et al., in press) [40] and expanding the production centers of these crops by 5–20 km could increase the daily per capita availability of F&V by 0.06–0.14 cups per day, representing an increase of 2.5%–5.4% over current total F&V availability.
A growing body of research has examined the connection between F&V demand (actual and potential), agricultural land use, and food production at different spatial scales [12,13,14,15,41]. At the national level, Young and Kantor [16] estimated that an additional 5–7 million acres (2–2.8 million hectares) of land would need to be cultivated in order for the population to meet F&V consumption recommendations; later, Buzby et al. [17] updated this estimate to 13 million acres (5.3 million hectares). While our results demonstrate that expansion of some current F&V production centers can moderately increase the total per capita availability of F&V, substantial increases in production would still be needed in order to accommodate population-wide adoption of dietary recommendations for F&V.
Additional production of F&V in the US could be achieved by further expanding the size of the production centers, increasing the number of production centers, converting land currently used for crops like grains and oilseeds to F&V production, and technological innovations to increase F&V crop yields. Indeed, others have demonstrated the potential for agricultural land to be reallocated to higher value crops like F&V at the expense of grains and dairy, based on different land use values across distinct land parcels suitable for the production of distinct crops [15]. Additionally, suitable land areas likely exist for crops other than those included in this analysis, so further increases in F&V production could be achieved by cultivating this land. Yet several factors present challenges to these approaches, such as labor availability, barriers to adoption among producers, and threats to crop yields from environmental concerns.
Access to labor is particularly problematic for F&V operations. The future availability of farmworkers is uncertain given the decline in the number of seasonal, short-term workers since the late 1990s [42], and the declining number of young farm operators entering the agricultural sector [43]. Many F&V crops require specialized knowledge, planning, and management from farm operators in order to ensure adequate production, and the time needed to develop this knowledge and implement these practices could be a barrier to adoption for non-F&V producers [44]. Although mechanization is more common for vegetables than fruit, and for processed produce than for fresh varieties, even crops grown under a mechanized production system may still require field grading and packing by hand [45] and machines cannot replicate the dexterity of farmworkers, which is needed to prevent crop damage that can reduce the market value of harvested crops, particularly those destined for the fresh market [45].
Changes in environmental conditions will also influence the viability of the F&V sector. For example, multi-year drought conditions have reduced water availability in California, threatening the vitality of the largest F&V industry in the country [46]. Reduced crop yields were reported on nearly 1.2 million acres (0.49 million hectares) in 2013 due to a shortage of surface and ground water [47], and aquifer recharge could take many years to reach pre-drought levels [48]. The prospect for increasing F&V production in California is made even more uncertain by the effects of salinization of soil and water sources [49,50], as well as the effects of climate change projections that include altered patterns of precipitation and temperature [51,52,53], all of which have the potential to reduce crop yields [54,55,56].
Even if the challenges associated with increasing domestic production were overcome, imports of F&V would still be essential for meeting increased consumer demand. Imports are needed to smooth out strong seasonal price fluctuations that often result from climatic seasonality or unexpected weather events [57,58]. In cases where the availability of domestically produced F&V lags behind demand (as a result of the time it takes to establish productive orchards and increase labor availability), imported F&V may be able to fill this gap. Indeed, F&V imports have increased steadily since 1975 [59,60].
There are several key strengths to this study. We included a broad range of parameters that allowed for a robust analysis of site suitability. Our models were specific to each crop, which allowed for a higher level of specificity when establishing the upper and lower bounds of the relevant growing conditions than would have been possible if our crop focus was more broadly defined (for example, field crops vs. specialty crops). By narrowing our focus to crops with increasing trends of consumption and domestic production, we were able to identify, based on our assumptions, crops that would be most likely to be adopted by consumers and producers. Finally, we focused our analyses on areas where supply chain infrastructure was likely to be present in order to address the reality that agricultural production requires the co-location of supply chain infrastructure in order for food to reach consumers.
This study has several limitations. It has been reported that recent drought conditions in California have encouraged producers to fallow at least 410,000 acres (166,000 hectares) of cropland [61]. This land could have been identified as suitable cropland by the geospatial models we used in this study, and may have contributed to an overestimation of suitable land area for crops with production centers in California. Data on irrigation limitations were not included due to lack of data availability, so we assessed whether crop-specific water needs were met based on precipitation, which would have resulted in a conservative estimate of suitable land area. This study may not have included all of the production centers for each crop because of limited data availability for some crops in some areas. Incomplete data on the location of national production centers would likely have contributed to an underestimation of suitable land area for some crops. We chose a sample of seven F&V based upon content of specific nutrients, but other F&V also contribute valuable nutrients. Mushrooms, in particular, pose challenges for geospatial analyses because most are produced under climate-controlled production systems, so standard parameters such as precipitation, surface temperature, soil depth, and soil texture class are not relevant. Future research should identify other relevant parameters for mushroom production, such as spatial availability of critical inputs such as substrate (e.g., straw, manure, and peat moss), and explore methods for accurate parameterization in geospatial analyses. Finally, increased supply of F&V may not be distributed equally among all individuals in the US, given limited access to nutritious and affordable food in some communities [62].
Additional research is needed to examine the availability of suitable agricultural land in and around smaller production centers throughout the country in order to fully capture the national potential to increase F&V production. These site suitability analyses could be integrated into existing modeling frameworks [63,64,65] that have been used to examine the capacity of supply chain infrastructure to handle additional volume. This research should focus on the potential to increase production in areas least likely to experience environmental degradation and natural resource limitations.

