43 results on '"Rosen, Carl J."'
Search Results
2. Quantifying critical N dilution curves across G × E × M effects for potato using a partially-pooled Bayesian hierarchical method
- Author
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Bohman, Brian J., Culshaw-Maurer, Michael J., Ben Abdallah, Feriel, Giletto, Claudia, Bélanger, Gilles, Fernández, Fabián G., Miao, Yuxin, Mulla, David J., and Rosen, Carl J.
- Published
- 2023
- Full Text
- View/download PDF
3. Impacts of cover crops and nitrogen fertilization on agricultural soil fungal and bacterial communities
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Castle, Sarah C., Samac, Deborah A., Gutknecht, Jessica L., Sadowsky, Michael J., Rosen, Carl J., Schlatter, Daniel, and Kinkel, Linda L.
- Published
- 2021
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4. Potato Nitrogen Response and Soil Microbial Activity as Affected by Fumigation
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Crants, James E., Kinkel, Linda L., Dundore-Arias, José Pablo, Robinson, Andrew P., Gudmestad, Neil C., and Rosen, Carl J.
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- 2021
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5. Precipitation Drives Nitrogen Load Variability in Three Iowa Rivers
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Wolf, Kari A., Gupta, Satish C., and Rosen, Carl J.
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- 2020
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6. Impacts of Sampling Design on Estimates of Microbial Community Diversity and Composition in Agricultural Soils
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Castle, Sarah C., Samac, Deborah A., Sadowsky, Michael J., Rosen, Carl J., Gutknecht, Jessica L. M., and Kinkel, Linda L.
- Published
- 2019
7. Efficacy of bromide tracers for evaluating the hydraulics of denitrification beds treating agricultural drainage water
- Author
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Ghane, Ehsan, Feyereisen, Gary W., and Rosen, Carl J.
- Published
- 2019
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- View/download PDF
8. Non-linear hydraulic properties of woodchips necessary to design denitrification beds
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Ghane, Ehsan, Feyereisen, Gary W., and Rosen, Carl J.
- Published
- 2016
- Full Text
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9. Acrylamide Formation in Processed Potatoes as Affected by Cultivar, Nitrogen Fertilization and Storage Time
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Sun, Na, Rosen, Carl J., and Thompson, Asunta L.
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- 2018
- Full Text
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10. Intended and unintended impacts of nitrogen‐fixing microorganisms and microbial inhibitors on nitrogen losses in contrasting maize cropping systems.
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Souza, Emerson F. C., Rosen, Carl J., Venterea, Rodney T., and Tahir, Muhammad
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- 2023
- Full Text
- View/download PDF
11. Hyperspectral aerial imagery for detecting nitrogen stress in two potato cultivars
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Nigon, Tyler J., Mulla, David J., Rosen, Carl J., Cohen, Yafit, Alchanatis, Victor, Knight, Joseph, and Rud, Ronit
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- 2015
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12. Nitrogen Response of French Fry and Chip Cultivars Selected for Low Tuber Reducing Sugars
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Sun, Na, Rosen, Carl J., and Thompson, Asunta L.
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- 2017
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13. Soil phosphorus balance in Minnesota soils and its effects on soil test phosphorus and soil phosphorus fractions.
- Author
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Sims, Albert L., Fabrizzi, Karina P., Kaiser, Daniel E., Rosen, Carl J., Vetsch, Jeffrey A., Strock, Jeffrey S., Lamb, John A., and Farmaha, Bhupinder S.
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PHOSPHORUS in soils ,SOIL testing - Abstract
Phosphorus (P) fertilizer recommendations based on the build and maintain (B&M) or the sufficiency philosophies were compared at six sites across Minnesota. Various levels of soil test P (STP) levels were established over four growing seasons. Applied P and P removed in harvested grain were monitored and used to develop a soil net P balance (Net P). Linear regression of net P with changes in STP was highly significant. Initial STP levels could be maintained at four of the six sites with a negative Net P. At those same sites, a zero Net P would tend to slowly increase STP over time. A sequential soil P fractionation analysis was conducted on soils from the six sites at the initiation and at the end of the 4‐year period. Nine total soil P fractions were extracted that represented both inorganic P (Pi) and organic P (Po) in the labile and non or less labile soil P pools. A positive linear relationship between Net P and changes in Pi fractions was significant. As Net P increased, so did the changes in Pi in the Resin, BiCarb, and NaOH fractions. These three fractions accounted for 66% to >100% of the changes in Net P with Resin and NaOH accounting for the majority of Net P. Changes in Net P that were accounted for in the less labile P pools, Sonic and HCl fractions, variable, and difficult to determine. There was little effect of Net P on Po fractions. Core ideas: Soil net P balance was positively correlated with changes in STP over four growing seasons.Medium STP interpretation class was maintained in most of these soils with a slight negative soil net P balance.In those same soils, a zero‐soil net P balance would tend to raise STP over time.Soil net P balance is positively related to changes in soil P, mostly in the labile and moderately labile fractions. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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14. Maize Stover and Cob Cell Wall Composition and Ethanol Potential as Affected by Nitrogen Fertilization
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Sindelar, Aaron J., Sheaffer, Craig C., Lamb, John A., Jung, Hans-Joachim G., and Rosen, Carl J.
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- 2015
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15. Potato response to adaptive nitrogen and reduced irrigation management in the Minnesota Central Sands
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Bohman, Brian, Rosen, Carl J, Mulla, David J., and McNearney, Matt
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- 2018
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16. Nitrogen uptake and utilization in advanced fresh‐market red potato breeding lines.
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Jones, Colin R., Michaels, Thomas E., Schmitz Carley, Cari, Rosen, Carl J., and Shannon, Laura M.
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HUMAN skin color ,TUBERS ,SANDY soils ,ROOT growth ,NITROGEN ,POTATOES - Abstract
Potato (Solanum tuberosum L.) production on sandy soils requires added N. Only 40–60% of the applied N is acquired by the crop. Increased N use efficiency (NUE) and its components, N utilization efficiency (NUtE) and N uptake efficiency (NUpE), could reduce fertilizer rates and environmental losses. We compared N efficiency in fresh‐market red potato varieties, in terms of yield and quality traits, and examined potential mechanisms for that efficiency including uptake, utilization, and increased root growth. We grew selections from a red potato breeding population and commercial varieties under two N rates: 101 and 202 kg N ha−1. We compared NUE, NUpE, and NUtE in low and high N. We compared root phenotypes at tuber initiation and yield and skin quality metrics at harvest. Values for NUtE correlated with NUE and yield in low N and NUpE correlated with NUE and yield in high N. Low‐N conditions produced smaller tubers, while high N resulted primarily in medium tubers. Nitrogen did not affect skinning and redness but low N did result in slightly lighter skin color. Total root mass 45 d after planting (DAP) correlated with final yield and NUE but did not correlate with measures of N uptake across treatments. Larger roots correlated with NUpE only in the high‐N treatment. Selection under low N may reveal NUE and expose more stable representations of the genetic components of skin quality phenotypes. While skinning and skin color were more variable among varieties in low N, within variety they exhibited year‐to‐year consistency. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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17. Nitrogen and Irrigation Management Strategies for Potato Production to Reduce Nitrate Leaching
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Bohman, Brian, Rosen, Carl J, Mulla, David J., and McNearney, Matt
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- 2017
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18. Soil‐nitrogen, potentially mineralizable‐nitrogen, and field condition information marginally improves corn nitrogen management.
