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1. BASALISC: Programmable Hardware Accelerator for BGV Fully Homomorphic Encryption

Author

Robin Geelen, Michiel Van Beirendonck, Hilder V. L. Pereira, Brian Huffman, Tynan McAuley, Ben Selfridge, Daniel Wagner, Georgios Dimou, Ingrid Verbauwhede, Frederik Vercauteren, and David W. Archer

Subjects
Fully homomorphic encryption, Brakerski-Gentry-Vaikuntanathan, Hardware accelerator, Application-specific integrated circuit, Computer engineering. Computer hardware, TK7885-7895, Information technology, T58.5-58.64
Abstract

Fully Homomorphic Encryption (FHE) allows for secure computation on encrypted data. Unfortunately, huge memory size, computational cost and bandwidth requirements limit its practicality. We present BASALISC, an architecture family of hardware accelerators that aims to substantially accelerate FHE computations in the cloud. BASALISC is the first to implement the BGV scheme with fully-packed bootstrapping – the noise removal capability necessary for arbitrary-depth computation. It supports a customized version of bootstrapping that can be instantiated with hardware multipliers optimized for area and power. BASALISC is a three-abstraction-layer RISC architecture, designed for a 1 GHz ASIC implementation and underway toward 150mm2 die tape-out in a 12nm GF process. BASALISC’s four-layer memory hierarchy includes a two-dimensional conflict-free inner memory layer that enables 32 Tb/s radix-256 NTT computations without pipeline stalls. Its conflict-resolution permutation hardware is generalized and re-used to compute BGV automorphisms without throughput penalty. BASALISC also has a custom multiply-accumulate unit to accelerate BGV key switching. The BASALISC toolchain comprises a custom compiler and a joint performance and correctness simulator. To evaluate BASALISC, we study its physical realizability, emulate and formally verify its core functional units, and we study its performance on a set of benchmarks. Simulation results show a speedup of more than 5,000× over HElib – a popular software FHE library.

Published
2023
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2. Nitrogen bound to manure fiber is increased by applications of simple phenolic acids

Author

Jonathan J. Halvorson, Scott L. Kronberg, Rachael G. Christensen, Ann E. Hagerman, and David W. Archer

Subjects
Manure, Acid detergent fiber, Nitrogen, Phenolic acids, Hydroxybenzoic acids, Hydroxycinnamic acids, Agriculture (General), S1-972
Abstract

Abstract Background Polyphenolic compounds like tannins can increase nitrogen (N) excreted in feces when consumed by ruminants but less often noted is increased N in fecal acid detergent fiber (ADF-N). Some simple phenolics are thought to facilitate binding interactions between nitrogenous compounds and soil. We hypothesized that contact with common phenolic acids, such as found in crops, could increase ADF-N, in excreted manure. Methods We performed two separate experiments to test our hypothesis. In the first experiment, we applied three solutions (i.e., 0.001, 0.01, 0.1 M) of sodium benzoate (B0), sodium 4-hydroxybenzoate (B1), 3,4-dihydroxybenzoic acid (B2), gallic acid (B3), ammonium benzoate (AB), and ammonium chloride (AC) to dried pulverized manure and measured ADF-N. In the second experiment we modified the methodology, by applying more compounds at a single concentration (0.001 M) and including an added nitrogen (NH4Cl) treatment. Results We found a statistically significant interaction between treatment and concentration in the first experiment (P

Published
2022
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3. Carbon fluxes from a spring wheat–corn–soybean crop rotation under no‐tillage management

