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== Références générales == | |||
Chen, L., et W.A. Dick. 2011. Gypsum as an agricultural amendment: General use guidelines. Ohio State University Extension). https://fabe.osu.edu/sites/fabe/files/imce/files/Soybean/Gypsum%20Bulletin.pdf | |||
CRAAQ. 2010. Guide de référence en fertilisation, 2re édition. | |||
Cordell, D. et S. White 2011. Clarifying the key issues of a vigorous debate about long-term phosphorus security. Sustainability 3:2027-2049. | |||
Diver, S. 2002. Notes On Compost Tea. A supplement to the ATTRA publication Compost Tea For Plant Disease | |||
Landry, C.M. 2018. Le carbone labile, au cœur d’une matière organique efficace. Conférence. Colloque santé des sols. 8 janvier 2018. | |||
Landry, C., M. Marchand-Roy, J. Mainguy et M. Paradis. 2019. Détermination terrain du coefficient d'efficacité azoté et du délai de libération de l'azote (N) des fientes granulées de poules pondeuses dans les cultures de maïs-grain et avoine. Institut de recherche et de développement en agroenvironnement (IRDA). Projet dans le cadre du programme fédéral-provincial de ‘Cultivons l’avenir’ 14p. https://irda.blob.core.windows.net/media/5616/landry-et-al-2019-determination_terrain_du_coefficient_defficacite_azote_et_du_delai_de_liberation_de_lazote_des_fientes_granulees_de_poules_pondeuses_fiche.pdf | |||
Heckman, J.R. 2009.Boron. Needs of soils and crop in New Jersey. Fact Sheet FS873. Rutgers, the state university of New Jersey. https://njaes.rutgers.edu/pubs/publication.php?pid=fs873 | |||
Majeau, J. A., M. Hebert et J. Desforges. 2013. Les cendre de poêle à bois: que peut-on en faire?. Vecteur environnement. Mai 2013: 43-49. https://www.environnement.gouv.qc.ca/matieres/articles/cendre-poele-bois-201305.pdf. | |||
OMAFRA. Publication 611F du MAAARO, Manuel sur la fertilité du sol http://www.omafra.gov.on.ca/french/crops/pub611/pub611ch2.pdf | |||
Singleton, P.W. and J.W. Tavares. 1986. Inoculation Response of Legumes in Relation to the Number and Effectiveness of Indigenous Rhizobium Populations. Applied and Environmental Microbiology 51:1013-1018. | |||
https://www.researchgate.net/publication/7423139_Inoculation_Response_of_Legumes_in_Relation_to_the_Number_and_Effectiveness_of_Indigenous_Rhizobium_Populations | |||
Sorensen, J.N. and K. Thorup-Kristensen. 2011. Plant-based fertilizers for organic vegetable production. Journal of Plant Nutrition and Soil Science. 174(2): 321-332. | |||
Sorensen J.N. and K. Grevsen. 2016. Strategies for cut-and-carry green manure production. Acta Hortic 1137.ISHS 2016. Proc. Int. Symp. On Innovation in Integrated and Organic Agriculture. Eds. : S Bellon et al | |||
Thies, J. E. 2021. Biological nitrogen fixation: symbiotic. In Principles and Applications of Soil Microbiology. pp. 455-487. | |||
== Références pour les mycorhizes == | |||
Banerjee , S., F. Walder , L. Büchi , M. Meyer , A. Y Held , A. Gattinger, T. Keller , R. Charles, M. G A van der Heijden. 2019. Agricultural intensification reduces microbial network complexity and the abundance of keystone taxa in roots. ISME J. :13:1722-1736. https://pubmed.ncbi.nlm.nih.gov/30850707 | |||
FIBL – essais DOC. p. 53. https://www.fibl.org/fileadmin/documents/shop/13711-03_Essai_DOC_FS_2017_F.pdf | |||
Hijri, M. 2016. Analysis of a large dataset of mycorrhiza inoculation field trials on potato shows highly significant increases in yield. Mycorrhiza. 26:209–214 | |||
Jochems-Tanguay L. 2014. Les inoculants mycorhiziens pour une agriculture québécoise plus productive et moins dépendantes aux engrais phosphatés. Essai présenté au Centre de formation en environnement et développement durable en vue de l’obtention du grade de maître en environnement (M. Env.). Université de Sherbrooke. https://www.usherbrooke.ca/environnement/fileadmin/sites/environnement/documents/Essais_2014/Jochems-Tanguay_L__2014-10-08_.pdf | |||
