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Nitrogen Contributions from Peanut Residues to Subsequent Crops

Arun Jani, Michael J. Mulvaney, Mahesh Bashyal, and Hardeep Singh

Introduction

Cooperative Extension Services throughout the Southeast recommend that farmers reduce nitrogen (N) fertilization to crops planted after peanut (Arachis hypogaea L.). The N fertilizer replacement value of peanut residues is termed a "peanut N credit" and may result in lower production costs due to reduced fertilizer expenditures. However, field experiments conducted throughout the region have shown that fall- and spring-sown crops planted after peanut generally do not perform any better than when planted after other crops or when peanut hay is removed (Balkcom et al. 2007; Jordan et al. 2008; Meso et al. 2007). These experiments suggest that if there is a peanut N credit, it is too small to affect the performance of subsequent crops. It may be that field observations of peanut N credits are due to mulching effects or crop rotational benefits, but the impact of these factors has not been thoroughly investigated in the Southeast. While peanut residues should not be used as a substitute for N fertilization, retaining peanut residues on the soil surface may protect soil from erosion, enhance water retention and soil organic matter, and improve overall soil quality.

Peanut Nitrogen Credits

Peanut is one of the most economically important row crops in Florida, with approximately 158,000 ac under cultivation and an estimated annual production value of $120 million (FDACS 2017). In addition to peanut's value as a cash crop, peanut residues contain large amounts of N from biological N fixation. During this process, soil bacteria, collectively called rhizobia, penetrate peanut roots and supply the plant with N in exchange for carbon. As peanut residues decompose after harvest, N is released and made available to subsequent crops.

Throughout the peanut-growing region of the United States, Cooperative Extension Services recommend N credits to crops planted after peanut. From Virginia to Oklahoma, including Florida, Alabama, and Georgia, Extension Services recommend reducing N fertilization to subsequent fall- and spring-sown crops by 10–60 lb N/ac (Buntin et al. 2007; Caddel et al. 2006; Harris 2013; Maguire and Heckendorn 2011; Mitchell and Phillips 2010; Wright, Marois, and Sprenkel 2011). Peanut N credits should reduce the N fertilizer requirements needed to meet yield goals of subsequent crops. If all the Florida peanut acreage provided an average of 30 lb N/ac credit to a subsequent crop, that would equate to a savings of 4.74 million lb of mineral N/year in Florida alone, or 10.3 million lb of urea/year worth over $2 million.

There is a lack of scientific evidence to support peanut N credit recommendations in the region (Balkcom et al. 2007; Jordan et al. 2008; Meso et al. 2007). Unanswered questions regarding peanut N credits include:

  • To what crop should the N credit be applied? Should it be applied to a fall-sown crop or a spring-sown crop? Does it matter?
  • Should the N credit be applied to at-plant fertilizer applications or topdress applications?
  • Should the N credit differ based on soil texture and climate (i.e., environment)?
  • Is there still an N credit if peanut residues are removed from the field?
  • Does the N credit differ if residues remain in windrows instead of being distributed using spreaders? Does the amount of residue change the N credit?
  • Do tillage and the timing of incorporation affect the N credit?

This document provides an overview of current, science-based information on peanut N credits to subsequent crops for Extension agents and specialists, regulatory officials, consultants, agricultural professionals, and farmers in the Southeast. It also discusses agronomic management and environmental factors that may contribute to the absence of peanut N credits in the region.

Nitrogen Release from Peanut Residues

The amount of N accumulated by peanut residues is determined by multiplying the percentage of N in residues by the amount of residues produced per acre. By tracking the amount of N released from peanut residues over time, it is possible to estimate how much residue-derived N is potentially available for subsequent crops.

The litterbag method is one common method to track N release from peanut residues. In this method, permeable nylon bags are filled with peanut residues at typical loading rates (3,500–4,000 lb/ac), placed in the field, and collected periodically to determine the amount of N remaining in residues over time. Subtracting the amount of N remaining at any time point from the amount of N remaining at an earlier time point provides an estimate of N released from residues during that period. For example, Figure 1 presents a general schematic diagram that indicates peanut residues would release 14 lb N/ac during a hypothetical wheat crop. This quantity may change depending on residue management practices, which are discussed later in this document.

Schematic calculation of N credits using litterbags. The difference between the amount of N remaining at two different time points is the amount released during that time.
Figure 1. Schematic calculation of N credits using litterbags. The difference between the amount of N remaining at two different time points is the amount released during that time.
Credit: Michael J. Mulvaney, UF/IFAS

Note that litterbags exclude most insects and small animals that would otherwise consume or transport residues (Bradford et al. 2002; Tian et al. 1992; Vreeken-Buijs and Brussaard 1996). Additionally, litterbags serve as a barrier between soil and residues, which slows down decomposition. Therefore, N release from peanut residues would likely be faster under natural conditions when litterbags are not used.