Author

Mark A. Liebig, Nicanor Z. Saliendra, and David W. Archer

Subjects
Agriculture, Environmental sciences, GE1-350
Abstract

Abstract The increase in corn (Zea mays L.) and soybean [Glycine max (L.) Merr.] production in rainfed cropping systems of the northern Great Plains (NGP) has altered the delivery of ecosystem services from agricultural land. To date, there is limited understanding about how these crops affect the carbon (C) balance of cropping systems in the region when included in a short rotation window. This study sought to quantify C balance of a spring wheat (Triticum aestivum L.)–corn—soybean rotation under no‐tillage management using eddy covariance (EC) techniques. Paired field sites with the same soil type near Mandan, ND, were used for the study. Annual net ecosystem production (NEP) by crop was –34, 120, and 7 g C m–2 y–1 for spring wheat, corn, and soybean, respectively. Carbon removed in grain over the rotation was less than a third of C lost by ecosystem respiration (ER) (210 vs. 674 g C m–2 y–1). After accounting for grain C removal, net ecosystem carbon balance (NECB) was –164, –253, and –121 g m–2 y–1 for spring wheat, corn, and soybean, respectively, with a mean NECB of –179 ± 39 g C m–2 y–1 (P = .043; t test for difference from zero), implying the rotation was a net C source. Time associated with active crop growth each year was 27% for spring wheat, 41% for corn, and 28% for soybean. Management strategies that lengthen the period of biomass growth may mitigate C loss from spring wheat–corn–soybean rotations in the NGP.

Published
2022
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4. Rotating perennial forages into annual wheat cropping systems: Correlations between plant available soil and grain mineral concentrations

Author

Andrea K. Clemensen, Sara E. Duke, José G. Franco, Michael A. Grusak, Mark A. Liebig, John R. Hendrickson, and David W. Archer

Subjects
Agriculture, Environmental sciences, GE1-350
Abstract

Abstract Correlations between plant available soil and grain mineral concentrations are often assumed, yet few studies examine these associations. Here, soil and wheat grain samples were analyzed from a semi‐arid dryland cropping study in the northern Great Plains conducted between 2006 and 2011. Continuous spring wheat (fertilized) (Triticum aestivum L; CSW) was compared with wheat following 5 yr of perennial forages of either alfalfa (Medicago sativa L.), intermediate wheatgrass (fertilized) (Thinopyrum intermedium (Host) Barkw. & D.R. Dewey sbsp. Intermedium; IWG), or an alfalfa/intermediate wheatgrass mixture (fertilized; MIX). Wheat performance (yield, 1,000 kernel weight [TKW], and crude protein [CP] concentration), and associations between 11 plant available soil mineral concentrations and 11 wheat grain mineral concentrations were assessed. Wheat following alfalfa had greater yield than all treatments, greater TKW than CSW, greater CP than IWG and CSW, but lower grain Zn concentration than IWG (p ≤ .05). Wheat grain following IWG had greater Fe and Mn concentration than MIX, greater Mg concentration than CSW, and lower S concentration than all treatments (p

Published
2022
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5. ESTIMATING ECONOMIC EFFICIENCY UNDER RISK FOR AGRICULTURAL COOPERATIVES

Author

Krishna Prasad Pokharel, Allen M. Featherstone, and David W. Archer

Subjects
agribusiness, cost efficiency, data envelopment analysis, downside risk, revenue efficiency, Agriculture
Abstract

This study examined the impact of downside risk on cost efficiency (CE) and revenue efficiency (RE) for a sample of agricultural cooperatives. Downside risk is an appropriate measure of risk as it accounts for loss below the target return level regardless of individuals’ risk preference. The semi-variance of return on equity was used a measure of downside risk. CE and RE were estimated using data envelopment analysis (DEA) without adjusting for downside risk and then re-estimated adjusting for downside risk. The average CE and RE scores were higher with the inclusion of downside risk than the scores without downside risk. The DEA method without accounting for risk overestimates inefficiency and may misguide managers on adjustments needed to improve performance.

Published
2019

6. Beef Production in the Southwestern United States: Strategies Toward Sustainability

Author

Sheri Spiegal, Andres F. Cibils, Brandon T. Bestelmeyer, Jean L. Steiner, Richard E. Estell, David W. Archer, Brent W. Auvermann, Stephanie V. Bestelmeyer, Laura E. Boucheron, Huiping Cao, Andrew R. Cox, Daniel Devlin, Glenn C. Duff, Kristy K. Ehlers, Emile H. Elias, Craig A. Gifford, Alfredo L. Gonzalez, John P. Holland, Jenny S. Jennings, Ann M. Marshall, David I. McCracken, Matthew M. McIntosh, Rhonda Miller, Mark Musumba, Robert Paulin, Sara E. Place, Matthew Redd, C. Alan Rotz, Cindy Tolle, and Anthony Waterhouse

Subjects
Southwestern United States, rangelands, sustainable agricultural systems, Coordinated Agricultural Project, pericoupling framework, Nutrition. Foods and food supply, TX341-641, Food processing and manufacture, TP368-456
Abstract

