BUXORO VOHASI SUGʻORILADIGAN O‘TLOQI ALLYUVIAL TUPROQLARINING BIOLOGIK JARAYONLARIGA PREPARATLARNING TA’SIRI
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aktinimesitlarumumiy vergul ro'yxat seperatori amminofikatorlarumumiy vergul ro'yxat seperatori oligonitrofillarumumiy vergul ro'yxat seperatori sporalilarumumiy vergul ro'yxat seperatori mikroskopik zamburugʻlarumumiy vergul ro'yxat seperatori aerob seluloza parchalovchilar,umumiy vergul ro'yxat seperatori shoʻrlangan tuproqlar##article.abstract##
Bugungi kunda bir qancha rivojlangan davlatlar tuproq-oʻsimlik aloqalarini
yaxshilashda kremniy tarkibli preparatlarni qoʻllab, bu orqali yuqori hosildorlikka erishmoqdalar.
Tuproqning biologik xossalarini yaxshilash bu, oʻsimlikning immun tizimini yaxshilanishi,
stresslarga javob reaksiyalarini hosil boʻlish jarayoni hamda sifati va koʻp hosildorlikka xizmat
qiladi. Tuproq mikroorganizmlari bu jarayonda muhim ahamiyatga ega. Ushbu maqolada
sugʻoriladigan oʻtloqi alluvial tuproqlarning biologik xossalarini yaxshilashda kremniy tarkibli
preparatlarni taʼsiri oʻrganilgan. Tuproq mikroorganizmlari faoligini mavsumiy oʻzgarishlarida
Aminosid-Aton, Aminosid-Silicon, Bioazot preparatlarini taʼsiri oʻrganilgan.
##submission.citations##
Crous, P. W., Braun, U., Schubert, K. & Groenewald, J. Z. Delimiting Cladosporium from
morphologically similar genera. Stud. Mycol. 58, 33–56 (2007).
Hawksworth, D. L. The magnitude of fungal diversity: the 1.5 million species estimate
revisited. Mycol. Res. 105, 1422–1432 (2001).
Nabieva, G., Makhkamova, D. & Botirova, N. Microbiological activity of saline alluvial
meadow soils in the karakalpak republic (on the example of the takhtakupir fog).
UniversumChemistry Biol. 83, (2021).
И. Н. Автономова, М. К. Зинченко & И. М. Щукин. Микробные комплексы и их
функционирование при применении органических удобрений на серой лесной почве
верхневолжья. (2022) doi:10.24412/2225-2584-2022-4-4-8.
Мошкина, Е. В. et al. Microbiological characteristics of soils under vegetation microgroups in
a middle-taiga cowberry pine forest in karelia. Proc. Karelian Res. Cent. Russ. Acad. Sci. 107
(2019) doi:10.17076/eco1135.
Abdullah, E. H. E., Misran, A., Yaapar, M. N., Yusop, M. R. & Ramli, A. The potential of
silicon in improving rice yield, grain quality, and minimising chalkiness: A review. Pertanika
J. Trop. Agric. Sci. (2021) doi:10.47836/pjtas.44.3.09.
Kakoi, K. et al. Isolation of Mutants of the Nitrogen-Fixing Actinomycete Frankia. Microbes
Environ. 29, 31–37 (2014).
Hamdali, H., Hafidi, M., Virolle, M. J. & Ouhdouch, Y. Growth promotion and protection
against damping-off of wheat by two rock phosphate solubilizing actinomycetes in a P-deficient
soil under greenhouse conditions. Appl. Soil Ecol. 40, 510–517 (2008).
Abdallah, M. E., Haroun, S. A., Gomah, A. A., El-Naggar, N. E. & Badr, H. H. Application of
actinomycetes as biocontrol agents in the management of onion bacterial rot diseases. Arch.
Phytopathol. Plant Prot. 46, 1797–1808 (2013).
Weston, D. J. et al. Pseudomonas fluorescens Induces Strain-Dependent and StrainIndependent Host Plant Responses in Defense Networks, Primary Metabolism, Photosynthesis,
and Fitness. Mol. Plant-Microbe Interactions® 25, 765–778 (2012).
Egamberdieva, D., Alaylar, B., Kistaubayeva, A., Wirth, S. & Bellingrath-Kimura, S. D.
Biochar for Improving Soil Biological Properties and Mitigating Salt Stress in Plants on Saltaffected Soils. Commun. Soil Sci. Plant Anal. 53, 140–152 (2022).
Jaiswal, B., Singh, S., Agrawal, S. B., Lokupitiya, E. & Agrawal, M. Improvements in Soil
Physical, Chemical and Biological Properties at Natural Saline and Non-Saline Sites Under
Different Management Practices. Environ. Manage. 69, 1005–1019 (2022).
Furtak, K. & Gajda, A. M. Activity and Variety of Soil Microorganisms Depending on the
Diversity of the Soil Tillage System. in Sustainability of Agroecosystems (ed. Oliveira, A. B.
D.) (InTech, 2018). doi:10.5772/intechopen.72966.
Hoshyar, A. N., Kharkovsky, S. & Samali, B. Statistical Features and Traditional SA-SVM
Classification Algorithm for Crack Detection. J. Signal Inf. Process. 09, 111–121 (2018).
Hozzein, W. N. et al. Exploring the potential of actinomycetes in improving soil fertility and
grain quality of economically important cereals. Sci. Total Environ. 651, 2787–2798 (2019).
Classen, A. T. et al. Direct and indirect effects of climate change on soil microbial and soil
microbial-plant interactions: What lies ahead? Ecosphere 6, art130 (2015).[17] Ma, J. F., Yamaji, N. & Mitani-Ueno, N. Transport of silicon from roots to panicles in plants.
Proc. Jpn. Acad. Ser. B 87, 377–385 (2011).
Fan, L. et al. Patterns of soil microorganisms and enzymatic activities of various forest types in
coastal sandy land. Glob. Ecol. Conserv. 28, e01625 (2021).
Bollag, J. M. Interactions of Soil Components and Microorganisms and their Effects on Soil
Remediation. Rev. Cienc. Suelo Nutr. Veg. 8, (2008).
Schaller, K. & Osterfeld, K. H. “In-vivo” and “in-vitro” Experiments on the Influence of
Compost Preparations and Heavy Metals on Soil Enzymes Activities and Soil Health. Bull.
Univ. Agric. Sci. Vet. Med. Cluj-Napoca Hortic. 79, 54 (2022).
Wang, G. et al. In-situ immobilization of cadmium-polluted upland soil: A ten-year field study.
Ecotoxicol. Environ. Saf. (2021) doi: 10.1016/j.ecoenv.2020.111275.
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