Crop Performance following Peanut

Results from field experiments conducted throughout the Southeast do not provide evidence for peanut N credits. Field studies conducted in Alabama showed that biomass accumulation by a fall-sown rye (Secale cereale L.) cover crop was not affected by the presence of peanut residues in the field (Balkcom et al. 2007). Similar results were observed in Florida where biomass accumulation by an oat (Avena sativa L.) cover crop was not consistently higher following peanut compared to following cotton (Gossypium hirsutum L.) (Zhao et al. 2010). Winter cereals like rye and oat are normally planted about one month after harvesting peanut and are known for their deep root systems and ability to scavenge for nutrients. The unresponsiveness of winter cereals to peanut makes it unsurprising that subsequent spring-sown crops planted several months after harvesting peanut would also be unresponsive. For example, researchers in Alabama showed that cotton yields did not increase when peanut residues were present (Meso et al. 2007). In North Carolina, researchers reported that neither corn (Zea mays L.) nor cotton yields were affected by rotations with or without peanut under both conventional and conservation tillage (Jordan et al. 2008).

Agronomic management and environmental factors may explain the absence of peanut N credits in the region. Management factors that affect N release and availability from peanut residues include tillage, planting time of subsequent crops, and peanut residue loading rate and distribution. Environmental factors, such as temperature, rainfall patterns, and soil nutrient holding capacity, are also important. These management and environmental factors are described in greater detail below.

Tillage and Nitrogen Release

Soil tillage practices affect peanut residue decomposition and N release rates. Incorporating residues with conventional tillage increases microbial access to residues compared to leaving residues on the soil surface. With greater access, soil microorganisms rapidly decompose incorporated residues and release N during the process.

Nitrogen is generally released most rapidly from peanut residues in the weeks immediately following harvest. Release rates will be especially rapid if rainfall is abundant and temperatures are warm, as is often the case during fall in the Southeast. Litterbag experiments in Alabama showed that 48 and 30% of N from incorporated and surface residues, respectively, was released within 30 days after harvest (Mulvaney et al. 2017). A typical peanut residue load of 3,000 lb/ac contains approximately 60 lb N/ac. If a winter cereal is planted on November 1 (approximately 30 days after peanut harvest), then 31 and 42 lb N/ac would remain from incorporated and surface peanut residues, respectively, at the time of planting, but only a fraction of that would be released during the season. The amount of N potentially available from peanut residues to spring-sown crops is smaller. Experiments in Florida and Alabama showed that only 2–8 and 2–16 lb N/ac from fall-incorporated and surface peanut residues, respectively, would be released during a cotton crop planted the following spring (Table 1) (Jani et al. 2019; Mulvaney et al. 2017).

Table 1. Estimates of N released from different quantities of incorporated and surface peanut residues during wheat and cotton crops (Jani et al. 2018; Mulvaney et al. 2017).

Residue Load (lb/ac)

Nitrogen Released during Season (lb N/ac)

Wheat

Cotton

Incorporated Residue

1,000

3

2

2,000

4

3

3,000

18

5

4,000

30

8

6,000

31

4

Surface Residue

1,000

5

2

2,000

11

4

3,000

29

3

4,000

21

10

6,000

36

16

Keep in mind that only a portion of N released from peanut residues during a subsequent crop is actually used by that crop. There are several pathways by which peanut residue N is made unavailable to roots. Nitrogen released from peanut residues can be leached out of the crop root zone with rainfall, a major source of N loss in sandy soils of Florida. In addition, if residues are left on the soil surface under conservation tillage, a portion of N may volatilize. Soil microorganisms also compete with roots for available N, representing another pathway by which N derived from residues becomes unavailable. Considering the different pathways by which N becomes unavailable to plants, it is not surprising that N use efficiency (NUE) by cereals and cotton is estimated to be only 33–44% (Li et al. 2016; Raun and Johnson 1999). The amount of peanut residue N actually used by winter cereals or spring-sown crops such as cotton is likely insufficient to increase yields.

Peanut Residue Distribution and Nitrogen Release

The amount of peanut residue N potentially available for subsequent crops also depends on the quantity of residue left in the field following peanut harvest. Peanut biomass accumulation can vary substantially in the Southeast, ranging from 2,900 to 4,460 lb/ac, which amounts to 41 and 71 lb N/ac, respectively (Jani et al. 2017; Meso et al. 2007). As stated earlier, not all of this N will be available for crops planted after peanut.

Peanut harvest practices create an uneven distribution of residues in the field. Placement of peanut in windrows after digging concentrates residues over a relatively small area. Peanut pickers may not be equipped with residue spreaders. If spreaders are not used, residues will remain in windrows (Figure 2), resulting in large spatial variability of potentially available N for subsequent crops. Farmers often observe a "windrow effect" whereby crops planted after peanut perform best where peanut was windrowed (Figures 3 and 4). Researchers in Florida explored the effects that windrowing may have on spatial variation of residue N in a litterbag experiment. Peanut residues were applied at rates that reflected the postharvest residue distribution gradient when residue spreaders are not used (1,000, 2,000, 4,000, and 6,000 lb/ac). Higher loading rates (4,000 and 6,000 lb/ac) represented areas on or near former windrows, while smaller loading rates (1,000 and 2,000 lb/ac) represented areas farther away from windrows.