From grazing lands to meat packing, beef production systems in the United States are striving to meet global demands without compromising environmental quality or local profitability. These challenges and opportunities are manifest in four US regions connected ecologically and socially through beef production: the American Southwest, the Ogallala Aquifer region, the Northern Plains, and the Upper Midwestern Corn Belt. Most calves raised on extensive, arid Southwestern ranches are exported to the Ogallala Aquifer region for finishing on grains that are grown either locally on Ogallala Aquifer water or imported from the Upper Midwest. Changes in climate, vegetation, and human demographics threaten the sustainability of the regionally-interconnected system. Heritage cattle genetics, precision ranching, and alternative supply chain options are three strategies that show promise for addressing these sustainability threats, but major knowledge gaps exist. For instance, while environmentally-friendly landscape use by Raramuri Criollo, a heritage cattle type, has been identified in several arid rangeland settings, little is known about their performance in conventional feed yards. While precision agriculture is already prevalent in croplands, less is known about how such technologies can be cost effective in arid rangelands. Moreover, many perceive grass-finishing on rangeland as environmentally friendly and beneficial for local agricultural communities, but tradeoffs involving greenhouse gas emissions, increased rangeland use, and disruption of cattle feeding systems of the Ogallala Aquifer region must be assessed. Here we introduce a USDA-NIFA Coordinated Agricultural Project designed to fill these knowledge gaps and advance sustainability of beef production linked to the US Southwest. With a boundary-spanning approach of education, participatory research, and extension, the project is identifying tradeoffs of the three strategies with explicit attention to pericoupling (i.e., socioeconomic and environmental interactions) of regions connected by beef production and full consideration of the coupled ecological and social systems within those regions.

Published
2020
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7. Winter Triticale: A Long-Term Cropping Systems Experiment in a Dry Mediterranean Climate

Author

William F. Schillinger and David W. Archer

Subjects
alternative crops, straw, crop rotation, dry Mediterranean climate, economics, winter triticale, Agriculture
Abstract

Triticale (X Triticosecale Wittmack) is a cereal feed grain grown annually worldwide on 4.2 million ha. Washington is the leading state for rainfed (i.e., non-irrigated) triticale production in the USA. A 9-year dryland cropping systems project was conducted from 2011 to 2019 near Ritzville, WA to compare winter triticale (WT) with winter wheat (Triticum aestivum L.) (WW) grown in (i) a 3-year rotation of WT-spring wheat (SW) -no-till summer fallow (NTF) (ii) a 3-year rotation of WW-SW-undercutter tillage summer fallow (UTF) and (iii) a 2-year WW-UTF rotation, We measured grain yield, grain yield components, straw production, soil water dynamics, and effect on the subsequent SW wheat crop (in the two 3-year rotations). Enterprise budgets were constructed to evaluate the production costs and profitability. Grain yields averaged over the years were 5816, 5087, and 4689 kg/ha for WT, 3-year WW, and 2-year WW, respectively (p < 0.001). Winter triticale used slightly less water than WW (p = 0.019). Contrary to numerous reports in the literature, WT never produced more straw dry biomass than WW. Winter wheat produced many more stems than WT (p < 0.001), but this was compensated by individual stem weight of WT being 60% heavier than that of WW (p < 0.001). Spring wheat yield averaged 2451 vs. 2322 kg/ha after WT and WW, respectively (p = 0.022). The market price for triticale grain was always lower than that for wheat. Winter triticale produced an average of 14 and 24% more grain than 3-year and 2-year WW, respectively, provided foliar fungal disease control, risk reduction, and other rotation benefits, but was not economically competitive with WW. A 15–21% increase in WT price or grain yield would be necessary for the WT rotation to be as profitable as the 3-year and 2-year WW rotations, respectively.