5. Conclusions

In this geospatial modeling study we show that there is enough suitable agricultural land in and around existing production centers to increase the availability of certain nutrient dense F&V in the US. Yet even greater production of F&V would be needed in order to accommodate increased adherence to dietary guidance, and increased imports will likely be needed. Challenges to increasing F&V production in the US include lack of labor availability, barriers to adoption among producers, and threats to crop yields from environmental concerns. Further research is needed to examine the potential to increase production for a broader range of crops in areas least likely to experience environmental degradation and natural resource limitations.

Supplementary Materials

The following are available online at www.mdpi.com//1660-4601/14/10/1106/s1, Table S1: Growing conditions for dates in Riverside County, California, by month; Table S2: Growing conditions for kiwis in Tulare County, California, by month; Table S3: Growing conditions for kiwis in Butte County, California, by month; Table S4: Growing conditions for broccoli in Monterey County, California, by month; Table S5: Growing conditions for broccoli in Santa Barbara County, California, by month; Table S6: Growing conditions for lima beans in Sussex and Kent Counties, Delaware, by month; Table S7: Growing conditions for sweet potatoes in Johnson, Nash, Sampson, and Wilson Counties, North Carolina, by month; Table S8: Growing conditions for sweet potatoes in Calhoun County, Mississippi, by month; Table S9: Growing conditions for sweet potatoes in Merced County, California, by month; Table S10: Growing conditions for Great Northern beans in Scotts Bluff, Box Butte, and Morrill Counties, Nebraska, by month.

Acknowledgments

This research was partially supported by the United States Department of Agriculture, Agricultural Research Service, 3062-51000-051-00D.

