Author: Lawrence Everett Walter
Publisher:
ISBN:
Category : Alfalfa
Languages : en
Pages : 116
Book Description
Controlled Environmental Studies of Alfalfa Seed Production
Author: Lawrence Everett Walter
Publisher:
ISBN:
Category : Alfalfa
Languages : en
Pages : 116
Book Description
Publisher:
ISBN:
Category : Alfalfa
Languages : en
Pages : 116
Book Description
Hybridization of Crop Plants
Author: Henry Hultman Hadley
Publisher: American Society of Agronomy
ISBN:
Category : Science
Languages : en
Pages : 850
Book Description
Publisher: American Society of Agronomy
ISBN:
Category : Science
Languages : en
Pages : 850
Book Description
Alfalfa Management Guide
Author: D. J. Undersander
Publisher:
ISBN: 9780891181798
Category : Alfalfa
Languages : en
Pages : 0
Book Description
The Alfalfa Management Guide is designed especially for busy growers, with to-the-point recommendations, useful images of diseased plants and pests, and quick-reference tables and charts. Revised in 2011, this edition of Alfalfa Management Guide covers the latest strategies for alfalfa establishment, production, and harvest-soil testing, fertilizing, integrated pest management, rotation, and more.
Publisher:
ISBN: 9780891181798
Category : Alfalfa
Languages : en
Pages : 0
Book Description
The Alfalfa Management Guide is designed especially for busy growers, with to-the-point recommendations, useful images of diseased plants and pests, and quick-reference tables and charts. Revised in 2011, this edition of Alfalfa Management Guide covers the latest strategies for alfalfa establishment, production, and harvest-soil testing, fertilizing, integrated pest management, rotation, and more.
Alfalfa Seed Production
Author: Charles Vancouver Piper
Publisher:
ISBN:
Category : Agriculture
Languages : en
Pages : 56
Book Description
Publisher:
ISBN:
Category : Agriculture
Languages : en
Pages : 56
Book Description
Proceedings
Author: Alfalfa Seed Production Symposium; Alfalfa Seed Advisory Board (Calif.); California Alfalfa Seed Research Advisory Board; University of California (System). Cooperative Extension; California Alfalfa Seed Production Research Program; California Alfalfa Seed Production Research Board
Publisher:
ISBN:
Category :
Languages : en
Pages :
Book Description
Publisher:
ISBN:
Category :
Languages : en
Pages :
Book Description
Weed and Dodder Control Studies in Alfalfa Seed Production
Alfalfa Seed Production
Author: J. M. Westgate
Publisher:
ISBN:
Category : Alfalfa
Languages : en
Pages : 44
Book Description
Publisher:
ISBN:
Category : Alfalfa
Languages : en
Pages : 44
Book Description
Effects of Plant Regulators on Growth Development and Seed Production of Alfalfa Development
Author: John Charles Phillips
Publisher:
ISBN:
Category : Alfalfa
Languages : en
Pages : 242
Book Description
Experiments were conducted to determine the effects of certain plant regulatory chemicals on seed production of alfalfa (Medicago sativa L.). Two plant regulators, SADH (succinic acid 2,2-dimethylhydrazide) and TIBA (2,3,5- triiodobenzoic acid), received particular attention. Replicated field tests of the plant regulators were carried out on the cultivar 'Talent' in southern Oregon and on 'DuPuits' in the Willamette Valley. Other experiments were conducted in the greenhouse, laboratory, and in controlled environment chambers to explore possible modes of action. In 1972 foliar sprays of SADH and an experimental formulation of succinic acid derivatives, TD-6266-R, resulted in seed yields of 'Talent' of approximately 400 kg ha−1 compared to 168 kg ha−1 in untreated plots. These responses were statistically significant, while lesser seed yield increases due to 2,4-DB [4-(2,4-dichlorophenoxY) butyric acid] and chlormequat [(2-chloroethyl)trimethylammonium chloride] were not significant. Similar field testing in 1973 resulted in no seed yield enhancement by any plant regulator. However, precipitation at the experimental site during the 1973 growing season was only 0.4 cm in contrast to the 30-year average of 4.3 cm. A plant regulator-environment interaction is suggested. Yield component analysis showed that the number of seeds per pod was increased significantly by the same treatments which promoted yield. Number of pods per raceme was also a strong determinant of seed yield. The relative importance of one component of yield, the number of seedbearing racemes per unit land area, is yet to be established. After treatment with SADH and TIBA in 1973, fieldgrown 'DuPuits' alfalfa accumulated more total dry matter and up to twice as much dry matter in pods as did untreated plots. Shoots treated with TIBA exhibited a mean net carbon dioxide exchange (NCE) rate of 21 mg CO2 dm−2 leaf area hr−1 compared to 16 mg CO2 dm−2 hr −1 for SADH-treated and control shoots. However, dry