Landry, C. 2020. Effet sur les rendements de l’ajout d'inoculum mycorhiziens commerciaux sur des semences enrobées dans la culture de la carotte nantaise en sol minéral en début de transition biologique. IRDA. Rapport présenté à MAPAQ DRCA. | |||
Landry G-A. 2017. Effets des mycorhizes sur la croissance et le rendement dans la culture de l’ail. MAPAQ (projet PADAAR). https://www.agrireseau.net/documents/Document_96915.pdf | |||
Oehl, F., E. Sieverding, P. Mäder, D. Dubois, K. Ineichen, T. Boller et A. Wiemken. 2004. Impact of long-term conventional and organic farming on the diversity of arbuscular mycorrhizal fungi. Oecologia 138:574–583. https://link.springer.com/article/10.1007/s00442-003-1458-2 | |||
Roy. J. Carottes en sol minéral : mycorhizées ou non. Conférence. https://www.youtube.com/watch?v=lEz6rCW9mMo | |||
== Références pour le thé de compost == | |||
Al-Mughrabi, K., 2006. Antibiosis ability of aerobic compost tea against foliar and tuber potato diseases. Biotechnology. 5:69-74 | |||
Duffy, B., C. Sarreal, S. Ravva and L. Stanker. 2013. Effect of molasses on regrowth of E. Coli O157:H7 and Salmonella in compost teas. Compost science and utilization. 12:93-96 | |||
Ingham, E.R. 2005. The Compost Tea Brewing Manual. Soil Foodweb Incorporated, 728 SW Wake Robin AveCorvallis, Oregon 97333. | |||
Pant, A.,T.J.K. Radovich, N.V. Hue, S.T. Talcott, and K.A. Krenek. 2009. Vermi- compost extracts influence growth, mineral nutrients, phytonutrients and antioxidant activity in Pak choi (Brassica rapa cv. Bonsai Chinensis group) grown under vermicompost and chemical fertilizer. J. Sci. Food Agric. 89: 2383–92. | |||
https://www.mapaq.gouv.qc.ca/SiteCollectionDocuments/Regions/ChaudiereAppalaches/2-Essaisdethedecompostdanstomatefraisehamp.pdf | |||
Arancon, N.Q., A. Pant, T. Radovich, V.H. Nguyen, J.K., Potter and C.E. Converse. 2012. Seed Germination and Seedling Growth of Tomato and Lettuce as Affected by Vermicompost Water Extracts (Teas), Hortscience. 47: 1722–1728. | |||
Heba, I. A. K. et I.M. Sherif, 2014. Effect Of Some Organic Extracts On Essential Nutrients Uptake Of Sugar Beet Under Saline Conditions. Research Journal of Agriculture and Biological Sciences. 10:53-64. | |||
Hirzel, J., Cerda, F, Millas, P. and A. France. 2012. Compost Tea Effects on Production and Extraction of Nitrogen in Ryegrass Cultivated on Soil Amended With Commercial Compost, Compost Science and Utilization. 20: 97-104. | |||
Gomez-Brandon, M., M. Vela, M. Martinez-Toledo, H. Insam and J. Dominguez. 2015. Effet of compost and vermicompost teas as organic fertilizers. In: Sinha, S. Pant, K.K. Bajpai S. (Eds.), Advances en Fertiliser Technology: Synthesis (Vol 1). Studium Press, LLC, USA, pp 300-318. | |||
== Référence pour les extraits d’algues == | |||
Alam, M. Z., G. Braun, J. Norrie, and D.M. Hodges. 2013. Effect of Ascophyllum extract application on plant growth, fruit yield and soil microbial communities of strawberry. Canadian Journal of Plant Science. 93(1):23-36. | |||
Aldworth, S. J., and J. Van Staden. 1987. The effect of seaweed concentrate on seedling transplants. South African Journal of Botany. 53(3):187-189. | |||
Basak A. 2008. Effect of preharvest treatment with seaweed products, Kelpak® and Goemar BM86®, on fruit quality in apple. Int J Fruit Sci. 8:1–14 | |||
Fan, D., D. M. Hodges, A. T. Critchley. and B. Prithiviraj. 2013. A commercial extract of Brown Macroalga (Ascophyllum nodosum) affects yield and the nutritional quality of spinach in vitro. Commun Soil Sci Plant Anal. 44:1873–1884. | |||
Craigie J.S. 2011 Seaweed extract stimuli in plant science and agriculture. J Appl Phycol. 23:371–393 | |||
