Sunn-Hemp Utilized as a Legume Cover Crop for Corn Production

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Sunn-Hemp Utilized as a Legume Cover Crop for Corn Production

Kipling S. Balkcom^a^,* and D. Wayne Reeves^b

^a USDA-ARS, National Soil Dynamics Lab., 411 S. Donahue Dr., Auburn, AL 36832
^b USDA-ARS, J. Phil Campbell Sr.–Natural Resource Conservation Center, 1420 Experiment Station Rd., Watkinsville, GA 30677

^* Corresponding author (kbalkcom{at}ars.usda.gov)

Received for publication July 7, 2004.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

The benefits of winter legumes as cover crops for corn (Zeamays L.) are diminished by the earliness of corn planting inrelation to biomass and N production by the legumes. Tropicallegumes may offer an alternative to winter legumes because theyproduce adequate biomass before corn planting. We determinedthe suitability of ‘Tropic Sunn’ sunn-hemp (Crotalariajuncea L.) as a cover crop for corn on a Compass loamy sand(coarse-loamy, siliceous, subactive, thermic Plinthic Paleudults)in central Alabama using a split-plot treatment structure ina randomized complete block design with four replications from1991 to 1993. Main plots were winter fallow and sunn-hemp plantedin mid-August, and subplots were N (0, 56, 112, and 168 kg Nha^–1) applied to corn 3 weeks after planting (WAP). Sunn-hempbiomass production approximately 14 WAP (first frost) averaged7.6 Mg ha^–1 with an N content of 144 kg ha^–1 inthe first 2 yr of the study. Corn grain yield following sunn-hempaveraged 6.9 Mg ha^–1 whereas yield following winter fallowaveraged 5.7 Mg ha^–1. Grain N averaged 16.3 kg ha^–1greater for corn following sunn-hemp than fallow plots. Beforefirst frost, sunn-hemp produced excellent biomass to serve asa winter cover crop in corn production while producing N equivalentto 58 kg ha^–1 of N fertilizer during the 3-yr period,based on corn yield and N response. Sunn-hemp has potentialto be utilized as an alternative to winter legumes for groundcover and as an N source for a subsequent corn crop in the Southeast.

Abbreviations: WAP, weeks after planting

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

PREVIOUS RESEARCH highlights the benefits of utilizing a winterlegume in a conservation tillage system for corn production(Mitchell and Teel, 1977; Ebelhar et al., 1984; Holderbaum et al., 1990;Decker et al., 1994). Winter legumes provide thesame benefits of grass cover crops including erosion control,improved water infiltration, higher organic C contents, andcooler soil temperatures (Reeves, 1994), while simultaneouslyproducing a source of biologically fixed N for subsequent cropslike corn. The additional N supplied by winter legumes can reduceN fertilizer requirements (Ebelhar et al., 1984; Holderbaum et al., 1990).However, the N contribution of legumes is highlyvariable and depends on species, dry matter production, N concentrationof the legume, indigenous soil N, and time of termination (Holderbaum et al., 1990;Reeves, 1994).

Time of termination has prompted researchers to focus on thesynchrony of N release from legumes with the N uptake of corn(Decker et al., 1994; Stute and Posner, 1995; Mansoer et al., 1997;Vaughan and Evanylo, 1998). In a conservation tillagecorn system, legumes are planted in the fall, allowed to matureover the winter, chemically terminated in the spring, and thencorn is planted into the surface residue. Corn is typicallyplanted early in the growing season, which forces an early terminationdate. A termination date at least 14 d before corn plantingenables soil surface water recharge by planting time (Hargrove and Frye, 1987);however, as a result, biomass production forerosion control is limited and N release may not always synchronizewith rapid N uptake of corn at the six-leaf stage (Magdoff, 1991).Decker et al. (1987) reported higher N percentages withincreased legume top growth the longer the legume was allowedto grow in the spring.

An alternative to winter legumes are adapted tropical legumes,which produce higher biomass contents in temperate climates(Mansoer et al., 1997). Yadvinder et al. (1992) showed thattropical legumes could produce their biomass in a shorter timeperiod compared with winter legumes. Reddy et al. (1986) showedmean biomass yields of 10 Mg ha^–1 for several tropicallegumes across a 3-yr full summer production period with meanN yields of 200 kg ha^–1.