Peanut residues are concentrated in former windrows when residue spreaders are not used at harvest.
Figure 2. Peanut residues are concentrated in former windrows when residue spreaders are not used at harvest.
Credit: Arun Jani, UF/IFAS

 

The amount of N remaining from peanut residues over time at four residue loading rates (1,000, 2,000, 4,000, and 6,000 lb/ac) and two placements (buried vs. on surface) in Citra, Florida. A theoretical wheat crop would be planted at day 30 (Jani et al. 2018).
Figure 3. The amount of N remaining from peanut residues over time at four residue loading rates (1,000, 2,000, 4,000, and 6,000 lb/ac) and two placements (buried vs. on surface) in Citra, Florida. A theoretical wheat crop would be planted at day 30 (Jani et al. 2018).
Credit: undefined

 

Carinata (Brassica carinata) crop following peanut. Strips of blooming carinata can be seen on former peanut windrows.
Figure 4. Carinata (Brassica carinata) crop following peanut. Strips of blooming carinata can be seen on former peanut windrows.
Credit: Michael J. Mulvaney, UF/IFAS

Regardless of tillage practice, residues loaded at higher rates (near or on former windrows) supplied substantially more N than smaller residue loading rates (Figure 3). However, at higher loading rates, more N was released rapidly and was subject to environmental losses or consumption by soil microorganisms. As previously mentioned, N release from peanut residues is fastest after harvest, which results in a lack of synchrony between residue N supply and demand by subsequent crops. In the case of a spring-sown crop, most N from peanut residues, even at high loading rates, would likely have already left the rooting zone by spring planting. Therefore, even in areas of the field where peanut residue N supply is high, such as in former windrows, the amount of N available to a subsequent crop is still relatively low under environmental conditions in Florida. The commonly observed "windrow effect" is most likely due to factors unrelated to N, such as greater soil organic matter and moisture retention, lower erosion, and cooler soil temperatures.

Evaluating Peanut N Credits to Winter Carinata

The common definition of ‘N credit’ according to the fertilizer replacement value approach is the N rate required to provide a corn-corn yield equal to that of a soybean-corn yield (Bundy et al., 1993). Usually, when we are evaluating N credits from legumes, we do not take into account, the possibility of N immobilization from non-legumes in rotation. This could potentially play an important role in subsequent crop response to mineral N. There have been few peanut N credit studies with a ‘unfertilized fallow’ as a control in the treatment structures especially in the southeastern US. A lack of true ‘unfertilized fallow’ in a cotton-peanut cropping systems may confound peanut N credits with yield depression after cotton due to potential N immobilization due to cotton residues (Rochester et al., 1993).

Carinata seed yield response to fertilization with 0, 30, 60, 90 and 120 lb. N acre-1 in former peanuts, cotton and fallow plots during 2018-19 and 2019-20 at Jay, FL. Error bars represent standard errors of the mean. Note vertical axis scales are different. Within year and N rate, means that share the same letter are not significantly different at  = 0.05 according to Tukey’s HSD.
Figure 5. Carinata seed yield response to fertilization with 0, 30, 60, 90 and 120 lb. N acre-1 in former peanuts, cotton and fallow plots during 2018-19 and 2019-20 at Jay, FL. Error bars represent standard errors of the mean. Note vertical axis scales are different. Within year and N rate, means that share the same letter are not significantly different at = 0.05 according to Tukey’s HSD.
Credit: undefined

Pairwise comparisons at 0 N indicate that carinata seed yield was lower in former cotton plots compared to former fallow plots in 2019-2020 season at Jay, FL. This inform us that carinata N requirement may vary with cropping history (Figure 5) and there may be a need to increase total N to account for yield depression behind cotton residues, especially under lower N application rates. Nitrogen immobilization due to cotton residues has been previously documented in cotton literature (Rochester et al., 1993). Carinata seed yield behind former peanut plots was similar to unfertilized fallow plots across all N rates across both years at Jay, FL. Corroborating our previous findings, it is likely that a substantial portion of peanut residue N was mineralized rapidly prior to significant carinata N uptake and became unavailable. It is also important to note that there is limited N uptake by carinata during early growth and the expected N credit by peanut therefore did not convey to biomass or yield. However, it is worth bearing in mind that we may expect N credit in areas with delayed N mineralization from peanut residues caused by extended periods of low rainfall (Hemwong et al., 2008) or cold weather.

Conclusion

There is not enough evidence to support current peanut N credit recommendations in the Southeast. Nitrogen is released rapidly from peanut residues, and it moves quickly through light-textured soils found in this region. Only a relatively small amount of N from peanut residues is available when subsequent crops need it.

References

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Peer Reviewed

Publication #SS-AGR-432

Release Date:January 24, 2023

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About this Publication

This document is SS-AGR-432, one of a series of the Agronomy Department, UF/IFAS Extension. Original publication date April 2019. Revised January 2023. Visit the EDIS website at https://edis.ifas.ufl.edu for the currently supported version of this publication.

About the Authors

Arun Jani, PhD candidate; and Michael J. Mulvaney, assistant professor, Agronomy Department; UF/IFAS West Florida Research and Education Center, Jay, FL 32565.

Contacts

  • Hardeep Singh