Author Contributions

Zach Conrad conceived and designed the experiments, performed the experiments, and analyzed the data; all authors contributed to the interpretation of study results and the writing of the manuscript, and read and approved the final version.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. US Department of Agriculture, Foreign Agricultural Service. Global Agricultural Trade System. 2017. Available online: https://apps.fas.usda.gov/gats/ExpressQuery1.aspx (accessed on 3 July 2017).
  2. Jerardo, A. The Import Share of US-Consumed Foods Continues to Rise; US Department of Agriculture, Economic Research Service. US Government Printing Office: Washington, DC, USA, 2002.
  3. US Department of Agriculture, Economic Research Service. Loss-Adjusted Food Availability Documentation. Available online: https://www.ers.usda.gov/data-products/food-availability-per-capita-data-system/loss-adjusted-food-availability-documentation/ (accessed on 8 February 2017).
  4. US Department of Health and Human Services and US Department of Agriculture. 2015–2020 Dietary Guidelines for Americans, Chapter 1. Available online: https://health.gov/dietaryguidelines/2015/resources/2015-2020_Dietary_Guidelines.pdf (accessed on 29 March 2016).
  5. Aune, D.; Giovannucci, E.; Boffetta, P.; Fadnes, L.T.; Keum, N.; Norat, T.; Greenwood, D.C.; Riboli, E.; Vatten, L.J.; Tonstad, S. Fruit and vegetable intake and the risk of cardiovascular disease, total cancer and all-cause mortality-a systematic review and dose-response meta-analysis of prospective studies. Int. J. Epidemiol. 2017. [Google Scholar] [CrossRef] [PubMed]
  6. Produce for Better Health Foundation. Fruits and Veggies: More Matters. 2015. Available online: https://www.fruitsandveggiesmorematters.org/ (accessed on 16 March 2015).
  7. Krebs-Smith, S.M.; Reedy, J.; Bosire, C. Healthfulness of the US food supply: Little improvement despite decades of dietary guidance. Am. J. Prev. Med. 2010, 38, 472–477. [Google Scholar] [CrossRef] [PubMed]
  8. Rehm, C.D.; Peñalvo, J.L.; Afshin, A.; Mozaffarian, D. Dietary intake among US adults, 1999–2012. JAMA 2016, 315, 2542–2553. [Google Scholar] [CrossRef] [PubMed]
  9. Wang, D.D.; Leung, C.W.; Li, Y.; Ding, E.L.; Chiuve, S.E.; Hu, F.B.; Willett, W.C. Trends in dietary quality among adults in the United States, 1999 through 2010. JAMA Intern. Med. 2014, 174, 1587–1595. [Google Scholar] [CrossRef] [PubMed]
  10. US Department of Agriculture, Economic Research Service. Fruit and Tree Nuts: Background. Available online: https://www.ers.usda.gov/topics/crops/fruit-tree-nuts/ (accessed on 16 March 2015).
  11. US Department of Agriculture, Economic Research Service. Overview. Available online: https://www.ers.usda.gov/topics/crops/vegetables-pulses.aspx (accessed on 16 March 2015).
  12. Giombolini, K.J.; Chambers, K.J.; Schlegel, S.A.; Dunne, J.B. Testing the local reality: Does the willamette valley growing region produce enough to meet the needs of the local population? A comparison of agriculture production and recommended dietary requirements. Agric. Human Values 2011, 28, 247–262. [Google Scholar] [CrossRef]
  13. Kremer, P.; Schreuder, Y. The feasibility of regional food systems in metropolitan areas: An investigation of Philadelphia’s foodshed. J. Agric. Food Syst. Community Dev. 2012, 2, 171–191. [Google Scholar] [CrossRef]
  14. Colasanti, K.J.A.; Hamm, M.W. Assessing the local food supply capacity of Detroit, Michigan. J. Agric. Food Syst. Community Dev. 2010, 1, 41–58. [Google Scholar] [CrossRef]
  15. Peters, C.J.; Bills, N.L.; Lembo, A.J.; Wilkins, J.L.; Fick, G.W. Mapping potential foodsheds in New York state by food group: An approach for prioritizing which foods to grow locally. Renew. Agric. Food Syst. 2012, 27, 125–137. [Google Scholar] [CrossRef]
  16. Young, C.E.; Kantor, L.S. Moving Toward the Food Guide Pyramid: Implications for US Agriculture; USDA Economic Research Service: Washington, DC, USA, 1999; pp. 403–423.
