14 results on '"Marsh, Brian H."'
Search Results
2. Surface and subsurface soil acidity: soybean root response to sulfate-bearing spent lime
- Author
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Marsh, Brian H. and Grove, J.H.
- Subjects
Soil acidity -- Research ,Soybean -- Physiological aspects ,Lime -- Environmental aspects ,Earth sciences - Abstract
The effect of sulfate bearing, oil refinery derived, spent lime on surface and subsurface soil chemical properties are discussed. The effects of the material was tested on soybean yield and root growth. Soil acidity was determined potentiometrically and was measured immediately. Correlations between soil amendments and soybean yield and root growth were found to be positive. more...
- Published
- 1992
Catalog
3. An Investigation of Current Potato Nitrogen Fertility Programs' Contribution to Ground Water Contamination
- Author
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Marsh, Brian H.
- Subjects
leaching potential ,irrigation management ,nitrogen fertilization ,Potato - Abstract
Nitrogen fertility is an important component for optimum potato yield and quality. Best management practices are necessary in regards to N applications to achieve these goals without applying excess N with may contribute to ground water contamination. Eight potato fields in the Southern San Joaquin Valley were sampled for nitrogen inputs and uptake, tuber and vine dry matter and residual soil nitrate-N. The fields had substantial soil nitrate-N prior to the potato crop. Nitrogen fertilizer was applied prior to planting and in irrigation water as needed based on in-season petiole sampling in accordance with published recommendations. Average total nitrogen uptake was 237 kg ha-1 on 63.5 Mg ha-1 tuber yield and nitrogen use efficiency was very good at 81 percent. Sixty-nine percent of the plant nitrogen was removed in tubers. Soil nitrate-N increased 14 percent from pre-plant to post-harvest averaged across all fields and was generally situated in the upper soil profile. Irrigation timing and amount applied did not move water into the lower profile except for a single location where nitrate also moved into the lower soil profile. Pre-plant soil analysis is important information to be used. Rotation crops having deeper rooting growth would be able to utilize nitrogen that remained in the soil profile., {"references":["Crozier, C., N. Creamer, M. Cubeta. 2004. Soil fertility management for Irish potato production in Eastern North Carolina. NC State Univ. Coop. Ext. AGW-439-49","Cohen, Y., Y. Zusman, V. Alchanatis, Z. Bar, D. Bonfil, A. Karnieli, A Zilberman, A. Moulin, V. Ostrovsky, A. Levi, R. Brikman, and M. Shenker. 2008. Nitrogen evaluation in potato plants based on spectral data and on simulated bands of the VENµS satellite. Downloaded on 15 Dec. 2015 from http://www.agri.gov.il/download/files/Part%201-%20Single%20leaves%20Venus_1.pdf.","Vos. J. and M. Bom. 1993. Hand-held chlorophyll meter: a promising tool to assess the nitrogen status of potato foliage. Potato Research 26:301-308.","Young, M., D. Mackerron and H. Davies. 1997. Calibration of near infrared reflectance spectroscopy to estimate nitrogen concentration in potato tissues. Potato Research 40:215-220.","Hopkins, B., J. Stark, D. Westermann and J. Ellsworth. Nutrient Management: Potato. Downloaded on 15 Dec. 2015 from http://ucanr.org/sites/nm/files/76642.pdf","Alva, A., T. Hodges, R. Boydston and H. Collins. 2002. Dry matter accumulations and partitioning in two potato cultivars. Journal of Plant Nutrition 25:1621-1630.","Biemond, H. and J. Vos. 1992. Effects of nitrogen on the development and growth of the potato plant. 2. The partitioning of dry matter, nitrogen and nitrate. Annals of Botany 70:37-45.","Waddell, J., S. Gupta, J. Moncrief, C. Rosen and D. Steele. 1999. Irrigation and nitrogen management effects on potato yield, tuber quality, and nitrogen uptake. Agronomy Journal 91:991-997.","Kavvadias, V., C. Paschalidis, G. Akrivos and D. Petropoulos. 