Published
2020
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8. Management Drives Differences in Nutrient Dynamics in Conventional and Organic Four-Year Crop Rotation Systems

Author

Sharon L. Weyers, David W. Archer, Jane M.F. Johnson, and Alan R. Wilts

Subjects
N-availability, mineralization, C-sequestration, manure, soil organic matter, Agriculture
Abstract

Application of exogenous N fertilizers provides agronomic benefits but carries environmental liabilities. Managing benefits and liabilities of N-based fertilizers in conventional (CNV) and organic (ORG) cropping systems might be improved with better knowledge of nutrient dynamics, the generation of intrinsic N, and maintenance of soil organic matter. This study evaluated mineral N dynamics, yields, residue inputs, and change in soil organic C (SOC) and total N (TN) in strip-tilled, four-year crop rotations [corn (Zea mays L.)-soybean (Glycine max [L.] Merr.)-wheat under-seeded with alfalfa (Triticum aestivum L./Medicago sativa L.)-alfalfa] over eight years of production under CNV management using mineral-N (NO3NH4) and chemical pesticides or ORG management using organic-N (animal manure) and no chemical treatments. In ORG, N availability increased over time, but did not benefit ORG yields due to poor control of insects and weeds. Corn, soybean, and wheat grain yields were 1.9 to 2.7 times greater in CNV. In general, SOC was lost in CNV but did not change in ORG. Cumulative yield N removals exceeded cumulative fertilizer-N inputs by an average of 78% in CNV and 64% in ORG. These results indicated ORG management supported N availability by generating intrinsic N.

Published
2020
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9. Vertical Distribution of Structural Components in Corn Stover

Author

Jane M. F. Johnson, Douglas L. Karlen, Garold L. Gresham, Keri B. Cantrell, David W. Archer, Brian J. Wienhold, Gary E. Varvel, David A. Laird, John Baker, Tyson E. Ochsner, Jeff M. Novak, Ardell D. Halvorson, Francisco Arriaga, David T. Lightle, Amber Hoover, Rachel Emerson, and Nancy W. Barbour

Subjects
lignocellulosic biomass, theoretical ethanol yield, soil organic carbon, sustainable, bioenergy, second generation feedstock, Agriculture (General), S1-972
Abstract

In the United States, corn (Zea mays L.) stover has been targeted for second generation fuel production and other bio-products. Our objective was to characterize sugar and structural composition as a function of vertical distribution of corn stover (leaves and stalk) that was sampled at physiological maturity and about three weeks later from multiple USA locations. A small subset of samples was assessed for thermochemical composition. Concentrations of lignin, glucan, and xylan were about 10% greater at grain harvest than at physiological maturity, but harvestable biomass was about 25% less due to stalk breakage. Gross heating density above the ear averaged 16.3 ± 0.40 MJ kg−1, but with an alkalinity measure of 0.83 g MJ−1, slagging is likely to occur during gasification. Assuming a stover harvest height of 10 cm, the estimated ethanol yield would be >2500 L ha−1, but it would be only 1000 L ha−1 if stover harvest was restricted to the material from above the primary ear. Vertical composition of corn stover is relatively uniform; thus, decision on cutting height may be driven by agronomic, economic and environmental considerations.

Published
2014
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10. Net Global Warming Potential of Spring Wheat Cropping Systems in a Semiarid Region

Author

Mark A. Liebig, David W. Archer, Jonathan J. Halvorson, Holly A. Johnson, Nicanor Z. Saliendra, Jason R. Gross, and Donald L. Tanaka

Subjects
GRACEnet, Nitrous oxide, soil organic carbon, Agriculture
Abstract

Investigations of global warming potential (GWP) of semiarid cropping systems are needed to ascertain agriculture’s contributions to climate regulation services. This study sought to determine net GWP for three semiarid cropping systems under no-tillage management in the northern Great Plains of North America: spring wheat (Triticum aestivum L.)—fallow (SW-F), continuous spring wheat (CSW) and spring wheat—safflower (Carthamus tinctorius L.)—rye (Secale cereale L.) (SW-S-R). Management records, coupled with published carbon dioxide (CO2) emission estimates, were used to determine emissions from production inputs and field operations. Static chamber methodology was used to measure soil-atmosphere methane (CH4) and nitrous oxide (N2O) fluxes over a 3-year period and changes in profile soil organic carbon (SOC) stocks were determined over 18 years. Carbon dioxide emissions associated with production inputs and field operations were greatest for CSW, intermediate for SW-S-R and lowest for SW-F. All cropping systems were minor CH4 sinks (≤0.5 kg CH4-C ha−1 yr−1) and moderate N2O sources (1.0 to 2.8 kg N2O-N ha−1 yr−1). No differences in SOC stocks were observed among cropping systems (P = 0.78), nor did SOC stocks change significantly from baseline conditions (P = 0.82). Summing across factors, net GWP was positive for SW-F and CSW, implying net greenhouse gas (GHG) emission to the atmosphere, while net GWP for SW-S-R was negative, implying net GHG uptake. Net GWP, however, did not differ among cropping systems (P = 0.17). Management practices that concurrently improve N use efficiency and increase SOC stocks are needed for semiarid cropping systems to be net GHG sinks.