  17. Buzby, J.C.; Wells, H.F.; Vocke, G. Possible Implications for US Agriculture from Adoption of Select Dietary Guidelines; USDA Economic Research Service: Washington, DC, USA, 2006.
  18. US Department of Agriculture, Agricultural Research Service, Nutrient Data Laboratory. USDA National Nutrient Database for Standard Reference, Release 26. 2015. Available online: https://ndb.nal.usda.gov/ (accessed on 29 March 2016).
  19. US Department of Health and Human Services and US Department of Agriculture. Dietary Guidelines for Americans 2015–2020, Chapter 2. 2015–2020. Available online: https://health.gov/dietaryguidelines/2015/resources/2015-2020_Dietary_Guidelines.pdf (accessed on 15 June 2017).
  20. US Department of Agriculture, Economic Research Service. Loss-Adjusted Food Availability (LAFA) Data Series. 2007–2011. Available online: https://www.ers.usda.gov/data-products/food-availability-per-capita-data-system/loss-adjusted-food-availability-documentation/ (accessed on 29 March 2016).
  21. US Department of Agriculture, National Agricultural Statistics Service. Quick Stats 2.0: Census of Agriculture. US National Level Data. 2002–2012. Available online: https://www.nass.usda.gov/Quick_Stats/ (accessed on 18 March 2015).
  22. USDA Center for Nutrition Policy and Promotion (CNPP). ChooseMyPlate.gov. Available online: http://www.choosemyplate.gov/food-groups/ (accessed on 18 Mar. 2015).
  23. Cook, R.L. Fundamental forces affecting U.S. Fresh produce growers and marketers. Choices: The Magazine of Food, Farm and Resource Issues (Online), 2011. Available online: http://go.galegroup.com/ps/i.do?id=GALE%7CA354272486&v=2.1&u=mlin_m_tufts&it=r&p=AONE&sw=w&asid=7eb7c91df6ea5a74a7c3411a2426bf18 (accessed on 22 September 2017).
  24. Mathews, A.J. Applying geospatial tools and techniques to viticulture. Geogr. Compass 2013, 7, 22–34. [Google Scholar] [CrossRef]
  25. Johnson, G.; Ernest, E.; Kleczewski, N.; Everts, K.; Van Gessel, M.; Whalen, J. Delaware Commercial Vegetable Production Recommendations for 2015; University of Delaware Cooperative Extension Service: Newark, DE, USA, 2015. [Google Scholar]
  26. University of Nebraska-Lincoln. Dry Edible Beans. Available online: http://cropwatch.unl.edu/drybeans (accessed on 20 March 2015).
  27. University of California-Davis, Division of Agriculture and Natural Resources. Kiwifruit in California. Available online: http://fruitandnuteducation.ucdavis.edu/education/fruitnutproduction/Kiwi/ (accessed on 20 March 2015).
  28. Stoddard, C.S.; Davis, R.M.; Cantwell, M.I. Sweetpotato Production in California; University of California Agriculture and Natural Resources: Richmond, CA, USA, 2013; Available online: http://vric.ucdavis.edu/veg_info_crop/sweetpotato.htm (accessed on 22 September 2017).
  29. Dara, S.K.; Klonsky, K.M.; Tumber, K.P. Sample Costs to Produce Fresh Market Broccoli: Central Coast Region—San Luis Obispo County; University of California Cooperative Extension: Davis, CA, USA, 2012. [Google Scholar]
  30. Beutel, J.A. Kiwi Production in California. Available online: http://sfp.ucdavis.edu/pubs/brochures/Kiwi/ (accessed on 20 March 2015).
  31. LeStrange, M.; Cahn, M.D.; Koike, S.T.; Smith, R.F.; Daugovish, O.; Fennimore, S.A.; Natwick, E.T.; Dara, S.K.; Takele, E.; Cantwell, M.I. Broccoli Production in California; University of California Agriculture and Natural Resources: Richmond, CA, USA, 2010. [Google Scholar]
  32. Hodel, D.R.; Johnson, D.V. Imported and American Varieties of Dates (Phoenix Dactylifera) in the United States; University of California Agriculture and Natural Resources: Oakland, CA, USA, 2007. [Google Scholar]
  33. Takele, E.; Mauk, P.; Sharabeen, I. Sample Costs to Establish a Date Palm Orchard and Produce Dates in the Coachella Valley, Riverside County, 2005–2006; University of California Cooperative Extension: Davis, CA, USA, 2007. [Google Scholar]