Crouch, I. J., and J. Van Staden. 1992. Effect of seaweed concentrate on the establishment and yield of greenhouse tomato plants. Journal of Applied Phycology. 4(4):291-296. | |||
Dell’Aversana, E., V. Cirillo, M. J. Van Oosten, E. Di Stasio, K. Saiano, P. Woodrow. and P. Carillo. 2021. Ascophyllum nodosum Based Extracts Counteract Salinity Stress in Tomato by Remodeling Leaf Nitrogen Metabolism. Plants. 10(6):104 | |||
Dixon, G. R., and U. Walsh. 2002. Suppressing Pythium ultimum induced damping-off in cabbage seedlings by biostimulation with proprietary liquid seaweed extracts. In XXVI International Horticultural Congress: Managing Soil-Borne Pathogens: A Sound Rhizosphere to Improve Productivity. 635:103-106. | |||
Goñi, O., P. Quille, and S. O'Connell. 2018. Ascophyllum nodosum extract biostimulants and their role in enhancing tolerance to drought stress in tomato plants. Plant physiology and biochemistry. 126: 63-73. | |||
González, A., J. Castro, J Vera. and A. Moenne. 2012. Seaweed Oligosaccharides Stimulate Plant Growth by Enhancing Carbon and Nitrogen Assimilation, Basal Metabolism, and Cell Division. J. Plant Growth Regul. 32:443–448. | |||
Khan, W., U. P. Rayirath, S. Subramanian et al. 2209. Seaweed Extracts as Biostimulants of Plant Growth and Development. J Plant Growth Regul. 28:386–399. | |||
Kumar G and D. Sahoo. 2011. Effect of seaweed liquid extract on growth and yield of Triticum aestivum var. Pusa Gold J Appl Phycol. 23:251–255. | |||
Kumari, R., I. Kaur and A. K. Bhatnagar. 2011 Effect of aqueous extract of Sargassum johnstonii Setchell& Gardner on growth, yield and quality of Lycopersicon esculentum Mill. J Appl Phycol. 23:623–633 | |||
Jayaraj, J., A. Wan, M. Rahman, and Z.K. Punja. 2008. Seaweed extract reduces foliar fungal diseases on carrot. Crop Protection. 27(10):1360-1366. | |||
Lizzi, Y., C. Coulomb, C. Polian, P. J. Coulomb, and P. O. Coulomb. 1998. Seaweed and mildew: what does the future hold?. Phytoma La Defense des Vegetaux (France). | |||
Mattner, S. W., D. Wite, D. A. Riches, I.J. Porter, and T. Arioli. 2013. The effect of kelp extract on seedling establishment of broccoli on contrasting soil types in southern Victoria, Australia. Biological agriculture & horticulture. 29(4):258-270. | |||
Ugarte, R. A., G. Sharp, and B. Moore. 2006. Changes in the brown seaweed Ascophyllum nodosum (L.) Le Jol. Plant morphology and biomass produced by cutter rake harvests in southern New Brunswick, Canada. In Eighteenth International Seaweed Symposium. 125-133. | |||
Whapham, C. A., G. Blunden, T. Jenkins, and S. D. Hankins. 1993. Significance of betaines in the increased chlorophyll content of plants treated with seaweed extract. Journal of Applied Phycology. 5(2):231-234. | |||
Zhang, Q., J. Zhang, J. Shen, A. Silva and D. A. Dennis. 2006. A simple 96-well microplate method for estimation of total polyphenol content in seaweeds. J Appl Phycol. 18:445–450 | |||
== Références pour les émulsions de poisson == | |||
Abbasi, P. A., K. L. Conn and G. Lazarovits. 2006. Effect of fish emulsion used as a preplanting soil amendment on Verticillium wilt, scab, and tuber yield of potato. Canadian Journal of Plant Pathology. 28(4):509-518. | |||
Aung, L. H., and G. J. Flick Jr. 1980. The influence of fish solubles on growth and fruiting of tomato. HortScience. 15(1):32-33. | |||
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Version du 2022-07-09 à 08:24:32
Portail - Opérations
Références générales
Chen, L., et W.A. Dick. 2011. Gypsum as an agricultural amendment: General use guidelines. Ohio State University Extension). https://fabe.osu.edu/sites/fabe/files/imce/files/Soybean/Gypsum%20Bulletin.pdf
CRAAQ. 2010. Guide de référence en fertilisation, 2re édition.