A tropical legume that has been investigated as a green manurecrop and as an intercrop for corn production in the tropicsis sunn-hemp (Lales and Mabbayad, 1983; Jeranyama et al., 2000).‘Tropic Sunn’, a sunn-hemp cultivar, was jointlyreleased by USDA-NRCS and the University of Hawaii Instituteof Tropical Agriculture and Human Resources in 1983. This legumecan produce high amounts of biomass and symbiotic N in an 8-to 12-wk frost-free period (NRCS, 1999). Therefore, our objectivewas to determine if the rapid growth and N accumulation of sunn-hempcould serve as an alternative to winter legumes as a cover cropfor conservation tillage corn production in the southern USA.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

We determined the suitability of Tropic Sunn sunn-hemp as acover crop for corn on a Compass loamy sand at the Alabama AgriculturalExperiment Station's E.V. Smith Research and Extension Centerin Shorter, AL, using a split-plot treatment structure in arandomized complete block design with four replications from1991 to 1993. Main plots were winter fallow and sunn-hemp plantedin mid-August, with N (0, 56, 112, and 168 kg N ha^–1)applied as ammonium nitrate 3 WAP corn as subplots. Three replicationsfrom the fallow and sunn-hemp plots, designated to receive noN, mistakenly received 56 kg N ha^–1 at 3 WAP in 1993.Consequently, those replications were eliminated from the analysisfor that year. Winter weed growth was not controlled in fallowplots. All treatment combinations were in the same locationeach year with no re-randomization of treatments. Subplot dimensionswere 3.7 m wide and 13.7 m long with a 0.3-m buffer betweenplots.

At the initiation of the experiment, in late summer of 1990,each main plot was sampled separately for a routine soil testby compositing 20 soil cores (1.9 cm diam. probe) to correctany nutrient deficiencies that were present in the surface 20cm of soil. Phosphorus, K, and Mg levels were high for eachmain plot based on the Mehlich I extractant (Mehlich, 1953)and the Auburn University Soil Testing Laboratory (Cope et al., 1983).Soil pH, measured in a 1:1 soil/water extract, indicateda recommendation of 0.91 Mg of limestone across the experimentalarea. Dolomitic lime was applied once in late summer of 1990according to Auburn University Soil Testing Laboratory recommendations.Initial soil NH₄–N and NO₃–N concentrations were3.1 and 1.7 mg kg^–1 with an organic matter content of11 g kg^–1. No additional commercial fertilizer was applied,with the exception of N, throughout the study.

All plots were disked, chisel-plowed, disked, and leveled beforesunn-hemp planting each year. Sunn-hemp seed was treated witha commercial cowpea [Vigna unguiculata (L.) Walp.] rhizobiuminoculant and planted at a seeding rate of 56 kg ha^–1on 15 Aug. 1990, 19 Aug. 1991, and 2 Sept. 1992 at a depth of1.3 to 2.5 cm with a grain drill. Grain drill row spacing was17.8 cm in 1990 and 10.2 cm in 1991 and 1992. As a result ofdifferent drill spacings among years, four sunn-hemp rows ofequal length for biomass collected on 6 Nov. 1990 was from a0.44 m² area, and sunn-hemp biomass collected on 8 Nov. 1991was from a 0.31 m² area. Sunn-hemp biomass samples were collectedin 1992, but the samples were misplaced before analysis. Drymatter production was comparable to the previous 2 yr. Abovegroundbiomass samples were oven-dried at 55°C for 72 h, weighed,and ground to pass a 1-mm screen with a Wiley mill¹ (ThomasScientific, Swedesboro, NJ). Subsamples were analyzed for totalN by dry combustion on a LECO CHN-600 analyzer¹ (Leco Corp.,St. Joseph, MI).

Each plot was in-row subsoiled to a depth of 30 cm before plantingcorn (Dekalb 689) on 17 Apr. 1991, 14 Apr. 1992, and 14 Apr.1993. Normal cultural practices to control insects and weedswere followed throughout the season. The center two rows ofeach plot were harvested with a small plot combine on 16 Aug.1991, 24 Aug. 1992, and 19 Aug. 1993, and yields were adjustedto a moisture content of 155 g kg^–1. Total N content wasdetermined on grain subsamples by dry combustion using the sameprocedure as the aboveground biomass samples.