  34. Beyer, D.M. Basic Procedures for Agaricus Mushroom Growing; Pennsylvania State University, College of Agricultural Sciences, Agricultural Research and Cooperative Extension: University Park, PA, USA, 2003. [Google Scholar]
  35. Oregon State University, PRISM Climate Group. Parameter-Elevation Regressions on Independent Slopes Model (Prism): Monthly Precipitation. 1981–2010. Available online: http://www.prism.oregonstate.edu/normals (accessed on 20 March 2015).
  36. Oregon State University, PRISM Climate Group. Parameter-Elevation Regressions on Independent Slopes Model (Prism): Monthly Minimum and Maximum Temperature. 1981–2010. Available online: http://www.prism.oregonstate.edu/normals (accessed on 20 March 2015).
  37. US Department of Agriculture, Natural Resources Conservation Service. Gridded Soil Survey Geographic (GSSURGO) Database State-Tile Package. 2014. Available online: http://datagateway.nrcs.usda.gov/ (accessed on 20 March 2015).
  38. US Department of Agriculture, National Agricultural Statistics Service. Cropland Data Layer. 2013. Available online: http://datagateway.nrcs.usda.gov/ (accessed on 20 March 2015).
  39. US Department of Commerce, US Census Bureau, Population Division. American Fact Finder: Annual Estimates of the Resident Population. 2015. Available online: https://factfinder.census.gov/faces/nav/jsf/pages/index.xhtml (accessed on 8 July 2017).
  40. Conrad, Z.; Chui, K.; Jahns, L.; Peters, C.J.; Griffin, T.S. Characterizing trends in fruit and vegetable intake in the US by self-report and by supply-and-disappearance data: 2001–2014. Public Health Nutr. 2017, in press. [Google Scholar] [CrossRef] [PubMed]
  41. Peters, C.; Picardy, J.; Darrouzet-Nardi, A.; Wilkins, J.; Griffin, T.; Fick, G. Carrying capacity of U.S. Agricultural land: Ten diet scenarios. Elementa 2016, 4. [Google Scholar] [CrossRef]
  42. Fan, M.; Gabbard, S.; Alves Pena, A.; Perloff, J.M. Why do fewer agricultural workers migrate now? Am. J. Agric. Econ. 2015, 97, 665–679. [Google Scholar] [CrossRef]
  43. US Department of Agriculture, Economic Research Service. Beginning Farmers and Age Distribution of Farmers. Available online: https://www.ers.usda.gov/topics/farm-economy/beginning-disadvantaged-farmers/beginning-farmers-and-age-distribution-of-farmers/ (accessed on 30 June 2017).
  44. Johnson, D.; Krissof, B.; Young, E.; Hoffman, L.; Lucier, G.; Breneman, V. Agronomic and Economic Barriers to Expanding Fruit and Vegetable Production in Eliminating Fruit and Vegetable Planting Restrictions: How Would Markets be Affected? USDA, Economic Research Service: Washington, DC, USA, 2006.
  45. Calvin, L.; Martin, P. The U.S. Produce Industry and Labor: Facing the Future in a Global Economy; USDA Economic Research Service: Washington, DC, USA, 2010.
  46. USDA Economic Research Service. California Drought: Food and Farm Impacts. Available online: http://usda.proworks.com/topics/in-the-news/california-drought-farm-and-food-impacts/ (accessed on 9 May 2015).
  47. USDA National Agricultural Statistics Service (NASS), Census of Agriculture. 2013 Farm and Ranch Irrigation Survey. Table 17. Available online: http://www.agcensus.usda.gov/Publications/Irrigation_Survey/ (accessed on 8 May 2015).
  48. Miller, N.L.; Dale, L.L.; Brush, C.F.; Vicuna, S.D.; Kadir, T.N.; Dogrul, E.C.; Chung, F.I. Drought resilience of the California central valley surface-ground-water-conveyance system. J. Am. Water Resour. Assoc. 2009, 45, 857–866. [Google Scholar] [CrossRef]
  49. Mukherjee, M.; Schwabe, K.A. Where’s the salt? A spatial hedonic analysis of the value of groundwater to irrigated agriculture. Agric. Water Manag. 2014, 145, 110–122. [Google Scholar] [CrossRef]
  50. Schoups, G.; Hopmans, J.W.; Young, C.A.; Vrugt, J.A.; Wallender, W.W.; Tanji, K.K.; Panday, S. Sustainability of irrigated agriculture in the San Joaquin Valley, California. Proc. Natl. Acad. Sci. USA 2005, 102, 15352–15356. [Google Scholar] [CrossRef] [PubMed]