Cordell, D. et S. White 2011. Clarifying the key issues of a vigorous debate about long-term phosphorus security. Sustainability 3:2027-2049.
Diver, S. 2002. Notes On Compost Tea. A supplement to the ATTRA publication Compost Tea For Plant Disease Landry, C.M. 2018. Le carbone labile, au cœur d’une matière organique efficace. Conférence. Colloque santé des sols. 8 janvier 2018.
Landry, C., M. Marchand-Roy, J. Mainguy et M. Paradis. 2019. Détermination terrain du coefficient d'efficacité azoté et du délai de libération de l'azote (N) des fientes granulées de poules pondeuses dans les cultures de maïs-grain et avoine. Institut de recherche et de développement en agroenvironnement (IRDA). Projet dans le cadre du programme fédéral-provincial de ‘Cultivons l’avenir’ 14p. https://irda.blob.core.windows.net/media/5616/landry-et-al-2019-determination_terrain_du_coefficient_defficacite_azote_et_du_delai_de_liberation_de_lazote_des_fientes_granulees_de_poules_pondeuses_fiche.pdf
Heckman, J.R. 2009.Boron. Needs of soils and crop in New Jersey. Fact Sheet FS873. Rutgers, the state university of New Jersey. https://njaes.rutgers.edu/pubs/publication.php?pid=fs873
Majeau, J. A., M. Hebert et J. Desforges. 2013. Les cendre de poêle à bois: que peut-on en faire?. Vecteur environnement. Mai 2013: 43-49. https://www.environnement.gouv.qc.ca/matieres/articles/cendre-poele-bois-201305.pdf.
OMAFRA. Publication 611F du MAAARO, Manuel sur la fertilité du sol http://www.omafra.gov.on.ca/french/crops/pub611/pub611ch2.pdf
Singleton, P.W. and J.W. Tavares. 1986. Inoculation Response of Legumes in Relation to the Number and Effectiveness of Indigenous Rhizobium Populations. Applied and Environmental Microbiology 51:1013-1018.
Sorensen, J.N. and K. Thorup-Kristensen. 2011. Plant-based fertilizers for organic vegetable production. Journal of Plant Nutrition and Soil Science. 174(2): 321-332.
Sorensen J.N. and K. Grevsen. 2016. Strategies for cut-and-carry green manure production. Acta Hortic 1137.ISHS 2016. Proc. Int. Symp. On Innovation in Integrated and Organic Agriculture. Eds. : S Bellon et al
Thies, J. E. 2021. Biological nitrogen fixation: symbiotic. In Principles and Applications of Soil Microbiology. pp. 455-487.
Références pour les mycorhizes
Banerjee , S., F. Walder , L. Büchi , M. Meyer , A. Y Held , A. Gattinger, T. Keller , R. Charles, M. G A van der Heijden. 2019. Agricultural intensification reduces microbial network complexity and the abundance of keystone taxa in roots. ISME J. :13:1722-1736. https://pubmed.ncbi.nlm.nih.gov/30850707
FIBL – essais DOC. p. 53. https://www.fibl.org/fileadmin/documents/shop/13711-03_Essai_DOC_FS_2017_F.pdf
Hijri, M. 2016. Analysis of a large dataset of mycorrhiza inoculation field trials on potato shows highly significant increases in yield. Mycorrhiza. 26:209–214
Jochems-Tanguay L. 2014. Les inoculants mycorhiziens pour une agriculture québécoise plus productive et moins dépendantes aux engrais phosphatés. Essai présenté au Centre de formation en environnement et développement durable en vue de l’obtention du grade de maître en environnement (M. Env.). Université de Sherbrooke. https://www.usherbrooke.ca/environnement/fileadmin/sites/environnement/documents/Essais_2014/Jochems-Tanguay_L__2014-10-08_.pdf
Landry, C. 2020. Effet sur les rendements de l’ajout d'inoculum mycorhiziens commerciaux sur des semences enrobées dans la culture de la carotte nantaise en sol minéral en début de transition biologique. IRDA. Rapport présenté à MAPAQ DRCA.