Data were analyzed with year in the model and there were significantyear x treatment interactions on response variables. Therefore,data were analyzed by analysis of variance using a general linearmodel procedure provided by Statistical Analysis System (SASInst., 2001) within each year, with data and discussion presentedby year. The simplest best-fit linear or quadratic regressionequations determined by the regression procedure provided bySAS were utilized to relate cover crops and N rates with selecteddependent variables. Treatment differences were considered significantif P > F was $≤$ 0.10.

RESULTS AND DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Sunn-Hemp Biomass and Nitrogen Production
Sunn-hemp biomass, which was only collected during the first2 yr of this experiment, averaged 7.6 Mg ha^–1 at firstfrost approximately 14 WAP (Table 1). Sunn-hemp provided aboveaverage ground cover at the beginning of winter to protect thesoil during a season when precipitation exceeds evapotranspiration,compared with the beginning of the summer growing season, whenevapotranspiration typically exceeds precipitation. The amountof sunn-hemp biomass produced was greater than the minimum 4.5Mg ha^–1 rate, reported by Reiter et al. (2003), for ahigh-residue cereal crop conservation tillage system in Alabamaand greater than reported dry matter produced from several winterlegumes across Kentucky, North Carolina, and Georgia (Hoyt and Hargrove, 1986).

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Table 1. Sunn-hemp dry matter production, N concentration, and N content measured at first frost from the E.V. Smith Research and Extension Center in Shorter, AL, during the 1991 and 1992 growing seasons. Sunn-hemp biomass samples were collected for the 1993 crop year, but samples were misplaced before analysis.

Aboveground N content of sunn-hemp for the first 2 yr of theexperiment was 144 kg ha^–1 at first frost (Table 1). ThisN content is comparable and in some cases higher than valuesfor crimson clover (Trifolium incarnatum L.) and hairy vetch(Vicia villosa Roth), the standards by which most species arecompared in most research of the Southeast (Reeves, 1994). Mansoer et al. (1997)reported an average sunn-hemp N content of 126kg ha^–1 for 3 site years, 9 to 12 WAP.

Corn Grain Yields
Corn grain yields were higher when planted into sunn-hemp thanfallow plots for 2 of the 3 yr of the experiment (Table 2).When averaged over all years, corn yields were 1.2 Mg ha^–1higher for corn following sunn-hemp. Each incremental rate ofN applied increased yields, averaged over both cover crops;however, a cover x N rate interaction occurred in 1991 (Table 2).Corn grain yields measured in sunn-hemp plots were higherthan fallow plots at lower N rates, but corn grain yields fromboth covers were approximately equal at the highest N rate (Fig. 1).Fallow plots were also more responsive to each incrementalincrease of N applied. The response of corn grain yields followingsunn-hemp with no additional N was above corn grain yields fromfallow plots with 56 kg N ha^–1 applied (Fig. 1). Mansoer et al. (1997)showed that sunn-hemp, mowed in the fall and overwinteredunder similar environmental conditions as our study, had 45kg N ha^–1 remaining at the time of corn planting the followingspring. The higher response to sunn-hemp with no additionalN may be attributed to the lack of mowing in our study, whichwould slow decomposition and subsequent release of N duringwinter, potentially increasing the N remaining at corn plantingand the "rotation effect" observed following legumes (Hargrove and Frye, 1987;Reeves, 1994; Torbert et al., 1996).

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Table 2. Corn grain yield and grain N contents measured for cover crop (main plots) and N rates (subplots) for 1991–1993 at the E.V. Smith Research and Extension Center in Shorter, AL.

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Fig. 1. Corn grain yields in 1991 following sunn-hemp and fallow plots measured across four N rates at the E.V. Smith Research and Extension Center in Shorter, AL.

Corn Grain Nitrogen Contents
Corn grain N contents were higher following sunn-hemp than fallowplots for all 3 yr of the experiment (Table 2). The 3-yr averagegrain N content of corn following sunn-hemp was 16.3 kg ha^–1higher than when corn followed fallow. Similar to corn grainyields, a cover x N rate interaction occurred in 1991 and 1992.Corn grain N contents in 1991, following sunn-hemp with no additionalN, were higher than grain N contents from fallow plots with0 and 56 kg N ha^–1 applied and approximately equal tograin N contents from fallow plots with 112 kg N ha^–1applied (Fig. 2A). In 1992, corn grain N contents were similarbetween main plots at the 0 and 168 kg N ha^–1 rate (Fig. 2B).The largest corn grain N content difference between coversoccurred with 112 kg N ha^–1 applied. The best fit to theresponse of corn grain N content and N applied following sunn-hempwas quadratic, indicating that the corn grain N content wasmaximized in 1992.