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Clark, Jason D., Fernández, Fabián G., Veum, Kristen S., Camberato, James J., Carter, Paul R., Ferguson, Richard B., Franzen, David W., Kaiser, Daniel E., Kitchen, Newell R., Laboski, Carrie A. M., Nafziger, Emerson D., Rosen, Carl J., Sawyer, John E., and Shanahan, John F.
- Abstract
Anaerobic potentially mineralizable nitrogen (PMN) combined with preplant nitrate test (PPNT) or pre‐sidedress nitrate test (PSNT) may improve corn (Zea mays L.) N management. Forty‐nine corn N response studies were conducted across the U.S. Midwest to evaluate the capacity of PPNT and PSNT to predict grain yield, N uptake, and economic optimal N rate (EONR) when adjusted by soil sampling depth, soil texture, temperature, PMN, and initial NH4–N from PMN analysis. Pre‐plant soil samples were obtained for PPNT (0‐ to 30‐, 30‐ to 60‐, 60‐ to 90‐cm depths) and PMN (0‐ to 30‐cm depth) before corn planting and N fertilization. In‐season soil samples were obtained at the V5 corn development stage for PSNT (0‐ to 30‐, 30‐ to 60‐cm depths) at 0 kg N ha−1 at‐planting rate and for PMN when 0 and 180 kg N ha−1 was applied at planting. Grain yield, N uptake, and EONR were best predicted when separating soils by texture or sites by annual growing degree‐days and including PMN and initial NH4–N with either NO3–N test. Using PSNT (mean R2 =.30)‐instead of PPNT (mean R2 =.19)‐based models normally increased predictability of corn agronomic variables by a mean of 11%. Including PMN and initial NH4–N with PPNT or PSNT only marginally improved predictability of grain yield, N uptake, and EONR (R2 increase ≤.33; mean R2 =.35). Therefore, including PMN with PPNT or PSNT is not suggested as a tool to improve N fertilizer management in the U.S. Midwest. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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19. Adjusting corn nitrogen management by including a mineralizable‐nitrogen test with the preplant and presidedress nitrate tests.
- Author
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Clark, Jason D., Fernández, Fabián G., Veum, Kristen S., Camberato, James J., Carter, Paul R., Ferguson, Richard B., Franzen, David W., Kaiser, Daniel E., Kitchen, Newell R., Laboski, Carrie A. M., Nafziger, Emerson D., Rosen, Carl J., Sawyer, John E., and Shanahan, John F.
- Abstract
The anaerobic potentially mineralizable N (PMN) test combined with the preplant (PPNT) and presidedress (PSNT) nitrate tests may improve corn (Zea mays L.) N fertilization predictions. Forty‐nine corn N response experiments (mostly corn following soybean [Glycine max (L.) Merr.]) were conducted in the U.S. Midwest from 2014–2016 to evaluate the ability of the PPNT and PSNT to predict corn relative yield (RY) and N fertilizer over‐ and under‐application rates when adjusted by PMN. Before planting and N fertilization, PPNT (0–30, 30–60, and 60–90 cm) and PMN (0–30 cm) samples were obtained. In‐season soil samples were obtained at the V5 development stage for PSNT (0–30, 30–60 cm) in all N rate treatments and PMN (0–30 cm) in only the 0 and 180 kg N ha−1 preplant N treatments. Increasing NO3–N sampling depths beyond 30 cm with or without PMN improved RY predictability marginally (R2 increase up to 0.20) and reduced over‐ and under‐application frequencies up to 14%. Including PMN (preplant only) with PPNT or PSNT improved RY predictability minimally (R2 increase up to 0.10) only for coarse‐ and medium‐textured soils, but N fertilizer over‐ and under‐application frequencies were not substantially reduced (≤12%). These marginal improvements in RY predictability and N fertilizer over‐ and under‐application frequencies, regardless of the variables used (e.g., fertilization, sampling depth, soil texture, and growing degree‐day categories), demonstrate that including PMN with soil NO3–N alone does not improve corn N fertilization need predictions enough to recommend their use. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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- View/download PDF
20. Impact of variable rate nitrogen and reduced irrigation management on nitrate leaching for potato.
- Author
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Bohman, Brian J., Rosen, Carl J., and Mulla, David J.
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IRRIGATION management ,CONTAMINATION of drinking water ,NITRATES ,SOIL leaching ,CROPPING systems - Abstract
Nitrogen (N) loss from cropping systems has important environmental implications, including contamination of drinking water with nitrate. A 2‐yr study evaluated the effects of six N rate, source, and timing treatments, including a variable rate (VR) N treatment based on the N sufficiency index approach using remote sensing, and two irrigation rate treatments, including conventional and reduced rate, on nitrate leaching, residual soil nitrate, and plant N uptake for potato (Solanum tuberosum L. cv. Russet Burbank) production in 2016 and 2017 on a Hubbard loamy sand. Nitrate leaching losses measured with suction‐cup lysimeters varied between 2016 and 2017 with flow‐weighted mean nitrate N concentrations of 5.6 and 12.8 mg N L−1, respectively, and increased from 7.1 to 10.4 mg N L−1 as N rate increased from 45 to 270 kg N ha−1. Despite reductions in N rate of 22 and 44 kg N ha−1 in 2016 and 2017, respectively, for the VR N treatment, there was no significant difference in nitrate leaching compared with the existing N best management practices (BMPs). Reducing irrigation rate by 15% decreased nitrate leaching load by 17% through a reduction in percolation. Residual soil nitrate N in the top 60 cm across all treatments (7.9 mg N kg−1) suggests a risk for nitrate leaching during the nongrowing season, and plant N uptake did not explain yearly variation in nitrate leaching and residual soil nitrate. Although existing N BMPs are effective at controlling N losses, development of alternative practices is needed to further reduce the risk of groundwater contamination. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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- View/download PDF
21. Soil sample timing, nitrogen fertilization, and incubation length influence anaerobic potentially mineralizable nitrogen.
- Author
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Clark, Jason D., Veum, Kristen S., Fernández, Fabián G., Kitchen, Newell R., Camberato, James J., Carter, Paul R., Ferguson, Richard B., Franzen, David W., Kaiser, Daniel E., Laboski, Carrie A. M., Nafziger, Emerson D., Rosen, Carl J., Sawyer, John E., and Shanahan, John F.