2012. Nitrogen and potassium fertilization responses of potato (Solanum tuberosum) cs. Spunta. Communications In Soil Science and Plant Analysis 43:176-189.\n[10]\tSaffigna, P., D. Keeney and C. Tanner. 1977. Nitrogen, chloride, and water balance with irrigated Russet Burbank potatoes in a sandy soil. Agronomy J. 69:251-257.\n[11]\tFontes, P., H. Braun, C. Busato and P. Cecon. 2010. Economic optimum nitrogen fertilization rates and nitrogen fertilization rate effects on tuber characteristics of potato cultivars. Potato Research 53:167-179.\n[12]\tArshadi, J. and M. Asgharipour. 2011. Effect of nitrogen top-dress management using chlorophyll meter on yield, quality and correlation between some agronomic traits in potato. Advances in Environmental Biology. 5:711-718.\n[13]\tWesterman, D. 2005. Nutritional requirements of potato. American Journal of Potato Research 82:301-307.\n[14]\tEghball, B. 2000. Nitrogen mineralization from field-applied beef cattle feedlot manure or compost. Soil Sci. Soc. of Amer. J. 64:2024-2030.\n[15]\tWen, G., T. Bates and R. Voroney. 1995. Evaluation of nitrogen availability in irradiated sewage sludge, sludge compost and manure compost. J. Environ. Qual. 24:527-534.\n[16]\tMunoz, G., K. Kelling, K. Rylant and J. Zhu. 2008. Field evaluation of nitrogen availability from fresh and composted manure. J. Environ. Qual. 37:944-955.\n[17]\tEghball, B. and J. Power. 1999. Composted and noncomposted manure application to conventional and no-tillage systems: Corn yield and nitrogen uptake. Agron. J. 91:819-825.\n[18]\tGale, E., D. Sullivan, C. Cogger, A. Bary, D. Hemphill and E. Myhre. 2006. Estimating plant-available nitrogen release from manures, composts and specialty products. J. Environ. Qual. 35:2321-2332.\n[19]\tRosen, C. and P. Beirman. 2005. Using manure and compost as nutrient sources for vegetable crops. U. Minn. Ext. Service. pp. 1-12.\n[20]\tGil, M., M. Carballo and L. Calvo. 2011. Modelling N mineralization from bovine manure and sewage sludge composts. Bioresource Technology 102:863-871.\n[21]\tPettygrove, G. A. Heinrich and D. Crohn. 2009. Manure nitrogen mineralization. UC Manure Technical Bulletin Series. pp 1-5. \n[22]\tZebarth, B., G. Tai, R. Tarn, H. deJong and P. Milburn. 2004. Nitrogen use efficiency characteristics of commercial potato cultivars. Can. J. Plant Sci. 84:589-598.\n[23]\tCambouris, A., B. Zebarth, M. Nolin and M. Lverdiere. 2008. Apparent fertilizer nitrogen recovery and residual soil nitrate under continuous potato cropping: Effect of N fertilization rate and timing. Can. J. Plant Sci. 88:813-825.\n[24]\tJoern, B. and M. Vitosh. 1995. Influence of applied nitrogen on potato. Part II: Recovery and partitioning of applied nitrogen. American Potato Journal 82: 73-84.\n[25]\tSaffigna, P., D. Keeney and C. Tanner. 1977. Nitrogen, chloride, and water balance with irrigated Russet Burbank potatoes in a sandy soil. Agron. J. 69:251-257.\n[26]\tHong, L., L. Parent, A. Karam and C. Tremblay. 2003. Efficiency of soil and fertilizer nitrogen of a sod-potato system in the humid, acid and cool environment. Plant and Soil 251:23-36.\n[27]\tIwama, K. 2008. Physiology of the potato: New insights into root system and repercussions for crop management. Potato Research 51:333-353.\n[28]\tAhmadi, S., P. Finn, M. Andersen, A. Sepaskhah and C. Jensen. 2011. Effects of irrigation strategies and soil on field grown potatoes: Root distribution. Agricultural Water Management. 98:1280-1290.\n[29]\tAnon. 1983. Sprinkle Irrigation. Section 15, Natural Resources Conservation Service National Engineering Handbook. Chapter 11 pp 17.\n[30]\tThorup-Kirstensen, K., M. Cortasa and R. Loges. 2009. Winter wheat roots grow twice as deep as spring wheat roots, is this important for N uptake and N leaching losses? Plant and Soil 322:101-104. \n[31]\tKing, B. and J. Stark. 1997. Potato Irrigation. University of Idaho Cooperative Extension Bulletin 789. pp 1-15."]} more...