Published
2019
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11. Peer-to-Peer Enclaves for Improving Network Defence

Author

David W. Archer and Adam Wick

Subjects
cyber countermeasures, cybersecurity, dynamic cyberdefence, enclave computing, network defence, peer-to-peer, Technology (General), T1-995, Management. Industrial management, HD28-70
Abstract

Information about cyberthreats within networks spreads slowly relative to the speed at which those threats spread. Typical "threat feeds" that are commercially available also disseminate information slowly relative to the propagation speed of attacks, and they often convey irrelevant information about imminent threats. As a result, hosts sharing a network may miss opportunities to improve their defence postures against imminent attack because needed information arrives too late or is lost in irrelevant noise. We envision timely, relevant peer-to-peer sharing of threat information – based on current technologies – as a solution to these problems and as a useful design pattern for defensive cyberwarfare. In our setting, network nodes form communities that we call enclaves, where each node defends itself while sharing information on imminent threats with peers that have similar threat exposure. In this article, we present our vision for this solution. We sketch the architecture of a typical node in such a network and how it might interact with a framework for sharing threat information; we explain why certain defensive countermeasures may work better in our setting; we discuss current tools that could be used as components in our vision; and we describe opportunities for future research and development.

Published
2013

12. Crop Diversity Effects on Near-Surface Soil Condition under Dryland Agriculture

Author

Mark A. Liebig, David W. Archer, and Don L. Tanaka

Subjects
Agriculture (General), S1-972, Environmental sciences, GE1-350
Abstract

Unprecedented changes in agricultural land use throughout the northern Great Plains of North America have highlighted the need to better understand the role of crop diversity to affect ecosystem services derived from soil. This study sought to determine the effect of four no-till cropping systems differing in rotation length and crop diversity on near-surface (0 to 10 cm) soil properties. Cropping system treatments included small grain-fallow (SG-F) and three continuously cropped rotations (3 yr, 5 yr, and Dynamic) located in south-central North Dakota, USA. Soil pH was lower in the 3 yr rotation (5.17) compared to the Dynamic (5.51) and SG-F (5.55) rotations (P≤0.05). Among cropping system treatments, 5 yr and Dynamic rotations possessed significantly greater soil organic C (SOC) and total N (mean = 26.3 Mg C ha−1, 2.5 Mg N ha−1) compared to the 3 yr (22.7 Mg C ha−1, 2.2 Mg N ha−1) and SG-F (19.9 Mg C ha−1, 2.0 Mg N ha−1) rotations (P≤0.05). Comparison of SOC measured in this study to baseline values at the research site prior to the establishment of treatments revealed only the 5 yr and Dynamic rotations increased SOC over time. The results of this study suggest that a diverse portfolio of crops is necessary to minimize soil acidification and increase SOC.

Published
2014
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38. Late-seeded cover crops in a semiarid environment: overyielding, dominance and subsequent crop yield

Author

Kristine A. Nichols, Marty R. Schmer, David W. Archer, Mark A. Liebig, John R. Hendrickson, and Donald L. Tanaka

Subjects
0106 biological sciences, Crop yield, 04 agricultural and veterinary sciences, 01 natural sciences, Agronomy, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Dominance (ecology), Seeding, Cover crop, Agronomy and Crop Science, 010606 plant biology & botany, Food Science
Abstract

Interest in cover crops is increasing but information is limited on integrating them into crop rotations especially in the relatively short growing season on the northern Great Plains. A 3-yr research project, initiated in 2009 near Mandan, North Dakota, USA, evaluated (1) what impact cover crops may have on subsequent cash crops yields and (2) whether cover crop mixtures are more productive and provide additional benefits compared to cover crop monocultures. The study evaluated 18 different cover crop monocultures and mixtures that were seeded in August following dry pea (Pisum sativum L.). The following year, spring wheat (Triticum aestivum L.), corn (Zea mays L.), soybean (Glycine max L.) and field pea were seeded into the different cover crop treatments and a non-treated control. A lack of timely precipitation in 2009 resulted in a low cover crop yield of 17 g m2 compared to 100 and 77 g m2 in 2008 and 2010, respectively. Subsequent cash crop yield was not affected by late-seeded cover crops. Cool-season cover crop monocultures were more productive than warm-season monocultures and some mixtures in 2008 and 2010. Relative yield total did not differ from one in any cover crop mixture suggesting that overyielding did not occur. Species selection rather than species diversity was the most important contributor to cover crop yield. Cover crops can be grown following short-season cash crops in the northern Great Plains, but precipitation timing and species selection are critical.