- Subjects
SOIL sampling ,CLAY soils ,CORN development ,SOIL weathering ,WEATHER ,NITROGEN fertilizers - Abstract
Understanding the variables that affect the anaerobic potentially mineralizable N (PMN
an ) test should lead to a standard procedure of sample collection and incubation length, improving PMNan as a tool in corn (Zea mays L.) N management. We evaluated the effect of soil sample timing (preplant and V5 corn development stage [V5]), N fertilization (0 and 180 kg ha−1 ) and incubation length (7, 14, and 28 d) on PMNan (0–30 cm) across a range of soil properties and weather conditions. Soil sample timing, N fertilization, and incubation length affected PMNan differently based on soil and weather conditions. Preplant vs. V5 PMNan tended to be greater at sites that received < 183 mm of precipitation or < 359 growing degree-days (GDD) between preplant and V5, or had soil C/N ratios > 9.7:1; otherwise, V5 PMNan tended to be greater than preplant PMNan . The PMNan tended to be greater in unfertilized vs. fertilized soil in sites with clay content > 9.5%, total C < 24.2 g kg−1 , soil organic matter (SOM) < 3.9 g kg−1 , or C to N ratios < 11.0:1; otherwise, PMNan tended to be greater in fertilized vs. unfertilized soil. Longer incubation lengths increased PMNan at all sites regardless of sampling methods. Since PMNan is sensitive to many factors (sample timing, N fertilization, incubation length, soil properties, and weather conditions), it is important to follow a consistent protocol to compare PMNan among sites and potentially use PMNan to improve corn N management. [ABSTRACT FROM AUTHOR]- Published
- 2020
- Full Text
- View/download PDF
22. Predicting Economic Optimal Nitrogen Rate with the Anaerobic Potentially Mineralizable Nitrogen Test.
- Author
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Clark, Jason D., Fernández, Fabián G., Veum, Kristen S., Camberato, James J., Carter, Paul R., Ferguson, Richard B., Franzen, David W., Kaiser, Daniel E., Kitchen, Newell R., Laboski, Carrie A. M., Nafziger, Emerson D., Rosen, Carl J., Sawyer, John E., and Shanahan, John F.
- Abstract
Estimates of mineralizable N with the anaerobic potentially mineralizable N (PMN
an ) test could improve predictions of corn (Zea mays L.) economic optimal N rate (EONR). A study across eight US midwestern states was conducted to quantify the predictability of EONR for single and split N applications by PMNan. Treatment factors included different soil sample timings (pre-plant and V5 development stage), planting N rates (0 and 180 kg N ha-1 ), and incubation lengths (7, 14, and 28 d) with and without initial soil NH4 --N included with PMNan . Soil was sampled (0-30 cm depth) before planting and N application and at V5 where 0 or 180 kg N ha-1 were applied at planting. Evaluating across all soils, PMNan was a weak predictor of EONR (R² ≤ 0.08; RMSE, ≥67 kg N ha-1 ), but the predictability improved (15%) when soils were grouped by texture. Using PMNan and initial soil NH4 --N as separate explanatory variables improved EONR predictability (11-20%) in fine-textured soils only. Delaying PMNan sampling from pre-plant to V5 regardless of N fertilization improved EONR predictability by 25% in only coarse-textured soils. Increasing PMNan incubations beyond 7 d modestly improved EONR predictability (R² increased ≤0.18, and RMSE was reduced ≤7 kg N ha-1 ). Alone, PMNan predicts EONR poorly, and the improvements from partitioning soils by texture and including initial soil NH4 --N were relatively low (R² ≤ 0.33; RMSE ≥ 68 kg N ha-1 ) compared with other tools for N fertilizer recommendations. [ABSTRACT FROM AUTHOR]- Published
- 2019
- Full Text
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23. Contrasting effects of inhibitors and biostimulants on agronomic performance and reactive nitrogen losses during irrigated potato production.
- Author
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Souza, Emerson F.C., Rosen, Carl J., and Venterea, Rodney T.
- Subjects
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POTATOES , *NITRIFICATION inhibitors , *CONTRAST effect , *GROWING season , *PLANT growth , *POTATO growing - Abstract
• The nitrification inhibitors DCD and DMPP were effective in mitigating N 2 O emissions from urea applied to potato cultivated on sandy soil. • The biostimulant containing N-fixing microorganisms increased nitrate leaching one growing season and N 2 O emissions over both seasons. • Nitrification inhibitors and biostimulants had modest agronomic benefits due to adequate available N for potato production. • Further studies should assess biostimulants performance and investigate their effects on biological processes in other agro-ecosystems. Urea is the dominant form of nitrogen (N) fertilizer used globally. Various additives have been designed for co-application with urea to improve performance of N-intensive crops including potato (Solanum tuberosum L.). Few if any studies have compared 'inhibitor' additives with 'biostimulants' designed to enhance plant growth or microbial activity. Over two potato growing seasons (2015–2016) in an irrigated loamy sand in Minnesota, we quantified agronomic performance and N losses as both nitrate (NO 3 −) and nitrous oxide (N 2 O) in treatments receiving urea, with and without additives including: nitrification inhibitors dicyandiamide (DCD) or 3,4-dimethylpyrazole phosphate (DMPP), alone or combined with the urease inhibitor N-(n-butyl) thiophosphoric triamide (NBPT), or a biostimulant containing N-fixing microbes (NFM) by itself or combined with an amino acid blend (AAB). The biostimulants produced modest (˜10%) improvements in tuber yield, under limited conditions, compared to urea alone. However, NFM increased N 2 O emissions by 32–56%, in contrast to the inhibitors, which decreased N 2 O emissions by 42–75%. Compared to urea alone, the inhibitors tended to increase soil ammonium and decrease soil NO 3 − concentrations; however, no differences in soil inorganic N in the upper 0.3 m of the profile were observed with the biostimulants. During the growing season with greater rates of soil water flux (2015), none of the inhibitors decreased NO 3 − leaching, while NFM increased NO 3 − leaching by 23%. When AAB was combined with NFM, reactive N losses did not differ from the urea-only treatment. Biostimulants can have unintended impacts on reactive N losses and should be used with caution pending additional study to better understand their effects on biological processes, and to quantify their performance in other agro-ecosystems. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
24. Evaluation of Variable Rate Nitrogen and Reduced Irrigation Management for Potato Production.
- Author
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Bohman, Brian J., Rosen, Carl J., and Mulla, David J.
- Abstract
Availability of soil moisture and N are primary limiting factors for potato growth on sandy soils in humid climates. This study was conducted to determine whether tuber yield or net economic return were affected by variable rate (VR) N or reduced irrigation management, and to evaluate methods to detect crop N status including remote sensing, chlorophyll meter, and petiole sampling. The effects of six N rate, source, and timing treatments and two irrigation rate treatments on tuber yield, quality, and net profitability for potato [Solanum tuberosum (L.) 'Russet Burbank'] were investigated in 2016 and 2017 at Becker, MN, on a Hubbard loamy sand. A VR N treatment based on the N sufficiency index (NSI) approach using remote sensing was also tested. Irrigation treatments included a conventional rate (100%) and a reduced rate (85%). The VR treatment reduced N applied relative to the recommended rate by 22 and 44 kg N ha
-1 in 2016 and 2017, respectively. Irrigation rate was reduced by 29 and 33 mm in 2016 and 2017, respectively. Neither VR N nor reduced irrigation produced significant differences in tuber yield or net return compared to full rate treatments. Using NSI, remote sensing was able to predict crop N status with comparable accuracy to petiole sampling while chlorophyll meter measurements were less sensitive to detecting crop N stress. Managing N using remote sensing and reducing irrigation rate are strategies that could be used on sandy soils in humid climates without having agronomic or economic impacts on potato production. [ABSTRACT FROM AUTHOR]- Published
- 2019
- Full Text
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25. Does Irrigated Corn Require Multiple Applications of Sulfur?
- Author
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Kurbondski, Andria J., Kaiser, Daniel E., Rosen, Carl J., and Sutradhar, Apurba K.