- Published
- 2016
- Full Text
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4. Field Application of Reduced Crude Conversion Spent Lime
- Author
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Marsh, Brian H. and Grove, John H.
- Subjects
corn ,Soil acidity ,food and beverages ,soybean ,liming materials ,complex mixtures - Abstract
Gypsum is being applied to ameliorate subsoil acidity and to overcome the problem of very slow lime movement from surface lime applications. Reduced Crude Conversion Spent Lime (RCCSL) containing anhydrite was evaluated for use as a liming material with specific consideration given to the movement of sulfate into the acid subsoil. Agricultural lime and RCCSL were applied at 0, 0.5, 1.0, and 1.5 times the lime requirement of 6.72 Mg ha-1 to an acid Trappist silt loam (TypicHapuldult). Corn [Zea mays (L.)]was grown following lime material application and soybean [Glycine max (L.) Merr.]was grown in the second year.Soil pH increased rapidly with the addition of the RCCSL material. Over time there was no difference in soil pH between the materials but there was with increasing rate. None of the observed changes in plant nutrient concentration had an impact on yield. Grain yield was higher for the RCCSL amended treatments in the first year but not in the second. There was a significant increase in soybean grain yield from the full lime requirement treatments over no lime., {"references":["Oats, K. and A. Caldwell. 1985. Use of by-product gypsum to alleviate soil acidity. Soil Sci. Soc. Am. J. 49:915-918.","Alva, A., M. Sumner, and A. Noble. 1988. Alleviation of aluminum toxicity by phosphogypsum. Commun. Soil Sci. Plant Anal. 19:385-403.","Shainberg, I., M. Sumner, W. Miller, M Farina, M. Pavan, and M. Fey. 1989. Use of gypsum on soils: A review. Pp. 1-111. In B. Stewart (ed.) Advances in soil science. Vol. 9. Springer-Verlag. New York.","Hammel, J., M. Sumner, and H. Shadhandeh. 1985. Effect of physical and chemical profile modification on soybean and corn production. Soil Sci. Soc. Am. J. 49:1508-1511.","Pavan, M., F. Bingham, and P. Pratt. 1984. Redistribution of exchangeable calcium, magnesium, and aluminum following lime or gypsum applications to a BrazilianOxisol. Soil Sci. Soc. Am. J. 48:33-38.","Rayor, A. 1981. Effect of calcium concentration on growth and ion uptake of soybean plants in solution culture. Z. Pflanzenphysiol. 105:59-64.","Noble, A. M. Fey, and M. Sumner. 1988. Calcium-aluminum balance and the growth of soybean roots in nutrient solutions. Soil Sci. Soc. Am. J. 52:1651-1656.","Souza, D. and K. Ritchy. 1986. Usodoeso gesso no solo de cerrado. pp 119-144. In An. Sem. UsoFosgogessoAgriculturea. EMBRAPA, Brazilia, D. F., Brazil.","Shoemaker, H., E. McLean, and P. Pratt. 1961. Buffer methods for determining lime requirement of soil with appreciable amounts of extractable aluminum. Soil Sci. Soc. An. Proc. 25-274-277.\n[10]\tMarsh, B., and J. Grove. 1992. Plant and soil chemical compositions as affected by a highly reactive alternative lime source containing sulfate. Soil Sci. Soc. Am. J. 56:1831-1836.\n[11]\tAnonymous. 1987. Lime and fertilizer recommendations, 1987-1988. Kentucky Coop. Ext. Serv. Bull. AGR-1.\n[12]\tThomas, G. 1982. Exchangeable cations. P. 159-165. In A. Page (ed.) Methods of soil analysis. Part 2. American Society of Agronomy, Madison, WI.\n[13]\tChapman, H. 1965. Diagnostic criteria for plants and soils. University of California, Riverside.\n[14]\tMarsh, B. and J. Grove. 1992. Surface and subsurface soil acidity: Soybean root response to sulfate bearing spent lime. Soil Sci. Soc. Am. J. 56:1837-1842. \n[15]\tSilverbush, M. and S. Barber. 1985. Root growth, nutrient uptake and yield of soybean cultivars grown in the field. Commun. Soil Sci. Plant Anal. 16:119-127."]} more...