Landry G-A. 2017. Effets des mycorhizes sur la croissance et le rendement dans la culture de l’ail. MAPAQ (projet PADAAR). https://www.agrireseau.net/documents/Document_96915.pdf
Oehl, F., E. Sieverding, P. Mäder, D. Dubois, K. Ineichen, T. Boller et A. Wiemken. 2004. Impact of long-term conventional and organic farming on the diversity of arbuscular mycorrhizal fungi. Oecologia 138:574–583. https://link.springer.com/article/10.1007/s00442-003-1458-2
Roy. J. Carottes en sol minéral : mycorhizées ou non. Conférence. https://www.youtube.com/watch?v=lEz6rCW9mMo
Références pour le thé de compost
Al-Mughrabi, K., 2006. Antibiosis ability of aerobic compost tea against foliar and tuber potato diseases. Biotechnology. 5:69-74
Duffy, B., C. Sarreal, S. Ravva and L. Stanker. 2013. Effect of molasses on regrowth of E. Coli O157:H7 and Salmonella in compost teas. Compost science and utilization. 12:93-96
Ingham, E.R. 2005. The Compost Tea Brewing Manual. Soil Foodweb Incorporated, 728 SW Wake Robin AveCorvallis, Oregon 97333. Pant, A.,T.J.K. Radovich, N.V. Hue, S.T. Talcott, and K.A. Krenek. 2009. Vermi- compost extracts influence growth, mineral nutrients, phytonutrients and antioxidant activity in Pak choi (Brassica rapa cv. Bonsai Chinensis group) grown under vermicompost and chemical fertilizer. J. Sci. Food Agric. 89: 2383–92. https://www.mapaq.gouv.qc.ca/SiteCollectionDocuments/Regions/ChaudiereAppalaches/2-Essaisdethedecompostdanstomatefraisehamp.pdf
Arancon, N.Q., A. Pant, T. Radovich, V.H. Nguyen, J.K., Potter and C.E. Converse. 2012. Seed Germination and Seedling Growth of Tomato and Lettuce as Affected by Vermicompost Water Extracts (Teas), Hortscience. 47: 1722–1728.
Heba, I. A. K. et I.M. Sherif, 2014. Effect Of Some Organic Extracts On Essential Nutrients Uptake Of Sugar Beet Under Saline Conditions. Research Journal of Agriculture and Biological Sciences. 10:53-64.
Hirzel, J., Cerda, F, Millas, P. and A. France. 2012. Compost Tea Effects on Production and Extraction of Nitrogen in Ryegrass Cultivated on Soil Amended With Commercial Compost, Compost Science and Utilization. 20: 97-104.
Gomez-Brandon, M., M. Vela, M. Martinez-Toledo, H. Insam and J. Dominguez. 2015. Effet of compost and vermicompost teas as organic fertilizers. In: Sinha, S. Pant, K.K. Bajpai S. (Eds.), Advances en Fertiliser Technology: Synthesis (Vol 1). Studium Press, LLC, USA, pp 300-318.
Référence pour les extraits d’algues
Alam, M. Z., G. Braun, J. Norrie, and D.M. Hodges. 2013. Effect of Ascophyllum extract application on plant growth, fruit yield and soil microbial communities of strawberry. Canadian Journal of Plant Science. 93(1):23-36.
Aldworth, S. J., and J. Van Staden. 1987. The effect of seaweed concentrate on seedling transplants. South African Journal of Botany. 53(3):187-189.