- Subjects
CORN ,FERTILIZER application ,SOIL science ,SULFUR ,CORN yields ,IRRIGATED soils ,HUMUS ,NITROGEN fertilizers - Abstract
Sulfur is applied to irrigated corn (Zea mays L.) grown on sandy soils. The objective of this study was to evaluate the sprinkler-irrigated corn response to S. Treatments were a factorial combination of 0, 14, 28, and 42 kg S ha-1 as (NH4)2SO4 applied on the soil surface at four locations at planting and in season (V5). Tissue samples were collected at V8 and R2 and evaluated along with corn grain yield and soil pore water SO4 2--S concentration measured at 60 cm with suction tube lysimeters. Application of S increased V8 plant mass, V8 whole plant S concentration and S uptake, and R2 leaf S concentration but did not increase corn grain yield. Decreased V8 plant mass was a result of S deficiency and was only corrected when some S was applied at planting. A total of 28 kg S ha-1 was sufficient to ensure adequate plant growth and S uptake whether S was applied at planting, in-season, or as a combination of the two timings. Concentrations of S were elevated in soil pore water from at planting and in-season S application indicating a portion of the S applied were still available for most'and at the end of'the growing season. Sulfur fertilizer is crucial early in the growing season for irrigated corn to ensure optimal corn growth. Rate of application is more important than time of S application in irrigated corn production. Incidental applications of S may reduce the need of S fertilizer for irrigated corn.
- Published
- 2019
- Full Text
- View/download PDF
26. United States Midwest Soil and Weather Conditions Influence Anaerobic Potentially Mineralizable Nitrogen.
- Author
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Clark, Jason D., Veum, Kristen S., Fernández, Fabián G., Camberato, James J., Carter, Paul R., Ferguson, Richard B., Franzen, David W., Kaiser, Daniel E., Kitchen, Newell R., Laboski, Carrie A. M., Nafziger, Emerson D., Rosen, Carl J., Sawyer, John E., and Shanahan, John F.
- Subjects
SOIL weathering ,WEATHER ,NITROGEN fertilizers ,SOIL science ,GRASSLAND soils ,FOREST soils ,FERTILIZER application - Abstract
Nitrogen provided to crops through mineralization is an important factor in N management guidelines. Understanding of the interactive effects of soil and weather conditions on N mineralization needs to be improved. Relationships between anaerobic potentially mineralizable N (PMNan) and soil and weather conditions were evaluated under the contrasting climates of eight US Midwestern states. Soil was sampled (0.30 cm) for PMNan analysis before pre-plant N application (PP0N) and at the V5 development stage from the pre-plant 0 (V50N) and 180 kg N ha
-1 (V5180N) rates and incubated for 7, 14, and 28 d. Even distribution of precipitation and warmer temperatures before soil sampling and greater soil organic matter (SOM) increased PMNan. Soil properties, including total C, SOM, and total N, had the strongest relationships with PMNan (R2 < 0.40), followed by temperature (R2 < 0.20) and precipitation (R2 < 0.18) variables. The strength of the relationships between soil properties and PMNan from PP0N, V50N, and V5180N varied by .10%. Including soil and weather in the model greatly increased PMNan predictability (R2 < 0.69), demonstrating the interactive effect of soil and weather on N mineralization at different times during the growing season regardless of N fertilization. Delayed soil sampling (V50N) and sampling after fertilization (V5180N) reduced PMNan predictability. However, longer PMNan incubations improved PMNan predictability from both V5 soil samplings closer to the PMNan predictability from PP0N, indicating the potential of PMNan from longer incubations to provide improved estimates of N mineralization when N fertilizer is applied.- Published
- 2019
- Full Text
- View/download PDF
27. Denitrifying Bacteria Active in Woodchip Bioreactors at Low-Temperature Conditions.
- Author
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Jang, Jeonghwan, Anderson, Emily L., Venterea, Rodney T., Sadowsky, Michael J., Rosen, Carl J., Feyereisen, Gary W., and Ishii, Satoshi
- Subjects
DENITRIFYING bacteria ,BIOREACTORS ,DENITRIFICATION ,SUBSURFACE drainage ,NITRITE reductase ,ELECTRON donors ,WATER temperature ,ELECTRON sources - Abstract
Woodchip bioreactor technology removes nitrate from agricultural subsurface drainage by using denitrifying microorganisms. Although woodchip bioreactors have demonstrated success in many field locations, low water temperature can significantly limit bioreactor efficiency and performance. To improve bioreactor performance, it is important to identify the microbes responsible for nitrate removal at low temperature conditions. Therefore, in this study, we identified and characterized denitrifiers active at low-temperature conditions by using culture-independent and -dependent approaches. By comparative 16S rRNA (gene) analysis and culture isolation technique, Pseudomonas spp., Polaromonas spp., and Cellulomonas spp. were identified as being important bacteria responsible for denitrification in woodchip bioreactor microcosms at relatively low temperature conditions (15°C). Genome analysis of Cellulomonas sp. strain WB94 confirmed the presence of nitrite reductase gene nirK. Transcription levels of this nirK were significantly higher in the denitrifying microcosms than in the non-denitrifying microcosms. Strain WB94 was also capable of degrading cellulose and other complex polysaccharides. Taken together, our results suggest that Cellulomonas sp. denitrifiers could degrade woodchips to provide carbon source and electron donors to themselves and other denitrifiers in woodchip bioreactors at low-temperature conditions. By inoculating these denitrifiers (i.e., bioaugmentation), it might be possible to increase the nitrate removal rate of woodchip bioreactors at low-temperature conditions. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
28. Nitrogen Fertility and Cultivar Effects on Potato Agronomic Properties and Acrylamide-forming Potential.
- Author
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Na Sun, Yi Wang, Gupta, Sanjay K., and Rosen, Carl J.
- Abstract
Acrylamide is a potentially harmful compound when consumed in the human diet and is formed during potato (Solanum tuberosum L.) processing from the precursors reducing sugars and asparagine. The objective of this study was to determine the effects of N rate (135-404 kg ha-1) on tuber yield and quality and tuber reducing sugars and asparagine concentrations in newly released cultivars Easton and Dakota Russet, relative to the standard cultivar Russet Burbank. Tuber samples were collected at intervals from initial set through harvest during two growing seasons. Tuber yield of all cultivars increased quadratically with increasing N rate. Highest yield was produced by Easton, followed by Russet Burbank and Dakota Russet. Russet Burbank had more tubers per plant than the new cultivars. Specific gravity decreased with increasing N rate and was lowest in Russet Burbank both years. The new cultivars had a lower hollow heart incidence than Russet Burbank when environmental conditions were favorable for hollow heart development. Tuber-reducing sugars changed during the growing season but were related more to cultivar and growing conditions than N rate. New cultivars had lower reducing sugars than Russet Burbank. In contrast to reducing sugars, asparagine increased with increasing N rate and was less affected by environmental conditions during the growing season. Easton had slightly lower asparagine concentrations than Russet Burbank and Dakota Russet. This study indicates that cultivar and growing conditions have a dominant effect on tuber-reducing sugars, while N rate has a more consistent effect on tuber asparagine. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
29. Nitrogen Source and Rate Effects on Irrigated Potato in Tropical Sandy Soils.
- Author
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Souza, Emerson F. C., Soratto, Rogério P., Fernandes, Adalton M., and Rosen, Carl J.