- Published
- 2014
- Full Text
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5. A Comparison of Fuel Usage and Harvest Capacity in Self-Propelled Forage Harvesters
- Author
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Marsh, Brian H.
- Subjects
Corn silage ,fuel use ,forage harvester ,length of cut - Abstract
Self-propelled forage harvesters in the 850 horsepower range were tested over three years for fuel consumption, throughput and quality of chop for corn silage. Cut length had a significant effect on fuel consumption, throughput and some aspects of chop quality. Measure cut length was often different than theoretical length of cut. Where cut length was equivalent fuel consumption and throughput were equivalent across brands. Shortening cut length from 17 to 11mm increases fuel consumption 53 percent measured as Mg of silage harvested per gallon of fuel used and a 42 percent decrease in capacity as tons of fresh material per hour run time., {"references":["","Kononoff, P., A. Heinrichs, and H. Kehman. 2003. The Effect of Corn\nSilage Particle Size on Eating Behavior, Chewing Activities, and Rumen\nFermentation in Lactating Dairy Cows. J. Dairy Sci. 86:3343-3353.","Bal, M., R. Shaver, A. Jirovec, K. Shinners, and J. Coors. 2000. Crop\nprocessing and chop length of corn silage: Effects on intake, digestion,\nand milk production by dairy cows. J. Dariy Sci. 83:1264-1273.","Johnson, L, J. Harrison, C. Hunt, K. Shinners, C. Doggett, and D.\nSapienza. 1999. Nutritive value of corn silage as affected by maturity\nand mechanical processing: A contemporary review. J. Dairy Sci.\n82:2813-2825.","Frost, J. and R. Binnie. 2004. A comparison of two systems for\nharvesting herbage for silage. ARINI BT26 6DR.","Lancas, k., S. Upadhyaya, M. Sisme, and S. Shafii. 1996. Overinflated\ntractor tires waste fuel, reduce productivity. CA Agriculture. 50:28-31.","Heinrichs, Jud. 1996. Evaluating particle size of forages and TMRs\nusing the Penn State Particle Size Separator. DAS 96-20.","Mertens, D. and G. Ferreira. 2001. Partitioning in vitro digestibility of\ncorn silages of different particle sizes. Abstract #826. ADSA Meetings,\nIndianapolis, IN.","Lammers, B., D. Buckmaster and A. Heinrichs. 1996. A Simple Method\nfor the Analysis of Particle Sizes of Forage and Total Mixed\nRations.Journal of Dairy Science 79:922-928."]} more...
- Published
- 2013
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6. Forage Yield and Soilborne Mosaic Virus Resistance of Several Varieties of Rye, Triticale and Wheat (1997)
- Author
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Staggenborg, Scott A., primary, Bowden, Robert L., additional, Marsh, Brian H., additional, and Martin, Victor L., additional
- Published
- 1997
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7. Soil pH Effect on Imazaquin Persistence in Soil
- Author
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Marsh, Brian H., primary and Lloyd, Randy W., additional
- Published
- 1996
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8. Soybean Response to Row Spacing and Seeding Rates in Northeast Kansas (1996)
- Author
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Staggenborg, Scott A., primary, Devlin, Daniel L., additional, Fjell, Dale L., additional, Shroyer, James P., additional, Gordon, W. B., additional, Marsh, Brian H., additional, and Maddux, Larry D., additional more...
- Published
- 1996
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9. Sulfur Fertilization of Smooth Bromegrass in Kansas
- Author
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Lamond, Ray E., primary, Whitney, David A., additional, and Marsh, Brian H., additional
- Published
- 1995
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10. UPDATE ON FUSARIUM RACE 4 VARIETAL EVALUATIONS IN CALIFORNIA.
