Global ETD Search

231	Cotton Planting Date and Planting Rate Kittock, D. L., Taylor, B. B., Cluff, R., Thatcher, M. 02 1900 (has links) DPL 41 and Pima S-5 cotton were planted at low, medium, and high planting rates on April 12, April 27, and May 10 on the Safford Experimental Farm in 1983. Heavy rains in late September and early October reduced lint yields. Pima S-5 produced 66% as much lint as DPL 41. Both varieties had the highest lint yield when planted on April 27. The highest planting rate produced the highest yield for DPL 41, while the medium planting rate produced the most lint for Pima S-5 on April 27. Agriculture -- Arizona Cotton -- Arizona
232	Cotton Lint Quality and Relative Value at Different Harvest Dates Kittock, D. L., Daugherty, L. S., Selley, R. A. 02 1900 (has links) No description available. Agriculture -- Arizona Cotton -- Arizona
233	The Relationship Between Heat Units and Yield in Arizona Cotton Counties Taylor, B. B., Malcuit, J. E., Hitz, T. H. 02 1900 (has links) No description available. Agriculture -- Arizona Cotton -- Arizona
234	Variety-Date of Planting-Row Width Test Fisher, W. D., Pegelow, E. J. 03 1900 (has links) The 1985 and 1986 Cotton Reports have the same publication and P-Series numbers. Agriculture -- Arizona Cotton -- Arizona Cotton -- Planting rates and dates
235	Yield of 12 Upland Cotton Varieties Planted at 3 Dates at Maricopa in 1985 Kittock, David L., Hofmann, Wallace C., Else, Peter T., Malcuit, Joel, Michaud, Carl 03 1900 (has links) The 1985 and 1986 Cotton Reports have the same publication and P-Series numbers. / The earliest planting date (28 March) gave the highest average lint yield. The average decrease in lint yield with delayed planting after 28 March was 6 to 7 pounds of lint/acre/day. Varieties did not differ greatly in lint yield. The early (short season) varieties Centennial and Deltapine 30 were consistently lowest in lint yield. Deltapine 775, Deltapine 90Y, and Stoneville 112 were among the highest producers at all three planting dates. Agriculture -- Arizona Cotton -- Arizona Cotton -- Planting rates and dates
236	A Summary on Skip-Row Planted Cotton in Arizona Briggs, R. E., Massey, G. D. 02 1900 (has links) This item was digitized as part of the Million Books Project led by Carnegie Mellon University and supported by grants from the National Science Foundation (NSF). Cornell University coordinated the participation of land-grant and agricultural libraries in providing historical agricultural information for the digitization project; the University of Arizona Libraries, the College of Agriculture and Life Sciences, and the Office of Arid Lands Studies collaborated in the selection and provision of material for the digitization project. Agriculture -- Arizona Cotton -- Arizona Cotton -- Planting Cotton -- Skip-row patterns
237	Skip-Row Cotton Favors Acala Varieties Blackledge, G. E. 02 1900 (has links) This item was digitized as part of the Million Books Project led by Carnegie Mellon University and supported by grants from the National Science Foundation (NSF). Cornell University coordinated the participation of land-grant and agricultural libraries in providing historical agricultural information for the digitization project; the University of Arizona Libraries, the College of Agriculture and Life Sciences, and the Office of Arid Lands Studies collaborated in the selection and provision of material for the digitization project. Agriculture -- Arizona Cotton -- Arizona Cotton -- Planting Cotton -- Skip-row patterns
238	IRRIGATION TIMING AND PLANTING DATE EFFECT ON GUAR SEED YIELDS. Husman, Stephen Herbert, 1954- January 1985 (has links) No description available. Guar -- Planting time. Guar -- Irrigation. Guar gum industry -- Arizona.