  51. Pierce, D.W.; Das, T.; Cayan, D.R.; Maurer, E.P.; Miller, N.L.; Bao, Y.; Kanamitsu, M.; Yoshimura, K.; Snyder, M.A.; Sloan, L.C.; et al. Probabilistic estimates of future changes in California temperature and precipitation using statistical and dynamical downscaling. Clim. Dyn. 2013, 40, 839–856. [Google Scholar] [CrossRef]
  52. Mehta, V.K.; Haden, V.R.; Joyce, B.A.; Purkey, D.R.; Jackson, L.E. Irrigation demand and supply, given projections of climate and land-use change, in Yolo County, California. Agric. Water Manag. 2013, 117, 70–82. [Google Scholar] [CrossRef]
  53. Joyce, B.A.; Mehta, V.K.; Purkey, D.R.; Dale, L.L.; Hanemann, M. Modifying agricultural water management to adapt to climate change in California’s central valley. Clim. Chang. 2011, 109, 299–316. [Google Scholar] [CrossRef]
  54. Medellín-Azuara, J.; Howitt, R.; MacEwan, D.; Lund, J. Economic impacts of climate-related changes to California agriculture. Clim. Chang. 2011, 109, 387–405. [Google Scholar] [CrossRef]
  55. Hatfield, J.L.; Boote, K.J.; Kimball, B.A.; Ziska, L.H.; Izaurralde, R.C.; Ort, D.; Thomson, A.M.; Wolfe, D. Climate impacts on agriculture: Implications for crop production. Agron. J. 2011, 103, 351–370. [Google Scholar] [CrossRef]
  56. Deschenes, O.; Kolstad, C. Economic impacts of climate change on California agriculture. Clim. Chang. 2011, 109, 365–386. [Google Scholar] [CrossRef]
  57. Plattner, K.; Perez, A.; Thornsbury, S. Evolving U.S. Fruit Markets and Seasonal Grower Price Patterns; USDA Economic Research Service: Washington, DC, USA, 2014.
  58. Huang, S.W. Imports Contribute to Year-Round Fresh Fruit Availability; USDA Economic Research Service: Washington, DC, USA, 2013.
  59. USDA Economic Research Service. Fruit and Tree Nut Yearbook. Tables H3–H7. 2014. Available online: https://www.ers.usda.gov/data-products/fruit-and-tree-nut-data/yearbook-tables.aspx#40989 (accessed on 12 May 2015).
  60. USDA Economic Research Service. Vegetables and Pulses Yearbook. Table 9. 2015. Available online: https://www.ers.usda.gov/data-products/vegetables-and-pulses-data/yearbook-tables.aspx (accessed on 12 May 2015).
  61. Howitt, R.; Medellín-Azuara, J.; MacEwan, D.J.; Lund, J.; Sumner, D. Economic Analysis of the 2014 Drought for California Agriculture. Available online: https://watershed.ucdavis.edu/2014-drought-report (accessed on 12 May 2015).
  62. Ploeg, M.V.; Breneman, V.; Farrigan, T.; Hamrick, K.; Hopkins, D.; Kaufman, P.; Lin, B.-H.; Nord, M.; Smith, T.A.; Williams, R.; et al. Access to Affordable and Nutritious Food–Measuring and Understanding Food Deserts and Their Consequences: Report to Congress; US Department of Agriculture, Economic Research Service: Washington, DC, USA, 2009.
  63. Etemadnia, H.; Goetz, S.J.; Canning, P.; Tavallali, M.S. Optimal wholesale facilities location within the fruit and vegetables supply chain with bimodal transportation options: An LP-MIP heuristic approach. Eur. J. Oper. Res. 2015, 244, 648–661. [Google Scholar] [CrossRef]
  64. Atallah, S.S.; Gomez, M.I.; Bjorkman, T. Localization effects for a fresh vegetable product supply chain: Broccoli in the eastern United States. Food Policy 2014, 49, 151–159. [Google Scholar] [CrossRef]
  65. Nicholson, C.F.; Gómez, M.I.; Gao, O.H. The costs of increased localization for a multiple-product food supply chain: Dairy in the United States. Food Policy 2011, 36, 300–310. [Google Scholar] [CrossRef]
Ijerph 14 01106 g001 550
Figure 1. Suitable agricultural land for dates in Riverside County, California.
Figure 1. Suitable agricultural land for dates in Riverside County, California.
Ijerph 14 01106 g001
Ijerph 14 01106 g002 550
Figure 2. Suitable agricultural land for kiwis in (a) Tulare County, California and (b) Butte County, California.
Figure 2. Suitable agricultural land for kiwis in (a) Tulare County, California and (b) Butte County, California.
Ijerph 14 01106 g002
Ijerph 14 01106 g003 550
Figure 3. Suitable agricultural land for broccoli in (a) Monterey County, California and (b) Santa Barbara County, California.