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Fig. 2. Corn grain N contents following sunn-hemp and fallow plots measured across four N rates at the E.V. Smith Research and Extension Center in Shorter, AL, for (A) 1991 and (B) 1992.

No obvious explanation exists for the similar grain N contentsmeasured between main plots in 1992 when no N was applied (Fig. 2B).Grain yields measured from those plots were low, but yieldsfollowing sunn-hemp were 85% higher (2.4 vs. 1.3 Mg ha^–1)than yields from the fallow plots. The largest response to sunn-hempwithout additional N occurred in 1991, probably resulting inhigher amounts of stover production compared with fallow plots.As a result, higher amounts of corn stover, with a high C/Nratio, were incorporated into the soil at the time plots wereprepared for sunn-hemp planting, before the 1992 corn growingseason. Incorporation of corn stover has been shown to promoteimmobilization of soil N (Smith and Sharpley, 1990; Aulakh et al., 1991).The high C/N ratio in stover may have immobilizedindigenous soil N, N mineralized from sunn-hemp leaves, andin combination with the remaining sunn-hemp stems, which alsohave a high C/N ratio, attributed to the low grain N contentsmeasured from sunn-hemp plots that received no additional Nin 1992.

Estimated Sunn-Hemp Nitrogen Contribution
Regression equations relating corn grain yields and corn grainN content as a function of fertilizer N rate following fallowand sunn-hemp covers predicted the N fertilizer equivalenceof sunn-hemp (Table 3). Based on corn grain yield regressionequations, sunn-hemp produced an average N fertilizer equivalenceof 58 kg ha^–1 over the 3-yr period. This amount correspondsto the 45 kg N ha^–1 reported by Mansoer et al. (1997),remaining in sunn-hemp residue at the time of corn plantingafter it was mowed in the fall and allowed to decompose overthe winter. As previously discussed, the lack of mowing in ourstudy may have slowed the decomposition process of sunn-hempresidue. In addition, the higher N content (18 kg ha^–1)of sunn-hemp residue from our study compared to that reportedby Mansoer et al. (1997) may explain the higher N fertilizerequivalence observed.

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Table 3. Regression equations for corn grain yields and corn grain N content as a function of fertilizer N rate following fallow and sunn-hemp plots for 1991–1993 at the E.V. Smith Research and Extension Center in Shorter, AL.

Hargrove (1986) suggested that grain N content provided a betterestimate of the N contribution from legumes because the responseis generally linear over typical N rate ranges, and yield integratesother factors besides N contribution. Other authors also suggestthat calculating N fertilizer equivalence with yield does notdistinguish between the effect of the N contribution from thecover crop and other effects of the cover crop (Smith et al., 1987;Frye et al., 1988). These other yield enhancing effectsare considered rotation effects and may include improvementsin soil structure and reduction in diseases or other phytotoxicsubstances (Hesterman, 1988). In Hargrove's study, it shouldbe noted that grain yields were not influenced by N rates followinglegumes, but grain N contents were. In contrast, we observedthat both yields and grain N contents were affected by N ratesfollowing sunn-hemp, and grain N contents following sunn-hempwere not always linear over the range of N rates utilized inour study.

Regression equations for grain N content predicted an N fertilizerequivalence of 33 kg ha^–1 for sunn-hemp. This number ismisleading because the first year the value was 86 kg N ha^–1,but it was <15 kg N ha^–1 for the last 2 yr. Nitrogenfertilizer equivalence predicted with regression equations foryield also decreased with each succeeding year (113, 38, and24 kg N ha^–1). Reeves et al. (1993) suggested that totalfertilizer N requirements may decrease with time due to theresidual effects of legume N, and Torbert et al. (1996) statedthat legume cover crops may improve fertilizer or native soilN utilization by corn. Since the experimental plots remainedin the same position for the duration of the experiment, residualeffects of N may have been more pronounced. However, if highresidual N contents were present in the soil, corn yields followingsunn-hemp would have a greater chance to plateau at the highN rate, indicating a maximum was achieved, especially for thelast year. The linear regression equations indicate that 168kg N ha^–1 may not have maximized yields (Table 3).

Another explanation for the discrepancy of predicted N fertilizerequivalence among years may be the composition of the sunn-hempresidue present at planting and the amount of precipitationreceived as sunn-hemp decomposes. Mansoer et al. (1997) reportedthat the majority of the N in sunn-hemp is present in the leaves,which decomposed rapidly during the first 4 wk after mowing.The remaining residue consisted of stems, with a high C/N ratio,potentially lowering the N fertilizer equivalence of sunn-hemp.In our study, sunn-hemp was not mowed, but the leaf materialprobably decomposed quickly due to the previously reported lowC/N ratio of the leaf fraction. As this decomposition occurred,mineralized N from sunn-hemp was susceptible to denitrificationand leaching, primarily from winter precipitation because nocrops were planted during the winter period to utilize the mineralN. Table 4 presents the precipitation amounts received duringthe period after sunn-hemp biomass collection in November totime of corn planting in April for the 3 yr of the study comparedwith the 30-yr mean. Precipitation received during the 4-wkperiod of November in 1990 was less than half the amount ofprecipitation received during the 30-yr mean for that same month.No measurements were taken to quantify mineral N contents, butthe potential for denitrification and leaching losses was muchlower for this period, which coincided with the highest N fertilizerequivalence measurement. Precipitation received during the 4-wkperiod of November in 1991 was approximately equal to the amountreceived during the 30-yr mean for the same month, increasingthe potential for N losses. Nitrogen fertilizer equivalencealso declined the second year. Precipitation received duringthe 4-wk period of November in 1992 was more than double theamount received during the 30-yr mean for the same month, coincidingwith the lowest N fertilizer equivalence measured. These effectsmay explain the values observed in our study among N fertilizerequivalence values.

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Table 4. Rainfall amounts for 1990–1991, 1991–1992, and 1992–1993 time periods and 30-yr means recorded at the E.V. Smith Research and Extension Center in Shorter, AL.

	CONCLUSIONS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS NOTES RESULTS AND DISCUSSION CONCLUSIONS REFERENCES

When compared with fallow, sunn-hemp produced higher corn grainyields 2 of the 3 yr with a weak trend (P = 0.2340) for higheryields the third year. Corn grain yields following sunn-hempresponded to N applications, but the response was less thanyields following fallow plots. Corn grain N contents were higherfollowing sunn-hemp than fallow for all 3 yr of the experiment.Calculated N fertilizer contribution from sunn-hemp averaged58 kg N ha^–1 based on corn yield and 33 kg N ha^–1based on grain content. These amounts appeared to be dependenton the amount of precipitation received after first frost, whichterminated the sunn-hemp. Sunn-hemp, planted in mid- to late-August,can produce adequate biomass and significant amounts of N toreplace winter annual legumes as a cover crop option for cornproduction in the humid Southeast. However, precipitation exceedsevapotranspiration during the winter months in this region,increasing potential for denitrification and leaching losses,and potentially decreasing the amount of N available from sunn-hempresidue for a succeeding corn crop. A winter cereal cover cropplanted following sunn-hemp termination by frost could possiblyutilize and sequester the N mineralized during winter from sunn-hemp,and thus, limit N losses and increase surface residue at cornplanting.

NOTES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

^¹ Mention of a trade name, proprietary product, or specific equipmentdoes not constitute a guarantee or warranty by the USDA anddoes not imply approval of a product to the exclusion of othersthat may be suitable.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

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Cope, J.T., Jr., C.E. Evans, and H.C. Williams. 1983. Soil test fertilizer recommendations for Alabama crops. Auburn Univ. Agric. Exp. Stn. 251.

Decker, A.M., A.J. Clark, J.J. Meisinger, F.R. Mulford, and M.S. McIntosh. 1994. Legume cover crop contributions to no-tillage corn production. Agron. J. 86:126–135.[Abstract/Free Full Text]

Decker, A.M., J.F. Holderbaum, R.F. Mulford, J.J. Meisinger, and L.R. Vough. 1987. Fall-seeded legume nitrogen contributions to no-till corn production. p. 21–22. In J.F. Power (ed.) The role of legumes in conservation tillage systems. Soil Conserv. Soc. of Am., Ankeny, IA.

Ebelhar, S.A., W.W. Frye, and R.L. Blevins. 1984. Nitrogen from legume cover crops for no-tillage corn. Agron. J. 76:51–55.[Abstract/Free Full Text]

Frye, W.W., R.L. Blevins, M.S. Smith, S.J. Corak, and J.J. Varco. 1988. Role of annual legume cover crops in efficient use of water and nitrogen. p. 129–154. In W.L. Hargrove (ed.) Cropping strategies for efficient use of water and nitrogen. Spec. Publ. 51. ASA, Madison, WI.

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Hargrove, W.L., and W.W. Frye. 1987. The need for legume cover crops in conservation tillage production. p. 1–5. In J.F. Power (ed.) The role of legumes in conservation tillage systems. Soil Conserv. Soc. of Am., Ankeny, IA.

Hesterman, O.B. 1988. Exploiting forage legumes for nitrogen contribution in cropping systems. p. 155–166. In W.L. Hargrove (ed.) Cropping strategies for efficient use of water and nitrogen. Spec. Publ. 51. ASA, Madison, WI.

Holderbaum, J.F., A.M. Decker, J.J. Meisinger, F.R. Mulford, and L.R. Vough. 1990. Fall-seeded legume cover crops for no-tillage corn in the humid East. Agron. J. 82:117–124.[Abstract/Free Full Text]

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Lales, J.C., and B.B. Mabbayad. 1983. The potential and establishment method of Crotalaria juncea L. as a green manure for corn (Zea mays L.). Philipp. J. Crop Sci. 8:145–147.

Magdoff, F. 1991. Understanding the Magdoff pre-sidedress nitrate test for corn. J. Prod. Agric. 4:297–305.

Mansoer, Z., D.W. Reeves, and C.W. Wood. 1997. Suitability of sunn hemp as an alternative late-summer legume cover crop. Soil Sci. Soc. Am. J. 61:246–253.[Abstract/Free Full Text]

Mehlich, A. 1953. Determinations of P, Ca, Mg, K, Na, and NH₄. North Carolina Soil Test Div. Mimeo. North Carolina Dep. of Agric., Raleigh, NC.

Mitchell, W.H., and M.R. Teel. 1977. Winter-annual cover crops for no-tillage corn production. Agron. J. 69:569–573.[Abstract/Free Full Text]

Natural Resources Conservation Service. 1999. Sunn hemp: A cover crop for Southern and tropical farming systems. Soil Qual. Instit. Tech. Note 10 [Online]. Available at http://soils.usda.gov/sqi/files/10d3.pdf (accessed 23 June 2004; verified 4 Oct. 2004). USDA-NRCS, Soil Quality Inst., Auburn, AL.

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Reeves, D.W. 1994. Cover crop and rotations. p. 125–172. In J.L. Hatfield and B.A. Stewart (ed.) Crops residue management. Lewis Publ., Boca Raton, FL.

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Journal of Natural Resources and Life Sciences Education		Soil Science Society of America Journal
Journal of Plant Registrations	Journal of Environmental Quality		The Plant Genome

				D. N. Baributsa, E. F. Foster, K. D. Thelen, A. N. Kravchenko, D. R. Mutch, and M. Ngouajio Corn and Cover Crop Response to Corn Density in an Interseeding System Agron. J., June 16, 2008; 100(4): 981 - 987. [Abstract] [Full Text] [PDF]

				H. H. Schomberg, N. L. Martini, J. C. Diaz-Perez, S. C. Phatak, K. S. Balkcom, and H. L. Bhardwaj Potential for Using Sunn Hemp as a Source of Biomass and Nitrogen for the Piedmont and Coastal Plain Regions of the Southeastern USA Agron. J., October 15, 2007; 99(6): 1448 - 1457. [Abstract] [Full Text] [PDF]

				C. M. Cherr, J. M. S. Scholberg, and R. McSorley Green Manure as Nitrogen Source for Sweet Corn in a Warm-Temperate Environment Agron. J., August 3, 2006; 98(5): 1173 - 1180. [Abstract] [Full Text] [PDF]