Results 41 to 50 of about 39,160 (208)
Fungal pathogens associated with crown and collar rot of apple trees in southern Syria
Acta Agriculturae Slovenica, 2017 Crown and collar rot of apple trees is a destructive and widespread disease in most areas of the world. Surveys have been done to describe disease symptoms, estimate the disease incidence, and identify the pathogens associated with this disease in ...
Walid Ghazi Naffaa, Abeer Rashid
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Nectria galligena as the cause of a collar rot disease in organically grown Topaz apple trees [PDF]
, 2006 Symptoms resembling collar rot were detected in organically managed Topaz trees aged 3-10 years, occur-ring one to several years after planting of the orchard. Trees were killed within the same growing season in which symptoms were first observed.
Klopp, Karsten, Weber, Roland W. S.
core
Harnessing Fungal Biowelding for Constructing Mycelium‐Engineered Materials
Advanced Engineering Materials, EarlyView.Mycelium‐bound composites (MBCs) offer low‐carbon alternatives for construction, yet interfacial bonding remains a critical challenge. This review examines fungal biowelding as a biocompatible adhesive, elucidating mycelium‐mediated interfacial mechanisms and their role in material assembly. Strategies to optimize biowelding are discussed, highlighting
Xue Brenda Bai +2 more
wiley +1 more source
Use of Neem leaves as soil amendment for the control of collar rot disease of chickpea
Egyptian Journal of Biological Pest Control, 2020 Chickpea (Cicer arietinum L.) is an important grain legume that is attacked by the fungal pathogen, Sclerotium rolfsii, responsible for collar rot disease. In the present study, the pathogen was isolated from diseased chickpea seedlings and identified on
Iqra Haider Khan +3 more
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A New Aglaonema Foliar Blight and Crown Rot [PDF]
, 1993 The cause of leaf, petiole, collar, and cane rots of aglaonema in Hawaii was determined to be Fusarium subglutinans. A bacterial leaf rot was also investigated.
Uchida, J.Y., Yahata, P.S.
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Management of collar rot disease in chickpea by Trichoderma species
Journal of AgriSearch, 2020 Nine isolates of Trichoderma spp. were isolated from different agro- ecological regions of Nepal viz; Jumla, Palpa, Chitwan, Tarahara, Banke, Illam and Salyan and screened against Sclerotium rolfsii Sacc. Adreded soil borne phytopathogen causing collar rot of chickpea in chickpea; In-vitro efficacy of nine fungal antagonist (Trichoderma spp.) against ...
PREM PANDEY +5 more
openaire +1 more source
Business Strategy and the Environment, EarlyView.ABSTRACT As sustainability transitions accelerate, firms increasingly engage in innovation ecosystems to pursue disruptive sustainable innovation (DSI). Nevertheless, empirical understanding regarding how innovation ecosystem coopetition—simultaneous cooperation and competition among interdependent actors—translates into sustainability‐oriented ...
Jin‐Sup Jung, Min‐Jae Lee
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The Indian Journal of Agricultural SciencesCollar rot disease incited by Aspergillus niger van Tiegham is one of the major constraint to groundnut (Arachis hypogaea L.) production in India. This fungus is ubiquitous, soil inhabitant causing severe reduction in seed germination.
GARIMA +6 more
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Systemic immunity against soil borne Phytophthora and control of ink disease of chestnut by foliar spray of potassium phosphonate [PDF]
, 2010 Chestnut ink disease represents a great risk for chestnut (Castanea sativa Mill.) in all regions of chestnut production of Europe and North America. Induced by soil borne oomycetes, Phytophthora cinnamomi and P.
Coelho, Valentim +4 more
core +1 more source
Revista de Ciencias Agrícolas, 2023 Controlled infection systems constitute a valuable tool in the study of pathosystems, as they enable the observation and measurement of specific characteristics with greater precision and ease compared to natural conditions. Additionally, they are useful
Erika Patricia Martinez-Lemus +6 more
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