Figure 3. Suitable agricultural land for broccoli in (a) Monterey County, California and (b) Santa Barbara County, California.
Ijerph 14 01106 g003
Ijerph 14 01106 g004 550
Figure 4. Suitable agricultural land for lima beans in Sussex and Kent Counties, Delaware.
Figure 4. Suitable agricultural land for lima beans in Sussex and Kent Counties, Delaware.
Ijerph 14 01106 g004
Ijerph 14 01106 g005 550
Figure 5. Suitable agricultural land for sweet potatoes in (a) Johnston, Nash, Sampson, and Wilson Counties, North Carolina, (b) Calhoun County, Mississippi, and (c) Merced County, California. Suitable land area for sweet potato production in Calhoun County, Mississippi were identified in this geospatial analysis, but are not clearly visible in Figure 5b due to the small land areas.
Figure 5. Suitable agricultural land for sweet potatoes in (a) Johnston, Nash, Sampson, and Wilson Counties, North Carolina, (b) Calhoun County, Mississippi, and (c) Merced County, California. Suitable land area for sweet potato production in Calhoun County, Mississippi were identified in this geospatial analysis, but are not clearly visible in Figure 5b due to the small land areas.
Ijerph 14 01106 g005
Ijerph 14 01106 g006 550
Figure 6. Suitable agricultural land for Great Northern beans in Scotts Bluff, Box Butte, and Morrill Counties, Nebraska.
Figure 6. Suitable agricultural land for Great Northern beans in Scotts Bluff, Box Butte, and Morrill Counties, Nebraska.
Ijerph 14 01106 g006
Ijerph 14 01106 g007 550
Figure 7. Suitable agricultural land for mushrooms (agaricus) in Chester County, Pennsylvania.
Figure 7. Suitable agricultural land for mushrooms (agaricus) in Chester County, Pennsylvania.
Ijerph 14 01106 g007
Table
Table 1. National production centers of nutrient dense fruits and vegetables.
Table 1. National production centers of nutrient dense fruits and vegetables.
CropMyPlate SubgroupProduction Center
CountyStateProportion of National Acreage (%)
Fruits
Datesn/aRiversideCalifornia55
Kiwisn/aTulareCalifornia35
ButteCalifornia24
Vegetables
BroccoliDark greenMontereyCalifornia39
Santa BarbaraCalifornia20
Lima beansStarchySussex and KentDelaware25
Sweet potatoesRed and orangeJohnston, Nash, Sampson, and WilsonNorth Carolina27
CalhounMississippi12
MercedCalifornia11
Great Northern beansBeans and peasScotts Bluff, Box Butte, and MorrillNebraska70
Mushrooms, AgaricusOtherChesterPennsylvania29
Table
Table 2. Current agricultural land area and potential agricultural land area suitable for the production of nutrient dense fruits and vegetables.
Table 2. Current agricultural land area and potential agricultural land area suitable for the production of nutrient dense fruits and vegetables.
CropCurrently Harvested 1Production Center Expansion 2
No Expansion5 km10 km15 km20 km
103 ha 3
Total148.7143.9209.5280.7344.7412.2
Dates3.06.07.38.69.810.3
Kiwis1.710.114.519.424.630.5
Broccoli54.110.712.114.721.127.6
Lima beans19.23.84.35.16.38.1
Sweet potatoes43.682.7133.9188.7235.3284.5
Great Northern beans26.630.637.143.846.849.7
Mushrooms, Agaricus0.40.10.20.40.81.4
Notes: 1 National mean (2002–2012), Census of Agriculture. 2 Represents distance from all sides of production center. 3 Values are cumulative.
Table
Table 3. Current and potential per capita availability of nutrient dense fruits and vegetables.
Table 3. Current and potential per capita availability of nutrient dense fruits and vegetables.
CropCurrent 1Production center expansion 2
No Expansion5 km10 km15 km20 km
10−3 cup eq. per person per day 3,4
Total84.943.663.586.3110.1138.0
Dates2.43.44.14.85.55.8
Kiwis1.62.73.85.16.58.0
Broccoli42.86.06.88.211.815.4
Lima beans<0.020.20.20.30.30.4
Sweet potatoes11.723.037.051.964.678.0
Great Northern beans5.97.28.710.311.011.7
Mushrooms, Agaricus20.61.22.95.610.318.6
Notes: 1 National mean (2007–2011), Loss-Adjusted Food Availability (LAFA) data series. 2 Represents distance from all sides of production center. 3 Adjusted for losses at the farm, retail, and consumer levels. 4 Values are cumulative.