239	Ecophysiology of dryland corn and grain sorghum as affected by alternative planting geometries and seeding rates Haag, Lucas A. January 1900 (has links) Doctor of Philosophy / Department of Agronomy / Scott A. Staggenborg and Alan J. Schlegel / Previous work in the High Plains with alternative planting geometries of corn and grain sorghum has shown potential benefits in dryland production. Studies conducted in 2009-2011 at Tribune, KS evaluated five planting geometries in corn and grain sorghum: conventional, clump, cluster, plant-one skip-one (P1S1), and plant-two skip-two (P2S2). Geometries were evaluated at three plant densities in corn: 3.0, 4.0, and 5.1 plants m[superscript]-2. Every measured corn production characteristic was affected by planting geometry, seeding rate, or an interaction in at least one of the years. Corn planted in a P2S2 configuration produced the least above-ground biomass, kernels plant[superscript]-1, kernels ear row[superscript]-1, and the highest kernel weight. Conventionally planted corn minimized harvest index and maximized stover production. Alternative geometries produced similar harvest indices. Grain yield response to seeding rate varied by geometry and year. Responsiveness and contribution of yield components were affected by geometry. Yield and yield components, other than ears plant[superscript]-1, were the least responsive to seeding rate in a cluster geometry. Clump planting consistently maximized kernels plant[superscript]-1. Prolificacy was observed in the cluster treatment and barrenness in the skip-row treatments. Light interception at silking was highest for clump and conventional geometries and lowest for the skip-row treatments. Corn in a P2S2 configuration did not fully extract available soil water. Conventionally planted corn had the lowest levels of soil water at tassel-silk indicating early-season use which potentially affected kernel set. In the lowest yielding year, grain water use efficiency was highest for clump and P2S2. Across-years, grain yields were lower for corn planted in a P2S2 geometry. Across-years corn yields were maximized when planted in clump at low or intermediate plant density, conventional and P1S1 at low plant density, P1S1 at high density, or cluster at any density. Planting grain sorghum in a P1S1 or P2S2 configuration reduced total biomass, grain yield, water use efficiency for grain production (WUEg), and water use efficiency for biomass production (WUEb) compared to conventional, clump, or cluster geometries at the yield levels observed in this study. Total water use was unaffected by planting geometry although cumulative water use at flower / grain fill was higher for conventional, clump, and cluster than for skip-row configurations. Sorghum planted in a conventional geometry was always in the highest grouping of grain yields. Grain yields from sorghum in either a cluster or clump geometry were each in the top yield grouping two of three years. When evaluated across-years, sorghum planted in a clump, cluster, or conventional geometry resulted in similar levels of above-ground biomass, grain yield, WUEg, and WUEb. Clump or cluster planting appear to have substantially less downside in a high yielding year than skip-row configurations. A comparison of corn and sorghum reinforced the findings of others that the relative profitability of the crops is largely dependent on the environment for any given crop year. Relative differences in grain yield, WUEg, WUEb, and net returns varied by year. Net returns over the three year study were maximized by conventional, cluster, and clump planted sorghum as well as clump planted corn. Dryland corn grain Sorghum planting geometry Agronomy (0285)
240	Effects of planting practices and nitrogen management on grain sorghum production Maiga, Alassane January 1900 (has links) Doctor of Philosophy / Department of Agronomy / P.V. Vara Prasad / Sorghum [Sorghum bicolor (L.) Moench] is a relatively drought- and heat-tolerant cereal crop. Global demand and consumption of agricultural crops for food, feed, and fuel is increasing at a rapid pace. To satisfy the growing worldwide demand for grain, production practices must be well optimized and managed. The objectives of the present study were: to optimize sorghum production by determining the best management practices (planting date, row spacing, seeding rate, hybrid maturity) for growth and yield, to evaluate the agronomic responsiveness of grain sorghum genotypes to nitrogen (N) fertilizer and to develop a partial financial budget to N fertilizer application based on best management practices. In order to meet these objectives, field experiments were conducted in 2009, 2010 and 2011 at Manhattan, Belleville, Ottawa, Hutchinson, Hays, at KSU Experiment Stations and Salina, and Randolph at Private Farms. Results indicated that early planting date (late May) and narrow row spacing (25 cm) providing the most equidistant spacing, produced better plant growth, light interception, yield components (number of grains per panicle, 300-grain weight), and biological yield. Results indicated that with increasing N rate, there was a proportional increase in chlorophyll SPAD meter reading, leaf color scores and number of green leaves. There was a significant difference among hybrids for N uptake, NUE and grain yield. However, there was no effect of N and no interaction between N and hybrid on grain yield. Over all, the genotypes with high NUE also had higher grain yield. Economic analysis using partial budget indicated that all N levels had positive gross benefit greater than control at all locations. However, the response varied across locations. Our research has shown that sorghum responds to changing management practices and opportunities exist to increase grain yield by optimizing planting date, seeding rate, row spacing, N application and selection of genotypes. Planting practices, nitrogen management Nitrogen management Agronomy (0285)

Search results