- Abstract
A suitable N source and an optimal application rate can improve the N-use efficiency of potato (Solanum tuberosum L.) while minimizing N losses, especially when potato is grown in sandy soils. Three experiments were conducted at irrigated sandy soil sites in São Paulo State, Brazil, to evaluate the effects of ammonium sulfate (AMS), ammonium sulfate nitrate with the nitrification inhibitor 3,4-dimethylpyrazole phosphate (ASN+DMPP), and urea applied at three N rates (80, 120, and 160 kg ha
-1 ), as well as a zero-N control on potato (cv. Agata). Leaf N and S concentrations, tuber yield, and agronomic efficiency (AE) were measured. The 80 kg N ha-1 rate was applied in the furrow at planting, and the other rates were split-applied, with 40 kg N ha-1 in the furrow at planting and the remainder applied at hilling. Regardless of the N source, the N fertilizer rates increased the potato leaf N concentration and tuber bulking of the potato crop, which in turn increased the tuber yield up to rates between 136 kg N ha-1 and at least 160 kg N ha-1 . Among the N sources, ASN+DMPP fertilizer resulted in a higher potato tuber set and yield than urea and led to the highest AE compared to AMS and urea. Overall, these results suggest the potential for ASN+DMPP to improve the synchronization between soil N availability and potato N demand and provide a more appropriate balance of N forms in the soil when potato is cultivated in sandy soils in a tropical climate. [ABSTRACT FROM AUTHOR]- Published
- 2019
- Full Text
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30. Data of bromide sorption experiments with woodchips and tracer testing of denitrification beds
- Author
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Ghane, Ehsan, Feyereisen, Gary W., and Rosen, Carl J.
- Published
- 2019
- Full Text
- View/download PDF
31. Reliability of Measurement and Genotype x Environment Interaction for Potato Specific Gravity.
- Author
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Yi Wang, Snodgrass, Lance B., Bethke, Paul C., Bussan, Alvin J., Holm, David G., Novy, Richard G., Pavek, Mark J., Porter, Gregory A., Rosen, Carl J., Sathuvalli, Vidyasagar, Thompson, Asunta L., Thornton, Michael T., and Endelman, Jeffrey B.
- Subjects
GENOTYPE-environment interaction ,POTATO quality ,GERMPLASM - Abstract
Specific gravity (SpGr) is often used to measure the processing quality of potato (Solanum tuberosum L.) tubers for French fries or potato chips because of its strong correlation with dry matter content and ease of measurement. For French fry processing genotypes, the desirable range for mean SpGr is typically 1.080 to 1.095, and a small variance around the mean is essential for product uniformity. Two multi-year, multi-location trials were conducted to investigate the genetics of SpGr in elite russet germplasm. Consistent with earlier studies, the mean SpGr was measured with high repeatability within each environment: the median plot-basis value was 0.83 for a national trial with six locations and 3 yr. In contrast, the median repeatability of the SD between tubers was only 0.21. Thus, multi-environment trials are needed to identify genotypes with a narrow SpGr distribution. Finlay--Wilkinson stability analysis of the mean SpGr established one genotype as an outlier: when best linear unbiased predictions were regressed on the environment means, this genotype had a regression coefficient of 2.1, compared with 0.4 to 1.4 for the others. The genetic correlation between environments showed a consistent regional pattern in mean SpGr over the years. There was a higher mean correlation between environments within the Pacific Northwest (0.97), Upper Midwest (0.91), and Northeast (0.85) than between environments from the different regions (0.35-0.78). Although breeding for national adaptation is an attractive idea, our results suggest that genetic gain may be easier to achieve at the regional level. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
32. Comparison of Contaminant Transport in Agricultural Drainage Water and Urban Stormwater Runoff.
- Author
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Ghane, Ehsan, Ranaivoson, Andry Z., Feyereisen, Gary W., Rosen, Carl J., and Moncrief, John F.
- Subjects
URBAN runoff ,WATER pollution ,NITROGEN in water ,PHOSPHORUS in water ,COMPARATIVE studies - Abstract
Transport of nitrogen and phosphorus from agricultural and urban landscapes to surface water bodies can cause adverse environmental impacts. The main objective of this long-term study was to quantify and compare contaminant transport in agricultural drainage water and urban stormwater runoff. We measured flow rate and contaminant concentration in stormwater runoff from Willmar, Minnesota, USA, and in drainage water from subsurface-drained fields with surface inlets, namely, Unfertilized and Fertilized Fields. Commercial fertilizer and turkey litter manure were applied to the Fertilized Field based on agronomic requirements. Results showed that the City Stormwater transported significantly higher loads per unit area of ammonium, total suspended solids (TSS), and total phosphorus (TP) than the Fertilized Field, but nitrate load was significantly lower. Nitrate load transport in drainage water from the Unfertilized Field was 58% of that from the Fertilized Field. Linear regression analysis indicated that a 1% increase in flow depth resulted in a 1.05% increase of TSS load from the City Stormwater, a 1.07% increase in nitrate load from the Fertilized Field, and a 1.11% increase in TP load from the Fertilized Field. This indicates an increase in concentration with a rise in flow depth, revealing that concentration variation was a significant factor influencing the dynamics of load transport. Further regression analysis showed the importance of targeting high flows to reduce contaminant transport. In conclusion, for watersheds similar to this one, management practices should be directed to load reduction of ammonium and TSS from urban areas, and nitrate from cropland while TP should be a target for both. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
33. Corn Response to Nitrogen Management under Fully-Irrigated vs. Water-Stressed Conditions.
- Author
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Maharjan, Bijesh, Rosen, Carl J., Lamb, John A., and Venterea, Rodney T.
- Abstract
Characterizing corn (Zea mays L.) grain yield (GY) response to N is critical for maximizing profits, increasing N use efficiency and minimizing environmental impacts. Although a large database of GY response to N exists for highly productive soils, few data exist for less productive soils. While changes in precipitation are expected in the future, few studies have compared GY response to varying N management practices under conditions of varying water availability. We measured GY and basal stalk nitrate nitrogen (BSN) at harvest using split-applied urea at eight N rates under fully-irrigated (FI) and water-stressed (WS) conditions in a loamy sand over 2 yr (2009 and 2010). We also measured GY and BSN using single, pre-plant applications of urea, polymer-coated urea (PCU) and urea amended with urease and nitrification inhibitors (IU) at one or two N rates. The results showed that economic optimum nitrogen rate (EONR) and agronomic optimum nitrogen rate (AONR) did not vary by water management, in spite of signifi cant increases in GY (up to 48%) under FI compared to WS. Modifi cation of N fertilizer timing or N source was effective for increasing GY (by 18-41%) with FI, but did not affect GY under WS conditions. Averaged across years, BSN was greater with WS compared to FI at most N rates; however, BSN corresponding to AONR was within the optimal range for both water regimes. These findings may have important implications in areas where changes in irrigation practices or water availability are expected under future climate conditions. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
34. Evaluation of a Quick Test to Assess Polymer-Coated Urea Prill Damage.
- Author
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Bierman, Peter M., Crants, James E., and Rosen, Carl J.