Basak A. 2008. Effect of preharvest treatment with seaweed products, Kelpak® and Goemar BM86®, on fruit quality in apple. Int J Fruit Sci. 8:1–14
Fan, D., D. M. Hodges, A. T. Critchley. and B. Prithiviraj. 2013. A commercial extract of Brown Macroalga (Ascophyllum nodosum) affects yield and the nutritional quality of spinach in vitro. Commun Soil Sci Plant Anal. 44:1873–1884.
Craigie J.S. 2011 Seaweed extract stimuli in plant science and agriculture. J Appl Phycol. 23:371–393
Crouch, I. J., and J. Van Staden. 1992. Effect of seaweed concentrate on the establishment and yield of greenhouse tomato plants. Journal of Applied Phycology. 4(4):291-296.
Dell’Aversana, E., V. Cirillo, M. J. Van Oosten, E. Di Stasio, K. Saiano, P. Woodrow. and P. Carillo. 2021. Ascophyllum nodosum Based Extracts Counteract Salinity Stress in Tomato by Remodeling Leaf Nitrogen Metabolism. Plants. 10(6):104 Dixon, G. R., and U. Walsh. 2002. Suppressing Pythium ultimum induced damping-off in cabbage seedlings by biostimulation with proprietary liquid seaweed extracts. In XXVI International Horticultural Congress: Managing Soil-Borne Pathogens: A Sound Rhizosphere to Improve Productivity. 635:103-106.
Goñi, O., P. Quille, and S. O'Connell. 2018. Ascophyllum nodosum extract biostimulants and their role in enhancing tolerance to drought stress in tomato plants. Plant physiology and biochemistry. 126: 63-73.
González, A., J. Castro, J Vera. and A. Moenne. 2012. Seaweed Oligosaccharides Stimulate Plant Growth by Enhancing Carbon and Nitrogen Assimilation, Basal Metabolism, and Cell Division. J. Plant Growth Regul. 32:443–448.
Khan, W., U. P. Rayirath, S. Subramanian et al. 2209. Seaweed Extracts as Biostimulants of Plant Growth and Development. J Plant Growth Regul. 28:386–399.
Kumar G and D. Sahoo. 2011. Effect of seaweed liquid extract on growth and yield of Triticum aestivum var. Pusa Gold J Appl Phycol. 23:251–255.
Kumari, R., I. Kaur and A. K. Bhatnagar. 2011 Effect of aqueous extract of Sargassum johnstonii Setchell& Gardner on growth, yield and quality of Lycopersicon esculentum Mill. J Appl Phycol. 23:623–633 Jayaraj, J., A. Wan, M. Rahman, and Z.K. Punja. 2008. Seaweed extract reduces foliar fungal diseases on carrot. Crop Protection. 27(10):1360-1366.
Lizzi, Y., C. Coulomb, C. Polian, P. J. Coulomb, and P. O. Coulomb. 1998. Seaweed and mildew: what does the future hold?. Phytoma La Defense des Vegetaux (France).
Mattner, S. W., D. Wite, D. A. Riches, I.J. Porter, and T. Arioli. 2013. The effect of kelp extract on seedling establishment of broccoli on contrasting soil types in southern Victoria, Australia. Biological agriculture & horticulture. 29(4):258-270. Ugarte, R. A., G. Sharp, and B. Moore. 2006. Changes in the brown seaweed Ascophyllum nodosum (L.) Le Jol. Plant morphology and biomass produced by cutter rake harvests in southern New Brunswick, Canada. In Eighteenth International Seaweed Symposium. 125-133.
Whapham, C. A., G. Blunden, T. Jenkins, and S. D. Hankins. 1993. Significance of betaines in the increased chlorophyll content of plants treated with seaweed extract. Journal of Applied Phycology. 5(2):231-234. Zhang, Q., J. Zhang, J. Shen, A. Silva and D. A. Dennis. 2006. A simple 96-well microplate method for estimation of total polyphenol content in seaweeds. J Appl Phycol. 18:445–450
Références pour les émulsions de poisson
Abbasi, P. A., K. L. Conn and G. Lazarovits. 2006. Effect of fish emulsion used as a preplanting soil amendment on Verticillium wilt, scab, and tuber yield of potato. Canadian Journal of Plant Pathology. 28(4):509-518.
Aung, L. H., and G. J. Flick Jr. 1980. The influence of fish solubles on growth and fruiting of tomato. HortScience. 15(1):32-33.
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