- Author
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Hutmacher, Robert B., Ulloa, Mauricio, Wright, Steve D., Keeley, Mark, Davis, R. Michael, Munk, Daniel S., Banuelos, Gerardo, Marsh, Brian H., Percy, Richard G., Smith, Les, and Biggs, Monica
- Abstract
In recent years, differences have been noted in field situations with the fungal pathogen Fusarium oxysporum f. sp. vas infectum in Acala and Pima cotton in the San Joaquin Valley of California. Typically, earlier-recognized races of this organism found in California cotton only caused significant crop foliar damage and yield impacts under conditions where it was found in combination with susceptible varieties of cotton and at least moderate populations of root knot nematode. A race 4 isolate of Fusarium oxysporum f. sp. vasinfectum (FOV) has been identified in Pima and Acala cotton fields in the San Joaquin Valley in recent years, and research to date has shown that this race can infect susceptible varieties, cause damage, and may reproduce inoculum under soil conditions that do not support significant root knot nematode populations. Research efforts to date have focused on (1) development of genetic tools to more clearly identify current Fusarium races found in California cotton samples; (2) evaluation of plant samples under field conditions to verify presence or absence of the pathogen, and (3) initiation of variety screening programs under both greenhouse conditions with inoculated soil, and in field sites where this FOV race 4 pathogen has been confirmed. Field screening trials to evaluate relative FOV resistance in commercial and experimental cotton lines have shown that susceptible Pima varieties are more severely affected in terms of foliar damage, stem vascular staining and plant stunting or mortality than tested Acala and non-Acala Upland varieties. The most tolerant (lowest seedling mortality, least stunted) varieties in field screenings have also been Pima cottons. Field and greenhouse trials have both repeatedly confirmed that tested Acala and non-Acala Upland varieties can also be infected, although generally with reduced plant mortality and stunting. Significant varietal differences in susceptibility to the race 4 FOV pathogen have been seen in both Pima and Acala cotton entries. [ABSTRACT FROM AUTHOR] more...
- Published
- 2008
11. PLANT MAPPING SOFTWARE FOR CALIFORNIA COTTON.
- Author
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Marsh, Brian H. and Hutmacher, Robert B.
- Abstract
In-season cotton plant mapping is an important component of gathered information necessary for appropriate decisions about growth regulator and pest control applications. It can also be a very time consuming process. Two methods currently in use are, manually filling out cards and averaging the data or using an HP Palmtop PC to enter the data. The Palmtop is not compatible with current PC technology and spreadsheet software. The output calculations were also developed for Acala cotton varieties and only use 1
st position boll information. Appropriate decision making information for Pima cotton should also include 2nd position and/or 3rd position bolls. Cotton plant mapping software for a PDA has been developed that is compatible with today's computer technology and utilizes the CottonPro calculations for data interpretation. The other innovation is that the program is graphically based utilizing touch screen technology. Rather than input various numbers, as present programs call for, a cotton plant diagram is displayed and the user points with the stylus to each boll position where a boll is present and the uppermost white flower. This program improves the speed and reliability for plant mapping data and is a great aid in making agronomic input decisions for cotton. [ABSTRACT FROM AUTHOR] more...- Published
- 2005
12. FUSARIUM RACE 4: COMMERCIAL CULTIVAR SCREENING FOR RESISTANCE.
- Author
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Hutmacher, Robert B., Ulloa, Mauricio, Wright, Steve, Davis, R. Michael, Bennett, Rebecca, Marsh, Brian H., Keeley, Mark P., Goodell, Peter B., and Banuelos, Gerardo
- Abstract
An abstract of the article "Fusarium Race 4: Commercial Cultivar Screening for Resistance," by Robert B. Hutmacher, Mauricio Ulloa, Steve Wright, R. Michael Davis, Rebecca Bennett, Brian H. Marsh, Mark P. Keeley, Peter B. Goodell and Gerardo Banuelos is presented. more...
- Published
- 2007
13. Surface and subsurface soil acidity: soybean root response to sulfate-bearing spent lime
- Author
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Grove, J. H. and Marsh, Brian H.
- Subjects
SOIL acidity - Published
- 1992
14. Plant and soil composition as affected by an alternative lime sourcecontaining sulfate
- Author
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Grove, J. H. and Marsh, Brian H.
- Subjects
PLANT nutrition ,SOIL composition ,SULFATES - Published
- 1992
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