- Abstract
Polymer-coated ureas (PCUs) can reduce N leaching in potato (Solanum tuberosum L.) production while maintaining yields. However, damage to the polymer coating during handling increases N release and potentially affects leaching and crop response. A 2-yr study was conducted to develop a quick test of PCU damage, compare its results with N release under field conditions, and determine damage effects on N uptake and yield in field experiments. A 24-h water immersion procedure was developed to measure N release differences from two sources of the PCU fertilizer Environmentally Smart Nitrogen (ESN) handled in different ways: ESN(C), dealer grade undamaged control, and ESN(A), damaged by air boom spreader application. Nitrogen release from ESN(A) was more rapid in both the 24-h test and during in situ soil incubation. Quick test results were positively correlated with N release during the first 7 d of field incubation (R² = 0.91, adjusted R² = 0.86). Differences in prill damage between ESN(C) and ESN(A) were greater in 2010 than 2011. Limited crop response differences occurred in 2011, but in 2010 petiole nitrate-N was more stable and higher late in the season for ESN(C) than ESN(A), and tuber, vine, and total N uptake were significantly greater for ESN(C). Tuber yield and size were not significantly affected by ESN damage. Based on these results, the quick test provides an accurate assessment of potential differences in N release during the growing season due to coating damage and can be used to evaluate leaching potential and possible need for fertigation. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
35. Co-application of DMPSA and NBPT with urea mitigates both nitrous oxide emissions and nitrate leaching during irrigated potato production.
- Author
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Souza, Emerson F.C., Rosen, Carl J., and Venterea, Rodney T.
- Subjects
POTATOES ,NITROUS oxide ,LEACHING ,NITRIFICATION inhibitors ,UREA ,IRRIGATED soils ,GROWING season - Abstract
Potato (Solanum tuberosum L.) production in irrigated coarse-textured soils requires intensive nitrogen (N) fertilization which may increase reactive N losses. Biological soil additives including N-fixing microbes (NFM) have been promoted as a means to increase crop N use efficiency, though few field studies have evaluated their effects, and none have examined the combined use of NFM with microbial inhibitors. A 2-year study (2018–19) in an irrigated loamy sand quantified the effects of the urease inhibitor NBPT, the nitrification inhibitor DMPSA, NFM, and the additive combinations DMPSA + NBPT and DMPSA + NFM on potato performance and growing season nitrous oxide (N 2 O) emissions and nitrate (NO 3
− ) leaching. All treatments, except a zero-N control, received diammonium phosphate at 45 kg N ha−1 and split applied urea at 280 kg N ha−1 . Compared with urea alone, DMPSA + NBPT reduced NO 3− leaching and N 2 O emissions by 25% and 62%, respectively, and increased crop N uptake by 19% in one year, although none of the additive treatments increased tuber yields. The DMPSA and DMPSA + NBPT treatments had greater soil ammonium concentration, and all DMPSA-containing treatments consistently reduced N 2 O emissions, compared to urea-only. Use of NBPT by itself reduced NO 3− leaching by 21% across growing seasons and N 2 O emissions by 37% in 2018 relative to urea-only. In contrast to the inhibitors, NFM by itself increased N 2 O by 23% in 2019; however, co-applying DMPSA with NFM reduced N 2 O emissions by ≥ 50% compared to urea alone. These results demonstrate that DMPSA can mitigate N 2 O emissions in potato production systems and that DMPSA + NBPT can reduce both N 2 O and NO 3− losses and increase the N supply for crop uptake. This is the first study to show that combining a nitrification inhibitor with NFM can result in decreased N 2 O emissions in contrast to unintended increases in N 2 O emissions that can occur when NFM is applied by itself. [Display omitted] • DMPSA + NBPT reduced N 2 O emissions and NO 3− leaching from urea applied to potato. • Applied as single inhibitors, DMPSA mitigated N 2 O and NBPT reduced NO 3− leaching. • Double-inhibitors increased potato N-uptake when extreme rainfall events occurred. • Tuber yield was not affected by either inhibitor or by N-fixing microbes. • N-fixing microbes demonstrated a potential to increase N 2 O emissions. DMPSA + NBPT reduced growing season N 2 O emissions and NO 3− leaching from urea applied to potato cultivated in irrigated coarse-textures soils. [ABSTRACT FROM AUTHOR]- Published
- 2021
- Full Text
- View/download PDF
36. Improving Potato Yield Prediction by Combining Cultivar Information and UAV Remote Sensing Data Using Machine Learning.
- Author
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Li, Dan, Miao, Yuxin, Gupta, Sanjay K., Rosen, Carl J., Yuan, Fei, Wang, Chongyang, Wang, Li, and Huang, Yanbo
- Subjects
REMOTE sensing ,MACHINE learning ,POTATOES ,MULTISPECTRAL imaging ,GROWING season ,RANDOM forest algorithms ,PRECISION farming - Abstract
Accurate high-resolution yield maps are essential for identifying spatial yield variability patterns, determining key factors influencing yield variability, and providing site-specific management insights in precision agriculture. Cultivar differences can significantly influence potato (Solanum tuberosum L.) tuber yield prediction using remote sensing technologies. The objective of this study was to improve potato yield prediction using unmanned aerial vehicle (UAV) remote sensing by incorporating cultivar information with machine learning methods. Small plot experiments involving different cultivars and nitrogen (N) rates were conducted in 2018 and 2019. UAV-based multi-spectral images were collected throughout the growing season. Machine learning models, i.e., random forest regression (RFR) and support vector regression (SVR), were used to combine different vegetation indices with cultivar information. It was found that UAV-based spectral data from the early growing season at the tuber initiation stage (late June) were more correlated with potato marketable yield than the spectral data from the later growing season at the tuber maturation stage. However, the best performing vegetation indices and the best timing for potato yield prediction varied with cultivars. The performance of the RFR and SVR models using only remote sensing data was unsatisfactory (R
2 = 0.48–0.51 for validation) but was significantly improved when cultivar information was incorporated (R2 = 0.75–0.79 for validation). It is concluded that combining high spatial-resolution UAV images and cultivar information using machine learning algorithms can significantly improve potato yield prediction than methods without using cultivar information. More studies are needed to improve potato yield prediction using more detailed cultivar information, soil and landscape variables, and management information, as well as more advanced machine learning models. [ABSTRACT FROM AUTHOR]- Published
- 2021
- Full Text
- View/download PDF
37. Relating nitrogen use efficiency to nitrogen nutrition index for evaluation of agronomic and environmental outcomes in potato.
- Author
-
Bohman, Brian J., Rosen, Carl J., and Mulla, David J.