Share and Cite

MDPI and ACS Style

Conrad, Z.; Peters, C.J.; Chui, K.; Jahns, L.; Griffin, T.S. Agricultural Capacity to Increase the Production of Select Fruits and Vegetables in the US: A Geospatial Modeling Analysis. Int. J. Environ. Res. Public Health 2017, 14, 1106. https://doi.org/10.3390/ijerph14101106

AMA Style

Conrad Z, Peters CJ, Chui K, Jahns L, Griffin TS. Agricultural Capacity to Increase the Production of Select Fruits and Vegetables in the US: A Geospatial Modeling Analysis. International Journal of Environmental Research and Public Health. 2017; 14(10):1106. https://doi.org/10.3390/ijerph14101106

Chicago/Turabian Style

Conrad, Zach, Christian J. Peters, Kenneth Chui, Lisa Jahns, and Timothy S. Griffin. 2017. "Agricultural Capacity to Increase the Production of Select Fruits and Vegetables in the US: A Geospatial Modeling Analysis" International Journal of Environmental Research and Public Health 14, no. 10: 1106. https://doi.org/10.3390/ijerph14101106

APA Style

Conrad, Z., Peters, C. J., Chui, K., Jahns, L., & Griffin, T. S. (2017). Agricultural Capacity to Increase the Production of Select Fruits and Vegetables in the US: A Geospatial Modeling Analysis. International Journal of Environmental Research and Public Health, 14(10), 1106. https://doi.org/10.3390/ijerph14101106

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop