Biomass Yield and Nutrient Responses of Switchgrass to Phosphorus Application

Kering, Maru K.; Biermacher, Jon T.; Butler, Twain J.; Mosali, Jagadeesh; Guretzky, John A.

doi:10.1007/s12155-011-9174-y

Cited by 65 publications

(49 citation statements)

References 27 publications

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“…Schmer et al [17] measured annual average biomass yields of 5.2 to 11.1 Mg ha −1 of switchgrass when managed as a biomass energy crop on marginal cropland in the northern Great Plains, USA. Even greater yields on marginal lands in Oklahoma were shown by Kering et al [8], with switchgrass producing 16.0 Mg ha −1 during the fifth year of production. Along newly constructed highways in West Virginia with rocky soils, switchgrass achieved good cover and soil stabilization after 2 years, although yields were not measured [21].…”

Section: Introductionmentioning

confidence: 84%

“…Determining economically optimum N application rates will help switchgrass producers maximize profits with high yields while reducing fertilizer and environmental costs. Unfortunately, there is no consensus on the amount of nutrients, particularly N, to apply to a field for switchgrass growth [8,16] because the amount varies with soil type and location [7]. The amount of N required by switchgrass is a function of the desired yield, N concentration of the biomass, potential productivity of the site, soil nutrient supply, and management practices [27].…”

Section: Introductionmentioning

confidence: 99%

“…Without fertilization, one study in Georgia showed 8.6 Mg ha −1 of biomass production averaged over the first 4 years of switchgrass growth [9]. Kering et al [8] showed only an 18 % increase in Alamo production with an N fertilizer rate of 135 kg N ha −1 and a potassium (K) rate of 68 kg K 2 O ha −1 as compared to the no fertilizer control. This indicates that switchgrass grown on marginal lands may benefit from the addition of K along with N. Switchgrass can grow without fertilizer inputs, but it clearly responds positively to fertilizer [12].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Switchgrass Biofuel Production on Reclaimed Surface Mines: I. Soil Quality and Dry Matter Yield

Brown

Griggs

Keene³

et al. 2015

Bioenerg. Res.

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Growing food crops for biofuel on productive agricultural lands may become less viable as requirements to feed a growing human population increase. This has increased interest in growing cellulosic biofuel feedstocks on marginal lands. Switchgrass (Panicum virgatum L.), a warm-season perennial, is a viable bioenergy crop candidate because it produces high yields on marginal lands under low fertility conditions. In other studies, switchgrass dry matter (DM) yields on marginal croplands varied from 5.0 to 10.0 Mg ha −1 annually. West Virginia contains immense areas of reclaimed surface mined lands that could support a switchgrass-based biofuel industry, but yield data on these lands are lacking. Field experiments were established in 2008 to determine yields of three switchgrass cultivars on two West Virginia mine sites. One site reclaimed with topsoil and municipal sludge produced biomass yields of 19.0 Mg DM ha −1 for Cave-inRock switchgrass after the sixth year, almost double the varieties Shawnee and Carthage, at 10.0 and 5.7 Mg ha −1 , respectively. Switchgrass yields on another site with no topsoil were 1.0 Mg ha −1 after the sixth year, with little variation among cultivars. A second experiment was conducted at two other mine sites with a layer of topsoil over gray overburden. Cavein-Rock was seeded with fertilizer applications of 0, 34, and 68 kg N-P 2 O 5 -K 2 O ha −1 . After the third year, the no fertilizer treatment averaged biomass yields of 0.3 Mg ha −1 , while responses to the other two rates averaged 1.1 and 2.0 Mg ha −1 , respectively. Fertilization significantly increased yields on reclaimed mine soils. Where mine soil fertility was good, yields were similar to those reported on agricultural soils in the Northeastern USA.

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Section: Introductionmentioning

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Switchgrass Biofuel Production on Reclaimed Surface Mines: I. Soil Quality and Dry Matter Yield

Brown

Griggs

Keene³

et al. 2015

Bioenerg. Res.

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“…This suggests that systems with N applications did not realize statistically greater yields .0001 † The letters represent harvest system, the first number is kg of N ha −1 and second number is kg of K 2 O ha −1 ‡ P values are based on Fisher's protected F tests § Means reported for yield, total cost, gross revenue, and net return for the feedstock production systems within a row marked with the same letter are not significantly different based on an LSD test (P <0.05) ¶ Costs of fertilizer was estimated assuming a base-case N price of $1.43 kg −1 and a K 2 O price of $1.17 kg −1 # Revenue was calculated using a base-case feedstock price of $83 Mg −1 than systems without N applications, which is in contrast to what was found by previous studies [7,14]. However, we point out that these studies were not conducted in K-deficient soils.…”

Section: Resultsmentioning

confidence: 99%

“…Extensive soil testing has revealed that a substantial percentage of acres in the southern Great Plains are deficient in potassium (K), primarily those in the eastern areas that are comprised of sandy soils and receive greater than 889 mm of rainfall each year [2]. At present, most switchgrass fertilizer management studies have mainly focused on the benefits and costs associated with nitrogen (N) fertilizer as the primary limiting nutrient [3][4][5] and a few studies have focused on phosphorus (P) fertilizer [1,6,7]. However, little information is available regarding the costs and benefits associated with N and K fertilization on switchgrass produced in K-deficient soils.…”

Section: Introductionmentioning

confidence: 99%

Economic Evaluation of Switchgrass Feedstock Production Systems Tested in Potassium-Deficient Soils

et al. 2013

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Limited information is available about the economic benefits and costs associated with managing switchgrass (Panicum virgatum L.) produced for bioenergy feedstock in the K-deficient soils common in the southern Great Plains. The objectives of this study were to determine the most economical production system for harvesting and managing N and K fertilizations on switchgrass stands and to determine how sensitive the results are to various feedstock and fertilizer market price scenarios. A 4-year agronomic field experiment was conducted on a K-deficient site in South Central Oklahoma; the treatments included two harvest systems (summer and winter (SW) and winter only (W)), two N rates (0 and 135 kg ha −1 ), and two K rates (0 and 67 kg ha −1 ). Enterprise budgeting techniques and mixed ANOVA models were used to determine and compare the effects of eight harvest/N/K systems on yield, total cost, revenue, and net return. The harvest/N/K systems evaluated included SW/0/0, SW/0/67, SW/135/0, SW/135/67, W/0/0, W/0/67, W/135/0, and W/ 135/67. Results revealed the SW/135/67 system produced significantly (P >0.0001) greater average yield compared to the other systems; however, the SW/0/0 system was the most (P >0.0001) economical, realizing an average net return of $415 ha −1 . Compared to the base-case net return of the SW/0/ 0 system, the value of the additional yield generated with the SW/135/67 system was less than the costs associated with the extra nutrients and additional harvest activity. For feedstock prices greater than $110 Mg −1 , the most economical system shifted from the SW/0/0 to favor the SW/135/67 system.

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