Published
2021
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40. Life cycle assessment of wheat production and wheat‐based crop rotations

Author

Sandeep Kumar, James J. Stone, Heidi L. Sieverding, Christopher Graham, Thandi Nleya, Rifat A. Karim, David W. Archer, and Prashansa Shrestha

Subjects
Crops, Agricultural, Agroecosystem, Environmental Engineering, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, Agricultural science, Agricultural land, Animals, Agricultural productivity, Waste Management and Disposal, Life-cycle assessment, Triticum, 0105 earth and related environmental sciences, Water Science and Technology, Crop insurance, Life Cycle Stages, Agricultural diversification, business.industry, Agriculture, 04 agricultural and veterinary sciences, Crop rotation, Pollution, Crop Production, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, business
Abstract

In the northern Great Plains (NGP), wheat is the primary grain commodity. There is a need for the NGP to have a detailed analysis of environmental impacts for wheat-based agricultural production systems to better understand regional agroecosystems. This article provides a cradle-to-field gate life cycle assessment (LCA) for NGP dryland wheat (Triticum aestivum L.) production. The environmental impacts for winter wheat production using crop rotation and agricultural intensification are quantified. Fourteen no-till crop rotations ranging in duration from 2 to 6 yr were evaluated and compared using data from a historical 13-yr replicated rotation study (>300 observations). Midpoint LCA categories chosen for this comparison are energy, agricultural land use, climate change potential, freshwater eutrophication, and freshwater ecotoxicity due to their direct links with agricultural management practices. The NGP farmers commonly use a fallow period every other year due to moisture limitations. This specific agricultural practice and allocations within rotations are critical considerations within agricultural LCAs. Two aspects of fallow considerations and a sensitivity analysis were also performed. The allocated midpoint impacts between crops in rotational studies averaged 0.31, 0.79, 0.62, and 0.63 kg CO2 eq. per unit of winter wheat when energy, economic, mass, and cereal unit allocations were used, respectively. Economic analysis of the studied experimental crop was performed; results demonstrated that crop insurance policies improved diversification economics by 20%. Agricultural diversification benefits and burdens were better represented by endpoint damage assessments than by midpoint impact analysis.

Published
2020
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43. 306 Cattle Performance and Forage Nutrients While Grazing an Integrated Crop-Livestock System Compared with Grass Pasture in the Northern Great Plains

Author

Rachael G Christensen, Scott L Kronberg, John R Hendrickson, David W Archer, and Mark A Liebig

Subjects
Genetics, Animal Science and Zoology, General Medicine, Food Science
Abstract

Many integrated crop-livestock system (ICL) studies have been conducted, but few report cattle performance and forage nutrients. Here, we report one year of cattle weight gains for Angus yearling heifers and steers grazing ICL plots (ICL) or tame grass pastures (PAS) in four replicates. Five yearlings (avg. BW 390 ± 26 kg) were randomly assigned to graze each plot while provided ad libitum water and trace mineral salt. Cattle assigned to ICL grazed three crop rotations: 1) corn interseeded with soybean (C/S), 2) spring wheat interseeded with cover crop and 3) cover crop planted into spring wheat from the previous year. Yearlings in ICL were stocked first on green C/S, grazing an average of 60 days. Beginning C/S biomass was 1,827 ± 638 g m−2, yearling end BW was 465 ± 34 kg and ADG 1.28 ± 0.27 kg. Yearlings then grazed residual cover crop growth, averaging additional 42 d grazing while supplemented with a ration of baled cover crop forage, wheat straw, and corn. Ration intake averaged 15.35 ±0.6 kg animal-1 d-1. Final BW of ICL yearlings on cover crops averaged 499 ± 34 kg, ADG of 0.79 ± 0.29 kg. Yearlings assigned PAS were provided 1,911 ± 162 g m−2 at the beginning of grazing for 69 days, had final BW 443 ± 35 kg, ADG of 1.01 ± 0.22. Forage nutrient analyses are reported in Table 1, showing that individual crops are similar in ADF and TDN, but vary in crude protein content. Performance of ICL cattle exceeded that of PAS while on corn and soybean but decreased ICL performance while grazing cover crop was likely due to extreme cold weather at the time of grazing. Nutrient values reported here can be used to plan and predict cattle growth while grazing crop residues instead of pastures.

