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OpenAlex Citation Counts

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OpenAlex is a bibliographic catalogue of scientific papers, authors and institutions accessible in open access mode, named after the Library of Alexandria. It's citation coverage is excellent and I hope you will find utility in this listing of citing articles!

If you click the article title, you'll navigate to the article, as listed in CrossRef. If you click the Open Access links, you'll navigate to the "best Open Access location". Clicking the citation count will open this listing for that article. Lastly at the bottom of the page, you'll find basic pagination options.

Requested Article:

Metal oxide nanoparticles alter peanut (Arachis hypogaea L.) physiological response and reduce nutritional quality: a life cycle study
Mengmeng Rui, Chuanxin Ma, Jason C. White, et al.
Environmental Science Nano (2018) Vol. 5, Iss. 9, pp. 2088-2102
Closed Access | Times Cited: 101

Showing 1-25 of 101 citing articles:

Zinc and iron oxide nanoparticles improved the plant growth and reduced the oxidative stress and cadmium concentration in wheat
Muhammad Rizwan, Shafaqat Ali, Basharat Ali, et al.
Chemosphere (2018) Vol. 214, pp. 269-277
Closed Access | Times Cited: 780
ZnO and CuO nanoparticles: a threat to soil organisms, plants, and human health
Vishnu D. Rajput, Tatiana Minkina, Svetlana Sushkova, et al.
Environmental Geochemistry and Health (2019) Vol. 42, Iss. 1, pp. 147-158
Closed Access | Times Cited: 239
Application of Nanoparticles Alleviates Heavy Metals Stress and Promotes Plant Growth: An Overview
Pingfan Zhou, Muhammad Adeel, Noman Shakoor, et al.
Nanomaterials (2020) Vol. 11, Iss. 1, pp. 26-26
Open Access | Times Cited: 222
Environmental Impact of Nanoparticles’ Application as an Emerging Technology: A Review
Guillermo Martínez, Manuel Merinero, María Pérez‐Aranda, et al.
Materials (2020) Vol. 14, Iss. 1, pp. 166-166
Open Access | Times Cited: 192
Physiological impacts of zero valent iron, Fe3O4 and Fe2O3 nanoparticles in rice plants and their potential as Fe fertilizers
Mingshu Li, Peng Zhang, Muhammad Adeel, et al.
Environmental Pollution (2020) Vol. 269, pp. 116134-116134
Closed Access | Times Cited: 188
Bio-interactions and risks of engineered nanoparticles
N. Prajitha, S.S. Athira, P.V. Mohanan
Environmental Research (2019) Vol. 172, pp. 98-108
Closed Access | Times Cited: 127
Effect of metal oxide nanoparticles on amino acids in wheat grains (Triticum aestivum) in a life cycle study
Yaoyao Wang, Fuping Jiang, Chuanxin Ma, et al.
Journal of Environmental Management (2019) Vol. 241, pp. 319-327
Closed Access | Times Cited: 113
Interaction of Copper-Based Nanoparticles to Soil, Terrestrial, and Aquatic Systems: Critical Review of the State of the Science and Future Perspectives
Vishnu D. Rajput, Tatiana Minkina, Bilal Ahmed, et al.
Reviews of Environmental Contamination and Toxicology (2019), pp. 51-96
Closed Access | Times Cited: 90
Impact of synthesized metal oxide nanomaterials on seedlings production of three Solanaceae crops
Nabil A. Younes, Hassan Shokry, Marwa Elkady, et al.
Heliyon (2020) Vol. 6, Iss. 1, pp. e03188-e03188
Open Access | Times Cited: 76
Effect of ZnO nanoparticles on the productivity, Zn biofortification, and nutritional quality of rice in a life cycle study
Guoying Yang, Haiyan Yuan, Hongting Ji, et al.
Plant Physiology and Biochemistry (2021) Vol. 163, pp. 87-94
Closed Access | Times Cited: 72
Effect of Foliar Fertigation of Chitosan Nanoparticles on Cadmium Accumulation and Toxicity in Solanum lycopersicum
Mohammad Faizan, Vishnu D. Rajput, Abdulaziz Al-Khuraif, et al.
Biology (2021) Vol. 10, Iss. 7, pp. 666-666
Open Access | Times Cited: 68
