Research and Reviews - International Journals

Research & Reviews: Journal of Botanical Sciences

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ISSN: 2320-0189

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Research & Reviews: Journal of Botanical Sciences : Citations & Metrics Report

Articles published in Research & Reviews: Journal of Botanical Sciences have been cited by esteemed scholars and scientists all around the world. Research & Reviews: Journal of Botanical Sciences has got h-index 14, which means every article in Research & Reviews: Journal of Botanical Sciences has got 14 average citations.

Following are the list of articles that have cited the articles published in Research & Reviews: Journal of Botanical Sciences.

  2022 2021 2020 2019 2018

Year wise published articles

 44 61 23 11 18

Year wise citations received

 46 56 23 11 18
Journal total citations count 733
Journal impact factor 2.07
Journal 5 years impact factor 3.18831168
Journal cite score 3.08823529
Journal h-index 14
Journal h-index since 2018 13
Journal Impact Factor 2020 formula
IF= Citations(y)/{Publications(y-1)+ Publications(y-2)} Y= Year
Journal 5-year Impact Factor 2020 formula
Citations(2018 + 2019 + 2020 + 2021 + 2022)/
{Published articles(2018 + 2019 + 2020 + 2021 + 2022)}
Journal citescore
Citescorey = Citationsy + Citationsy-1 + Citationsy-2 + Citations y-3 / Published articlesy + Published articlesy-1 + Published articlesy-2 + Published articles y-3
Citation image
Important citations (524)
image Tratt, d. m., buckland, k. n., keim, e. r., hall, j. l., adams, p. m., & johnson, p. d. (2021). on the utility of longwave-infrared spectral imaging for remote botanical identification. remote sensing, 13(17), 3344.
image Das, s., rawat, p., shankhdhar, d., & shankhdhar, s. c. (2020). drought stress: an impact of climate change, its consequences and amelioration through silicon (si). in sustainable agriculture in the era of climate change (pp. 169-185). springer, cham.
image Das, s., rawat, p., shankhdhar, d., & shankhdhar, s. c. (2020). drought stress: an impact of climate change, its consequences and amelioration through silicon (si). in sustainable agriculture in the era of climate change (pp. 169-185). springer, cham.
image Thorne, s. j., hartley, s. e., & maathuis, f. j. (2021). the effect of silicon on osmotic and drought stress tolerance in wheat landraces. plants, 10(4), 814.
image Moura, h. m., & unterlass, m. m. (2020). biogenic metal oxides. biomimetics, 5(2), 29.
image Carneiro-carvalho, a., anjos, r., aires, a., marques, t., pinto, t., & gomes-laranjo, j. (2019). ecophysiological study of the impact of sik fertilization on castanea sativa mill. seedling tolerance to high temperature. photosynthetica, 57(4), 1165-1175.
image Lian, c., xie, s., li, w., ran, j., zhang, j., han, z., ... & tian, l. (2019). association of wheat chaff derived silica fiber and esophageal cancer in north china. ecotoxicology and environmental safety, 178, 79-85.
image Setiawan, w. k., & chiang, k. y. (2021). crop residues as potential sustainable precursors for developing silica materials: a review. waste and biomass valorization, 12(5), 2207-2236.
image Li, t. (2018). identifying sources of fibre in chinese handmade papers by phytoliths: a methodological exploration. star: science & technology of archaeological research, 4(1), 1-11.
image Petkowski, j. j., bains, w., & seager, s. (2020). on the potential of silicon as a building block for life. life, 10(6), 84.
image Yapuchura, e. r., tartaglia, r. s., cunha, a. g., freitas, j. c., & emmerich, f. g. (2019). observation of the transformation of silica phytoliths into sic and sio 2 particles in biomass-derived carbons by using sem/eds, raman spectroscopy, and xrd. journal of materials science, 54(5), 3761-3777.
image Thorne, s. j., hartley, s. e., & maathuis, f. j. (2020). is silicon a panacea for alleviating drought and salt stress in crops?. frontiers in plant science, 11, 1221.
image Haynes, r. j. (2017). the nature of biogenic si and its potential role in si supply in agricultural soils. agriculture, ecosystems & environment, 245, 100-111.
image Haynes, r. j. (2017). significance and role of si in crop production. advances in agronomy, 146, 83-166.
image Adel, m. a. h. a. m., & ahmed, o. i. (2020). the effect of spraying with nan iron and gibberellic acid on the chemical traits of moringa oleifera seedlings growing in two agricultural medium. euphrates journal of agriculture science, 12(2).
image Kadhim, f. j., hakim, r. a., & mijwel, a. k. (2021). response of tomato, eggplant, and pepper to nano fertilizers and the method of their addition. plant archives, 21(1), 55-58.
image Al-zebari, y. i., kahlel, a. s., & al-hamdany, s. y. h. (2021, may). response of four potato (solanum tuberosum l.) varieties to four nano fertilizers. in iop conference series: earth and environmental science (vol. 761, no. 1, p. 012060). iop publishing.
image Al-zebari, y. i., kahlel, a. s., & al-hamdany, s. y. h. (2021, may). response of four potato (solanum tuberosum l.) varieties to four nano fertilizers. in iop conference series: earth and environmental science (vol. 761, no. 1, p. 012060). iop publishing.
image Ibraheem, f. f., kahlel, a. s., & al-kawaz, a. a. (2021). improvement of growth and yield characteristics of two broccoli varieties using nanofertilizer technology. plant cell biotechnology and molecular biology, 21-29.
image Kisku, k., & naik, u. c. (2021). nanobiotechnology: a process to combat abiotic stress in crop plants. in nanobiotechnology (pp. 139-163). springer, cham.

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