- Subjects
- *
NUTRITIONAL assessment , *NITROGEN , *BIOMASS - Abstract
• Nitrogen use efficiency [NUE] is best understood in terms of its constituent parts. • Interpreting N utilization efficiency depends on both N nutrition index and biomass. • A critical N utilization efficiency curve can be defined based on previous theory. • Increasing N uptake efficiency [NUpE] will reduce N losses to the environment. • Maximizing NUE does not necessarily improve agronomic or environmental outcomes. Maximizing nitrogen (N) use efficiency [NUE] is commonly identified as a key strategy to improve both agronomic and environmental outcomes; however, interpretation of NUE requires explicit consideration of crop N status. In this study, we derived a set of novel theoretical relationships between the nitrogen nutrition index [NNI] and NUE used to better interpret values for nitrogen uptake efficiency [NUpE] and nitrogen utilization efficiency [NUtE]. A small-plot trial for potato [ Solanum tuberosum (L.) 'Russet Burbank'] was conducted in 2016 and 2017 in Central Minnesota, USA, on a Hubbard loamy sand with six N rate, source, and timing treatments and two irrigation rate treatments. Impacts of treatments on NNI, NUpE, NUtE, NUE, biomass, harvest index, and potential N losses were interpreted within the context of a theoretical quantitative relationship between NUE and NNI. We found that for a constant NNI value, NUtE values increased non-linearly as biomass increased; at an NNI value of 1.0, this relationship defines the critical N utilization efficiency curve. As N rate increased from 40 to 270 kg N ha−1, NUtE significantly decreased from 109.8–69.7 g g−1 N, corresponding with a significant increase in both biomass (from 12.0–17.8 Mg ha−1) and in NNI (from 0.520 to 0.973), respectively. Additionally, we found that potential N losses (e.g., leaching) decreased as NUpE increased, or as total N inputs decreased. Potential N loss was lower in 2016 than 2017 (135 and 187 kg N ha−1, respectively) due to both greater NUpE and lower total N input from all sources in 2016 (0.602 g N g-1 N and 339 kg N ha-1, respectively) than in 2017 (0.526 g N g-1 N and 395 kg N ha-1, respectively). Interpreting NUE to evaluate agronomic and environmental outcomes requires separate consideration of its constituent factors (e.g., NUpE, NUtE, and HI) and explicit consideration of both NNI and biomass. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
38. Potassium: A Vital Macronutrient in Potato Production—A Review.
- Author
-
Torabian, Shahram, Farhangi-Abriz, Salar, Qin, Ruijun, Noulas, Christos, Sathuvalli, Vidyasagar, Charlton, Brian, Loka, Dimitra A., Souza, Emerson F. C., Rosen, Carl J., and Soratto, Rogério P.
- Subjects
POTATOES ,PLANT growth ,POTASSIUM ,POTASSIUM sulfate ,POTASSIUM chloride ,TUBERS - Abstract
Potassium (K) is a primary macronutrient for overall plant growth, yield potential, product quality and stress resistance of crops. Potato (Solanum tuberosum L.) crops require a high amount of potassium to achieve the ideal yield and quality. Therefore, the determination of optimum K rate and efficient source for potato is necessary because K affects crop physiological processes, dry matter production, cooking, and processing requirements. Through modeling on the pooled data extracted from 62 studies, the highest tuber yields might be obtained at an exchangeable soil K level of 200 mg kg
−1 approximately, dependent on soil pH, texture, and organic matter. Through modeling on the data of 48 studies, it also revealed that application of potassium sulfate (K2 SO4 ) and potassium chloride (KCl) at rates of 200 kg ha−1 and potassium nitrate (KNO3 ) at a rate of 100 kg ha−1 might achieve the ideal yield, implying the importance of K sources in potato production. However, these values (either soil exchangeable K content, or fertilizer rates) might not be applicable in a specific growing environment for a specific potato variety. It seems that there is no discrimination among split, pre-plant or in-season application of K, although pre-plant fertilization might be a trustworthy strategy for economic tuber yield. Owing to the luxury consumption of K by potato crop, a combination of factors, including soil exchangeable K level, petiole K concentration, crop removal amount, soil conditions, management practices, climatic conditions, and potato variety, should be considered in order to make rational K fertilizer recommendations. [ABSTRACT FROM AUTHOR]- Published
- 2021
- Full Text
- View/download PDF
39. Pennycress as a Cash Cover-Crop: Improving the Sustainability of Sweet Corn Production Systems.
- Author
-
Moore, Sarah A., Wells, M. Scott, Gesch, Russ W., Becker, Roger L., Rosen, Carl J., and Wilson, Melissa L.
- Subjects
SWEET corn ,COVER crops ,CATCH crops ,CORN residues ,SEED harvesting ,CROPS ,CORN harvesting - Abstract
Commercial sweet corn (Zea mays convar. saccharata var. rugosa) production has a proportionally high potential for nutrient loss to waterways, due to its high nitrogen (N) requirements and low N use efficiency. Cover crops planted after sweet corn can help ameliorate N lost from the field, but farmers are reluctant to utilize cover crops due to a lack of economic incentive. Pennycress (Thlaspi arvense L.) is a winter annual that can provide both economic and environmental benefits. Five N-rates (0, 65, 135, 135 split and 200) were applied pre-plant to sweet corn. After the sweet corn harvest, pennycress was planted into the sweet corn residue with two seeding methods and harvested for seed the following spring. Residual inorganic soil N (N
min ), pennycress biomass, biomass N and yield were measured. The nitrogen rate and seeding method had no effect on pennycress yield, biomass, or biomass N content. The nitrogen rate positively affected Nmin at pennycress seeding, wherein 200N plots had 38–80% higher Nmin than 0N plots, but had no effect on Nmin at pennycress harvest. Control treatments without pennycress had an average of 27–42% greater Nmin . In conclusion, pennycress can act as an effective N catch crop, and produce an adequate seed yield after sweet corn without the need for supplemental fertilization. [ABSTRACT FROM AUTHOR]- Published
- 2020
- Full Text
- View/download PDF
40. Potato Tuber Chemical Properties in Storage as Affected by Cultivar and Nitrogen Rate: Implications for Acrylamide Formation.
- Author
-
Sun, Na, Wang, Yi, Gupta, Sanjay K., and Rosen, Carl J.
- Subjects
ACRYLAMIDE ,CHEMICAL properties ,TUBERS ,POTATOES ,CULTIVARS ,FOOD storage ,COMPOSITION of potatoes ,GLUCOSE - Abstract
Recently released potato cultivars Dakota Russet and Easton were bred for low reducing sugars, and low acrylamide-forming potential in French fries. The objectives of this study were to determine: (1) the effects of nitrogen rate and storage time on tuber glucose concentrations in different cultivars; (2) the relationships between acrylamide, glucose, and asparagine for the new cultivars and Russet Burbank. The study was conducted at Becker, Minnesota over a period of two years on a loamy sand soil under irrigated conditions. All cultivars were subjected to five N rates from 135 to 404 kg ha
−1 in a randomized complete block design. Following harvest, tubers were stored at 7.8 °C and sampled at 0, 16, and 32 weeks. Dakota Russet and Easton had significantly lower concentrations of stem- and bud-end glucose, asparagine, and acrylamide than those of Russet Burbank in both years. The effect of storage time on glucose concentration was significant but differed with cultivar and year. N rate effects on stem- and bud-end glucose concentrations were cultivar and storage time dependent. After 16 weeks of storage, both asparagine and acrylamide concentrations linearly increased with increasing N rate. Glucose concentration was positively correlated with acrylamide concentration (r2 = 0.61). Asparagine concentration was also positively correlated with acrylamide concentration (r2 = 0.45) when the asparagine:glucose ratio was <1.306. The correlation between fry color and stem-end glucose concentration was significant over three cultivars in both years, but stronger in a growing season with minimal environmental stress. Taken together, these results suggest that while acrylamide formation during potato processing is a complex process affected by agronomic practices, environmental conditions during the growing season, and storage conditions, cultivar selection may be the most reliable method to minimize acrylamide in fried products. [ABSTRACT FROM AUTHOR]- Published
- 2020
- Full Text
- View/download PDF
41. Exploring Overwintered Cover Crops as a Soil Management Tool in Upper-midwest High Tunnels.
- Author
-
Perkus, Elizabeth A., Grossman, Julie M., Pfeiffer, Anne, Rogers, Mary A., and Rosen, Carl J.