Published
2022
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46. Analysis of Renewable Jet from Oilseed Feedstocks Replacing Fallow in the U.S. Northern Great Plains

Author

David W. Archer, Kristin C. Lewis, David R. Shonnard, Matthew N. Pearlson, Rui Shi, Suchada Ukaew, and Krishna Pokharel

Subjects
Jet (fluid), Renewable Energy, Sustainability and the Environment, business.industry, General Chemical Engineering, Fossil fuel, 02 engineering and technology, General Chemistry, Soil carbon, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Renewable energy, Bioenergy, Environmental protection, Biofuel, Soil water, Environmental Chemistry, Environmental science, 0210 nano-technology, business, Life-cycle assessment
Abstract

Potential land-use change impact has been of concern for producing biomass-derived fuels. To avoid displacing crop production, this study considered north central and western U.S. nonirrigated whea...

Published
2019
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47. Facilitating Crop–Livestock Reintegration in the Northern Great Plains

Author

Krishna Pokharel, Liming Lai, Heidi L. Sieverding, Nleya Thandiwe, Jeffrey B. Jacquet, Daren D. Redfearn, James J. Stone, Shannon L. Osborne, Derek R. Faust, Sandeep Kumar, Douglas Landblom, Brian J. Wienhold, Vance N. Owens, Mark A. Liebig, Sunish K. Sehgal, Songul Senturklu, Elaine E. Grings, Marty R. Schmer, David A.N. Ussiri, David W. Archer, Scott W. Smalley, Peter Sexton, Virginia L. Jin, Shaukat Ali, and Robert D. Mitchell

Subjects
Fodder crops, Rural economy, Agroforestry, business.industry, Crop yield, Crop livestock, Agronomy, Grazing, Crop quality, Environmental science, Livestock, Economic impact analysis, business, Agronomy and Crop Science
Published
2019
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48. Agronomic Performance of Brassicaceae Oilseeds in Multiple Environments Across the Western USA

Author

Jack Brown, David W. Archer, Terry A. Isbell, James R. Kiniry, Debra E. Palmquist, Jerry L. Hatfield, J. B. Davis, Russ W. Gesch, Brett L. Allen, Dan S. Long, Emily Oblath, Merle F. Vigil, and Jalal D. Jabro

Subjects
0106 biological sciences, biology, Renewable Energy, Sustainability and the Environment, 020209 energy, Field experiment, Camelina sativa, Sinapis, Brassica, Growing season, 02 engineering and technology, biology.organism_classification, 01 natural sciences, Camelina, Crop, Agronomy, 010608 biotechnology, 0202 electrical engineering, electronic engineering, information engineering, Cultivar, Agronomy and Crop Science, Energy (miscellaneous)
Abstract

Brassicaceae oilseed crops can provide rotation benefits to dryland wheat (Triticum aestivum L.) and supply feedstock for biofuel production. However, growers face decisions about what oilseed crop is best suited for an environment. The objective of this study was to determine how varying production environments affect the agronomic performance of modern cultivars of six Brassicaceae crop species and identify ideal genotypes for seven growing environments spanning four ecoregions. A field experiment was replicated in Colorado, Idaho, Iowa, Minnesota, Montana, North Dakota, and Oregon, USA, between 2013 and 2016 to measure seed and oil yields of seed for four cultivars of Brassica napus, two of B. carinata, two of B. juncea, two of Sinapis alba, one of B. rapa, and one of Camelina sativa. Also, δ13C signature of seed was used as an indicator of water limitation. Generally, across all genotypes, seed and oil yields increased with increased growing season precipitation. Modern commercial cultivars of B. napus and B. juncea had the highest seed oil contents and generally produced the greatest oil yields across most environments, although they were not always the highest seed yielders. For instance, B. carinata over six site years in North Dakota and Minnesota yielded greater than B. napus producing as much as 2471 kg ha−1 in Minnesota. Camelina produced competitive seed yields in some of the drier environments and its δ13C signature indicated that it had the greatest drought resistance. However, seed oil content of some of these high yielding genotypes may need improvement before they are viable as biofuel feedstock.