Influence of nanoscale micro-nutrient α-Fe2O3 on seed germination, seedling growth, translocation, physiological effects and yield of rice (Oryza sativa) and maize (Zea mays)
Dilip Itroutwar Prerna, K. Govindaraju, T. Selvaraj, et al.
Plant Physiology and Biochemistry (2021) Vol. 162, pp. 564-580
Closed Access | Times Cited: 67
Evidence and Impacts of Nanoplastic Accumulation on Crop Grains
Meng Jiang, Binqiang Wang, Rui Ye, et al.
Advanced Science (2022) Vol. 9, Iss. 33
Open Access | Times Cited: 63
Bioinoculation using indigenous Bacillus spp. improves growth and yield of Zea mays under the influence of nanozeolite
Parul Chaudhary, Priyanka Khati, Anuj Chaudhary, et al.
3 Biotech (2021) Vol. 11, Iss. 1
Open Access | Times Cited: 58
Exposure of cherry radish (Raphanus sativus L. var. Radculus Pers) to iron-based nanoparticles enhances its nutritional quality by trigging the essential elements
Noman Shakoor, Muhammad Adeel, Muhammad Zain, et al.
NanoImpact (2022) Vol. 25, pp. 100388-100388
Closed Access | Times Cited: 54
Silicon-based nanoparticles for mitigating the effect of potentially toxic elements and plant stress in agroecosystems: A sustainable pathway towards food security
Emmanuel Sunday Okeke, Ekene John Nweze, Tobechukwu Christian Ezike, et al.
The Science of The Total Environment (2023) Vol. 898, pp. 165446-165446
Open Access | Times Cited: 34
Boosting Solanum tuberosum resistance to Alternaria solani through green synthesized ferric oxide (Fe2O3) nanoparticles
Sadaf Anwaar, Dur-e-Shahwar Ijaz, Tauseef Anwar, et al.
Scientific Reports (2024) Vol. 14, Iss. 1
Open Access | Times Cited: 10
The impacts of γ-Fe2O3 and Fe3O4 nanoparticles on the physiology and fruit quality of muskmelon (Cucumis melo) plants
Yunqiang Wang, Shouxia Wang, Mengxuan Xu, et al.
Environmental Pollution (2019) Vol. 249, pp. 1011-1018
Closed Access | Times Cited: 72
Increased Plant Growth with Hematite Nanoparticle Fertilizer Drop and Determining Nanoparticle Uptake in Plants Using Multimodal Approach
Armel Boutchuen, Dell Zimmerman, Nirupam Aich, et al.
Journal of Nanomaterials (2019) Vol. 2019, pp. 1-11
Open Access | Times Cited: 69
Involvement of ethylene signaling in zinc oxide nanoparticle-mediated biochemical changes inArabidopsis thalianaleaves
Ali Raza Khan, Abdul Wakeel, Noor Muhammad, et al.
Environmental Science Nano (2018) Vol. 6, Iss. 1, pp. 341-355
Closed Access | Times Cited: 60
Effect of engineered nanoparticles on soil biota: Do they improve the soil quality and crop production or jeopardize them?
Hermes Pérez‐Hernández, F. Fernández-Luqueño, Esperanza Huerta Lwanga, et al.
Land Degradation and Development (2020) Vol. 31, Iss. 16, pp. 2213-2230
Closed Access | Times Cited: 58
Nanomaterials in Plants: A Review of Hazard and Applications in the Agri-Food Sector
Eva Kranjc, Damjana Drobne
Nanomaterials (2019) Vol. 9, Iss. 8, pp. 1094-1094
Open Access | Times Cited: 55
TiO2 nanoparticles dose, application method and phosphorous levels influence genotoxicity in Rice (Oryza sativa L.), soil enzymatic activities and plant growth
Sayyada Phziya Tariq Waani, Shagufta Irum, Iram Gul, et al.
Ecotoxicology and Environmental Safety (2021) Vol. 213, pp. 111977-111977
Open Access | Times Cited: 47
The Differences between the Effects of a Nanoformulation and a Conventional Form of Atrazine to Lettuce: Physiological Responses, Defense Mechanisms, and Nutrient Displacement
Juan Wu, Yujia Zhai, Fazel Abdolahpur Monikh, et al.
Journal of Agricultural and Food Chemistry (2021) Vol. 69, Iss. 42, pp. 12527-12540
Open Access | Times Cited: 42
Copper Oxide Nanomaterial Fate in Plant Tissue: Nanoscale Impacts on Reproductive Tissues
Marta Marmiroli, Luca Pagano, Riccardo Rossi, et al.
Environmental Science & Technology (2021) Vol. 55, Iss. 15, pp. 10769-10783
Closed Access | Times Cited: 41
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