- Subjects
- *
COVER crops , *CROP management , *SOIL management , *ENERGY crops , *CAPSICUM annuum , *RED clover - Abstract
High tunnels are an important season extension tool for horticultural production in cold climates, however maintaining soil health in these intensively managed spaces is challenging. Cover crops are an attractive management tool to address issues such as decreased organic matter, degraded soil structure, increased salinity, and high nitrogen needs. We explored the effect of winter cover crops on soil nutrients, soil health and bell pepper (Capsicum annuum) crop yield in high tunnels for 2 years in three locations across Minnesota. Cover crop treatments included red clover (Trifolium pratense) monoculture, Austrian winter pea/winter rye biculture (Pisum sativum/Secale cereale), hairy vetch/winter rye/tillage radish (Vicia villosa/ S. cereale/Raphanus sativus) polyculture, and a bare-ground, weeded control. Cover crop treatments were seeded in two planting date treatments: early planted treatments were seeded into a standing bell pepper crop in late Aug/early September and late planted treatments were seeded after bell peppers were removed in mid-September At termination time in early May, all cover crops had successfully overwintered and produced biomass in three Minnesota locations except for Austrian winter pea at the coldest location, zone 3b. Data collected include cover crop and weed biomass, biomass carbon and nitrogen, extractable soil nitrogen, potentially mineralizable nitrogen, microbial biomass carbon, permanganate oxidizable carbon, soil pH, soluble salts (EC), and pepper yield. Despite poor legume performance, increases in extractable soil nitrogen and potentially mineralizable nitrogen in the weeks following cover crop residue incorporation were observed. Biomass nitrogen contributions averaged 100 kg·ha-1 N with an observed high of 365 kg·ha-1 N. Cover crops also reduced extractable soil N in a spring sampling relative to the bare ground control, suggesting provision of nitrogen retention ecosystem services. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
42. Carbon supplementation and bioaugmentation to improve denitrifying woodchip bioreactor performance under cold conditions.
- Author
-
Feyereisen, Gary W., Wang, Hao, Wang, Ping, Anderson, Emily L., Jang, Jeonghwan, Ghane, Ehsan, Coulter, Jeffrey A., Rosen, Carl J., Sadowsky, Michael J., and Ishii, Satoshi
- Subjects
- *
BIOREMEDIATION , *SPRING , *COLD (Temperature) , *DIETARY supplements , *CARBON - Abstract
Cold temperatures limit nitrate-N load reductions of woodchip bioreactors in higher-latitude climates. This two-year, on-farm (Willmar, Minnesota, USA) study was conducted to determine whether field-scale nitrate-N removal of woodchip bioreactors can be improved by the addition of cold-adapted, locally isolated bacterial denitrifying strains (bioaugmentation) or dosing with a carbon (C) source (biostimulation). In Spring 2017, biostimulation removed 66% of the nitrate-N load, compared to 21% and 18% for bioaugmentation and control, respectively. The biostimulation nitrate-N removal rate (NRR) was also significantly greater, 15.0 g N m−3 d−1, versus 5.8 and 4.4 g N m−3 d−1, for bioaugmentation and control, respectively. After five weeks of operation, bioclogging of the biostimulation beds limited dosing for the remainder of the experiment; NRR was greater for biostimulation in Fall 2017, but in Spring 2018 there were no differences among treatments. Carbon dosing did not increase outflow of dissolved organic C concentration. The abundance of one of the inoculated strains, Cellulomonas cellacea strain WB94, increased over time, while another, Microvirgula aerodenitrificans strain BE2.4, increased briefly, returning to background levels after 42 d. Eleven days after inoculation in Spring 2017, outflow nitrate-N concentrations of bioaugmentation were sporadically reduced compared to the control for two weeks, but the effects were insignificant over the study period. The study suggests that biostimulation and bioaugmentation are promising technologies to enhance nitrate removal during cold conditions. A means of controlling bioclogging is needed for biostimulation, and improved means of inoculation and maintaining abundance of introduced strains is needed for bioaugmentation. In conclusion, biostimulation showed greater potential than bioaugmentation for increasing nitrate removal in a woodchip bioreactor, whereas both methods need improvement before implementation at the field scale. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
43. Split application of stabilized ammonium nitrate improved potato yield and nitrogen-use efficiency with reduced application rate in tropical sandy soils.
- Author
-
Souza, Emerson F.C., Soratto, Rogério P., Sandaña, Patricio, Venterea, Rodney T., and Rosen, Carl J.
- Subjects
- *
POTATO yields , *SANDY soils , *AMMONIUM nitrate , *POTATOES , *NITRIFICATION inhibitors , *IRRIGATED soils - Abstract
• A comprehensive assessment of the effectiveness of nitrification inhibitor DMPP under varying N rates and application timings on potato yield and NUE under tropical conditions was performed. • Compared to the conventional practice, split applied ammonium sulfate nitrate with DMPP (ASN + DMPP), at either 75% or 100% of recommended N rate (RNR), reduced N surplus in site-years with greater rainfall events and consistently increased potato tuber yield. • At reduced N rate (75% of RNR), single ASN + DMPP application at planting decreased potato yield, but at 100% of RNR potato production was not different from that receiving conventional N fertilization. • The mutual agronomic, economic, and environmental benefits of split-applied ASN + DMPP at 75% of RNR can contribute to the increased sustainability of tropical potato cropping systems. However, further studies are needed to confirm these benefits in other agro-ecosystems. Urea is the dominant nitrogen (N) fertilizer used for potato (Solanum tuberosum L.) cultivation in most parts of the world. Fertilizers containing a nitrification inhibitor (NI) claim to improve performance of crops including potato. No studies to date have conducted comprehensive assessment of N sources and the effectiveness of NI under varying N rates or application timings to enhance potato yield, tuber quality or N-use efficiency (NUE) in tropical regions. Three field experiments were conducted on irrigated sandy soils in southeastern Brazil to determine whether single or split application of ammonium sulfate nitrate (ASN) with the NI 3,4-dimethylpyrazole phosphate (DMPP) at reduced (75%) or recommended N rates (RNR, 100% = 160 kg ha-1) could improve yield, quality and/or NUE of 'Agata' potato over conventional split-applied urea at 100% of RNR. Compared to the conventional practice, split-applied ASN + DMPP, at either 75% or 100% of RNR, increased fresh tuber yield by an average of 15% across all site-years (SYs) and reduced N surplus in SYs with greater rainfall events suggesting that reactive N losses to the environment were also reduced. With split-applied ASN + DMPP at 75% of RNR, fresh tuber yield per unit of applied N increased by 34% compared to split-applied ASN + DMPP at 100% of RNR, and by 50–75% compared to a single application of ASN + DMPP at planting. These results demonstrate a mutually beneficial opportunity, where the rate of split-applied ASN + DMPP can be reduced by 25% while at the same time increasing yields, thus resulting in agronomic, economic, and environmental benefits due to the decreased potential for off-site reactive N losses. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
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