Published
2019
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49. Impacts of Intensified Cropping Systems on Soil Water Use by Spring Wheat

Author

Mark A. Liebig, David W. Archer, Jonathan J. Halvorson, Kathleen M. Yeater, and Donald L. Tanaka

Subjects
Soil Science, Sowing, 04 agricultural and veterinary sciences, 010501 environmental sciences, Crop rotation, 01 natural sciences, Crop, Tillage, Agronomy, Soil water, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Dryland farming, Water-use efficiency, Water use, 0105 earth and related environmental sciences
Abstract

In semiarid dryland farming regions, No-till and intensified crop rotations may improve water use. Our objective was to determine water use efficiency (WUE) and precipitation use efficiency (PUE) for spring wheat (Triticum aestivum L.; SW) grown in crop sequences representing different levels of intensification, under minimum (Min-till) or No-till. Root zone (0–122 cm) water at planting (SWP) was 2.76 cm higher for two- and three-phase sequences under Min-till than continuous spring wheat (CSW), and sequences with fallow averaged 2.65 cm higher than those without. Conversely, SWP was unaffected by sequence under No-till, with less effect of fallow. Root zone water at harvest was unaffected by the number of crop phases or fallow under Min-till. However, values for CSW exceeded the two- or three-phase sequences by 1.57 and 2.53 cm under No-till, and sequences without fallow averaged 1.52 cm more than those with fallow. The highest WUE (8.4 kg grain ha⁻¹ mm⁻¹ water) was observed when SW was grown in three-phase sequences compared with 7.7 kg grain ha⁻¹ mm⁻¹ water, for CSW and SW-fallow. Spring wheat under Min-till had higher WUE in sequences with fallow, but no effects of fallow occurred with No-till. The lowest PUE (near 3 kg grain ha⁻¹ mm⁻¹ precipitation) and no effects of tillage were found in sequences with fallow. However, SW in continuously cropped sequences had PUE between 5.5 and 6.4 kg grain ha⁻¹ mm⁻¹ precipitation and was higher under No-till. Both WUE and PUE are affected by intensification but may also be influenced by patterns of weather.

Published
2019
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50. Examining the financial performance of agricultural cooperatives in the USA

Author

Madhav Regmi, David W. Archer, Krishna P. Pokharel, and Allen M. Featherstone

Subjects
Rate of return, Return on assets, Leverage (finance), 050204 development studies, media_common.quotation_subject, 05 social sciences, Economics, Econometrics and Finance (miscellaneous), Equity (finance), Financial system, Agricultural and Biological Sciences (miscellaneous), Interest rate, Return on equity, 0502 economics and business, Profitability index, 050202 agricultural economics & policy, Business, Real interest rate, media_common
Abstract

Purpose The purpose of this paper is to identify financial stress and the causes of financial stress for agricultural cooperatives and provide management recommendations to stakeholders including cooperatives’ managers, boards of directors and lenders. Design/methodology/approach This research used the geometric mean of the real rate of return on equity to identify financially stressed agricultural cooperatives. The real rate of return on equity allows the allocation of total financial stress among the return on assets, leverage and interest rate issues. Findings This study found that financially non-stressed agricultural cooperatives had a higher rate of return on equity and rate of return on assets, but lower leverage ratios and interest rates than stressed agricultural cooperatives. Further, non-stressed cooperatives had higher total assets and sales compared to stressed cooperatives. This suggests that smaller cooperatives are more likely to face financial stress than larger cooperatives. The decomposition of the financial problem showed that a substantial percentage of financial stress was correlated with a low return on assets or profitability. A smaller percentage of financial stress was due to financing decisions. Originality/value This study provides value by measuring the impact of profitability, leverage and interest rate on the financial performance of agricultural cooperatives. Results showed that a substantial proportion of financial stress was associated with a low return on assets. This indicates that profitability is a problem for agricultural cooperatives. This study also examines profitability during a period of volatile returns in production agriculture.

Published
2019
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