matter accumulation and NCE responses were statistically nonsignificant at the .05 probability level. Specific leaf weight exhibited an increased diurnal maximum when treated with SADH and TIBA, while the diurnal minimum remained equal to that of control plants. The principal effect of TIBA on reproductive development was via its promotion of the growth and raceme initiation of axillary branches. In a dosage response study, 10 ppm TIBA was most effective, resulting in a fourfold increase in total branch length per primary stem and a highly significant increase in total raceme production. The finding that two axillary structures generally arise from an alfalfa leaf axil may be useful in understanding the phenomena of branching and floral initiation in this crop. Alfalfa genotypes differed in their growth response to environmental conditions. It appeared possible that genotypes also differed in response to applied plant regulators. This research has shown that applied plant regulators can promote flowering in alfalfa and has suggested that the carbon budget of alfalfa may also be affected. These changes may or may not be translated into increased seed production. The net effects are a result of plant regulator interaction with environmental conditions and plant genotype. Thus, variability in the response to plant regulators can be expected.
Publisher:
ISBN:
Category : Alfalfa
Languages : en
Pages : 242
Book Description
Experiments were conducted to determine the effects of certain plant regulatory chemicals on seed production of alfalfa (Medicago sativa L.). Two plant regulators, SADH (succinic acid 2,2-dimethylhydrazide) and TIBA (2,3,5- triiodobenzoic acid), received particular attention. Replicated field tests of the plant regulators were carried out on the cultivar 'Talent' in southern Oregon and on 'DuPuits' in the Willamette Valley. Other experiments were conducted in the greenhouse, laboratory, and in controlled environment chambers to explore possible modes of action. In 1972 foliar sprays of SADH and an experimental formulation of succinic acid derivatives, TD-6266-R, resulted in seed yields of 'Talent' of approximately 400 kg ha−1 compared to 168 kg ha−1 in untreated plots. These responses were statistically significant, while lesser seed yield increases due to 2,4-DB [4-(2,4-dichlorophenoxY) butyric acid] and chlormequat [(2-chloroethyl)trimethylammonium chloride] were not significant. Similar field testing in 1973 resulted in no seed yield enhancement by any plant regulator. However, precipitation at the experimental site during the 1973 growing season was only 0.4 cm in contrast to the 30-year average of 4.3 cm. A plant regulator-environment interaction is suggested. Yield component analysis showed that the number of seeds per pod was increased significantly by the same treatments which promoted yield. Number of pods per raceme was also a strong determinant of seed yield. The relative importance of one component of yield, the number of seedbearing racemes per unit land area, is yet to be established. After treatment with SADH and TIBA in 1973, fieldgrown 'DuPuits' alfalfa accumulated more total dry matter and up to twice as much dry matter in pods as did untreated plots. Shoots treated with TIBA exhibited a mean net carbon dioxide exchange (NCE) rate of 21 mg CO2 dm−2 leaf area hr−1 compared to 16 mg CO2 dm−2 hr −1 for SADH-treated and control shoots. However, dry matter accumulation and NCE responses were statistically nonsignificant at the .05 probability level. Specific leaf weight exhibited an increased diurnal maximum when treated with SADH and TIBA, while the diurnal minimum remained equal to that of control plants. The principal effect of TIBA on reproductive development was via its promotion of the growth and raceme initiation of axillary branches. In a dosage response study, 10 ppm TIBA was most effective, resulting in a fourfold increase in total branch length per primary stem and a highly significant increase in total raceme production. The finding that two axillary structures generally arise from an alfalfa leaf axil may be useful in understanding the phenomena of branching and floral initiation in this crop. Alfalfa genotypes differed in their growth response to environmental conditions. It appeared possible that genotypes also differed in response to applied plant regulators. This research has shown that applied plant regulators can promote flowering in alfalfa and has suggested that the carbon budget of alfalfa may also be affected. These changes may or may not be translated into increased seed production. The net effects are a result of plant regulator interaction with environmental conditions and plant genotype. Thus, variability in the response to plant regulators can be expected.
