Global ETD Search

11	Mechanisms of biological control of the damping-off fungus, Pythium ultimum, by binucleate Rhizoctonia / Siwek, K. January 1996 (has links) (PDF) Thesis (Ph. D.)--University of Adelaide, Dept. of Crop Protection, 1997. / Includes bibliographical references (leaves 162-198). Pythium ultimum Rhizoctonia. Peppers
12	Studies on the pathogenicity of seven species of pythium on red clover seedlings Halpin, James Edwin, January 1951 (has links) Thesis (M.S.)--University of Wisconsin-Madison. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references. Red clover Pythium.
13	The epidemiology and control of Pythium root dieback of muck-grown carrots Wisbey, Bruce Douglas January 1974 (has links) Olpidium was correlated with the frequency of precipitation greater than one half inch but was not correlated with root temperature, CO₂ or 0₂ concentration, saturated hydraulic conductivity, the height of the carrot beds, marketable yield or cull rate. Olpidium isolates with and without TNV did not produce lesions on carrot roots under greenhouse conditions. TNV was detected in both brown and white roots but only from problem fields. Carrot rootlets rub-inoculated with TNV failed to produce necrotic symptoms. Olpidium and TNV were found in onion, lettuce, celery and some weed species common to PRD problem fields. However, no root tip browning was observed in any of these hosts. Fast growing Pythium species were recovered equally frequently in brown and symptomless rootlets and from problem and non-problem soils. Most weeds, celery, onion and lettuce also had a high incidence of fast growing Pythium. The highly pathogenic, slow growing Pythium sulcatum was recovered only from problem soil. The recovery rate from symptomless roots was very low compared to brown roots. P. sulcatum was not isolated from celery or any of the weed species common in problem soil. Lettuce and onion were found to support low levels of infection. Evidence suggests that P. sulcatum is a primary incitant. PRD losses can be kept to a minimum and marketable yields increased by using tolerant varieties, such as HiPak; raised beds, if there is a readily available supply of irrigation water; precision seeding at 1 1/4 inches; and a crop rotation of onions preceding carrots. Matric potential was controlled in small containers separated from osmotic solutions of polyethylene glycol (PEG) 6000 by Pellicon ultrafiltration membranes (nominal molecular weight cutoff:500, Millipore Corp.). Matric potentials could be maintained for periods of 3-5 weeks before microbial breakdown of membranes occurred. Flow rate for the membranes was 1.0 cm³ cm⁻² day⁻¹ for a water potential difference across the membrane of 0.2 bar. Water potential measured with tensiometers or thermocouple psychrometers in a cylindrical container (4.3 cm diam. x 10 cm) with a membrane acrosss the bottom, remained relatively constant under conditions of soil surface evaporation but decreased rapidly when young plants were grown in the system. Soil cells (5.5 x 2.0 x 10 cm with one 43 mm diameter membrane in each side), containing two young carrots, and emersed in a -0.2 and -2.0 bar PEG solution had an average matric potential of -0.4 and -2.5 bars respectively over a three week period. The carrots transpired 7.8 and 3.9 ml/day at osmotic potentials of -0.2 and -2.0 bars respectively which suggests that sufficient water was passing through the membrane to meet the needs of a growing carrot. / Land and Food Systems, Faculty of / Graduate Carrots - diseases and pests Pythium
14	Observations on the level of pectic and cellulolytic enzymes in healthy Pisum sativum seedlings and those infected with Pythium ultimum. Shaw, Carol Elaine January 1967 (has links) No description available. Enzymes Peas. Pythium ultimum.
15	Influence of light on the oospore germination of several species of pythium and Phytophthora / Cardoso, Elke J. B. N. January 1971 (has links) No description available. Agriculture Pythium Phytophthora
16	Factors affecting Pythium root rot of soybean and germination of oospores of Pythium ultimum / Chou, Liu-Gei January 1973 (has links) No description available. Biology Pythium Soybean
17	A study of pythium species associated with turfgrasses in Ohio : their prevalence and pathogenicity / Saladini, John Louis January 1976 (has links) No description available. Agriculture Grasses Pythium
18	DISEASES OF HYDROPONICALLY GROWN SPINACH CAUSED BY PYTHIUM APHANIDERMATUM AND PYTHIUM DISSOTOCUM. Bates, Mary Lisa. January 1983 (has links) No description available. Hydroponics. Pythium aphanidermatum. Spinach -- Diseases and pests. Pythium dissotocum.
19	Rhythm of zoospore production of pythium on lettuce cultured hydroponically Sultan, Youneskhan, 1957- January 1988 (has links) Zoospore production of Pythium dissotocum Drechs. in the nutrient solution of hydroponically-grown lettuce, in the greenhouse, was shown to be cyclic. The number of zoospores detected in the nutrient solution was lowest around noontime, (11:00-14:00 hr) and highest around 20:00 hr. Growth chamber studies were conducted to determine the effect of different light periods on zoospore production. Under continuous light or continuous darkness, the population of zoospores in the nutrient solution decreased. But under 12 hours light, and 12 hours darkness or two periods of light each for 3 hours, zoospore populations decreased during the light period but increased during the dark period. Lettuce -- Diseases and pests. Pythium. Hydroponics.
20	The effects of salinity stress on the development of Pythium blight of Agrostis palustris Rasmussen, Scott Lynn, 1958- January 1987 (has links) Salinity stress predisposed Penncross creeping bentgrass to cottony blight caused by P. aphanidermatum. Studies were conducted on the effects of salinity on the mycelial growth of P. aphanidermatum and on the growth of Penncross bentgrass. Mycelial growth increased significantly up to Ec levels of 7.1 ds/m when compared to mycelial growth at the control Ec levels of 0.5 ds/m. Plant growth was reduced to 50% of the control at Ec levels of 4.3 ds/m. 3-month-old Penncross bentgrass plants were inoculated and incubated at two differing temperatures. At 32 C, all plants died within 3 days regardless of salinity treatment. Rates of plant death were greatest at salinity levels over 2.8 ds/m. At 27 C, plants irrigated with water at Ec levels from 4.3 to 7.1 ds/m showed complete necrosis within 5 days, while treatments irrigated with tap water showed no disease symptoms. Pythium. Grasses. Plants -- Effect of salt on.

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