Alfalfa Seed Production
Gene Flow in Alfalfa
Author: Allen Emile Van Deynze
Publisher:
ISBN:
Category : Alfalfa
Languages : en
Pages : 40
Book Description
"Although there have been instances in which low-level presence of regulated materials has resulted in market disruptions (e.g., Starlink corn, LL601 and LL604 rice), there is no evidence of significant market disruption associated with the commercialization of deregulated biotech traits in the United States. Concurrent with increased U.S. farmer adoption of biotech traits in corn, soybean, and cotton there have been increases in U.S. grain/fiber export (USDA-FAS 2007) and organic production (USDA-NASS 2007a, b, c). Although only 3 to 5% of the U.S. alfalfa hay production is sold to GE-sensitive markets (Putnam 2006), production for these markets has significant economic importance in specific regions of the United States. Approximately 33% of U.S. alfalfa seed production is exported, primarily to GE-sensitive markets. A thorough understanding of gene flow in alfalfa is critical to establishing stewardship programs that enable coexistence between alfalfa growers producing GE alfalfa hay or seed and growers producing these products for GE-sensitive markets. Understanding the relative importance of gene flow between and within feral plants, hay, and seed production fields helps to identify key biological, agricultural, and environmental barriers to gene flow and to formulate logical mitigation strategies for managing the AP of GE traits in non-GE alfalfa seed and hay. Synchrony in flowering, presence of pollinators, isolation distance, and relative abundance of pollen between pollen source and pollen recipient plants are typical biological barriers, most of which are amenable to management in hay and/or seed production systems. In general, it seems that NAFA Best Management Practices in hay and certified alfalfa seed production, coupled with the pollinator-specific isolation guidelines outlined in the NAFA Best Management Practices document, are adequate for managing AP to tolerance levels appropriate for most markets. These types of management practices are employed successfully by producers of certified seed in most crops, including alfalfa, to ensure genetic purity of seed stocks. Increased isolation distances in seed production--including production in non-GE seed production zones--use of border areas, crop rotation, use of certified seed, careful selection of the introduced pollinator, and routine elimination of neighboring feral alfalfa plants are tools that can be applied to decrease further the risk of gene flow in the production of seed for GE-sensitive markets."--Summary.
Publisher:
ISBN:
Category : Alfalfa
Languages : en
Pages : 40
Book Description
"Although there have been instances in which low-level presence of regulated materials has resulted in market disruptions (e.g., Starlink corn, LL601 and LL604 rice), there is no evidence of significant market disruption associated with the commercialization of deregulated biotech traits in the United States. Concurrent with increased U.S. farmer adoption of biotech traits in corn, soybean, and cotton there have been increases in U.S. grain/fiber export (USDA-FAS 2007) and organic production (USDA-NASS 2007a, b, c). Although only 3 to 5% of the U.S. alfalfa hay production is sold to GE-sensitive markets (Putnam 2006), production for these markets has significant economic importance in specific regions of the United States. Approximately 33% of U.S. alfalfa seed production is exported, primarily to GE-sensitive markets. A thorough understanding of gene flow in alfalfa is critical to establishing stewardship programs that enable coexistence between alfalfa growers producing GE alfalfa hay or seed and growers producing these products for GE-sensitive markets. Understanding the relative importance of gene flow between and within feral plants, hay, and seed production fields helps to identify key biological, agricultural, and environmental barriers to gene flow and to formulate logical mitigation strategies for managing the AP of GE traits in non-GE alfalfa seed and hay. Synchrony in flowering, presence of pollinators, isolation distance, and relative abundance of pollen between pollen source and pollen recipient plants are typical biological barriers, most of which are amenable to management in hay and/or seed production systems. In general, it seems that NAFA Best Management Practices in hay and certified alfalfa seed production, coupled with the pollinator-specific isolation guidelines outlined in the NAFA Best Management Practices document, are adequate for managing AP to tolerance levels appropriate for most markets. These types of management practices are employed successfully by producers of certified seed in most crops, including alfalfa, to ensure genetic purity of seed stocks. Increased isolation distances in seed production--including production in non-GE seed production zones--use of border areas, crop rotation, use of certified seed, careful selection of the introduced pollinator, and routine elimination of neighboring feral alfalfa plants are tools that can be applied to decrease further the risk of gene flow in the production of seed for GE-sensitive markets."--Summary.