Effect of particle size on SiO2 nanofluid viscosity determined by a two-step method Article Swipe
Gökberk Yalçın
,
Semiha Öztuna
,
Ahmet Selim Dalkılıç
,
Somchai Wongwises
·
YOU?
·
· 2024
· Open Access
·
· DOI: https://doi.org/10.1007/s10973-024-13403-1
YOU?
·
· 2024
· Open Access
·
· DOI: https://doi.org/10.1007/s10973-024-13403-1
According to review of the literature, the influence of nanoparticle diameter with irregular shapes on viscosity requires further research since there is no relation between particle size and nanofluid stability. In this study, SiO 2 /EG–water-based nanofluid samples were prepared, and their viscosities were experimentally determined. SiO 2 nanoparticles had sizes of 7, 15, and 40 nm, and the base fluid was a 50% ethylene glycol and 50% water mixture. Nanofluid samples were prepared using a two-step technique. Viscosity change was measured every 10 °C from 20 to 60 °C. The maximum viscosity values were observed for 7, 15, and 40 nm particles over an entire concentration range. Considering all measurements, the highest viscosity increase was 60.51% for 3% SiO 2 (7 nm) at 60 °C, and the lowest viscosity change was 7.72% for 1% SiO 2 (40 nm) at 40 °C. The most stable sample of the current study was 1% SiO 2 (15 nm), and its Zeta potential was − 35.6 mV. Finally, a new empirical equation that included temperature, particle diameter, and concentration terms is suggested to predict dynamic viscosity, with R adj 2 = 0.98. It was also compared with previous correlations.
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Metadata
- Type
- article
- Language
- en
- Landing Page
- https://doi.org/10.1007/s10973-024-13403-1
- OA Status
- hybrid
- Cited By
- 4
- References
- 59
- Related Works
- 10
- OpenAlex ID
- https://openalex.org/W4402167812
All OpenAlex metadata
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https://openalex.org/W4402167812Canonical identifier for this work in OpenAlex
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https://doi.org/10.1007/s10973-024-13403-1Digital Object Identifier
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Effect of particle size on SiO2 nanofluid viscosity determined by a two-step methodWork title
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articleOpenAlex work type
- Language
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enPrimary language
- Publication year
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2024Year of publication
- Publication date
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2024-09-03Full publication date if available
- Authors
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Gökberk Yalçın, Semiha Öztuna, Ahmet Selim Dalkılıç, Somchai WongwisesList of authors in order
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https://doi.org/10.1007/s10973-024-13403-1Publisher landing page
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hybridOpen access status per OpenAlex
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https://doi.org/10.1007/s10973-024-13403-1Direct OA link when available
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Nanofluid, Viscosity, Particle size, Materials science, Particle (ecology), Chemical engineering, Thermodynamics, Nanoparticle, Nanotechnology, Composite material, Physics, Engineering, Oceanography, GeologyTop concepts (fields/topics) attached by OpenAlex
- Cited by
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4Total citation count in OpenAlex
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2025: 3, 2024: 1Per-year citation counts (last 5 years)
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10Other works algorithmically related by OpenAlex
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| abstract_inverted_index.size | 27 |
| abstract_inverted_index.that | 170 |
| abstract_inverted_index.this | 32 |
| abstract_inverted_index.were | 39, 44, 73, 95 |
| abstract_inverted_index.with | 12, 184, 194 |
| abstract_inverted_index.°C, | 126 |
| abstract_inverted_index.°C. | 90, 142 |
| abstract_inverted_index.0.98. | 189 |
| abstract_inverted_index.7.72% | 133 |
| abstract_inverted_index.every | 83 |
| abstract_inverted_index.fluid | 61 |
| abstract_inverted_index.since | 20 |
| abstract_inverted_index.sizes | 51 |
| abstract_inverted_index.study | 150 |
| abstract_inverted_index.terms | 177 |
| abstract_inverted_index.their | 42 |
| abstract_inverted_index.there | 21 |
| abstract_inverted_index.using | 75 |
| abstract_inverted_index.water | 69 |
| abstract_inverted_index.60.51% | 117 |
| abstract_inverted_index.change | 80, 131 |
| abstract_inverted_index.entire | 106 |
| abstract_inverted_index.glycol | 66 |
| abstract_inverted_index.lowest | 129 |
| abstract_inverted_index.range. | 108 |
| abstract_inverted_index.review | 3 |
| abstract_inverted_index.sample | 146 |
| abstract_inverted_index.shapes | 14 |
| abstract_inverted_index.stable | 145 |
| abstract_inverted_index.study, | 33 |
| abstract_inverted_index.values | 94 |
| abstract_inverted_index.between | 25 |
| abstract_inverted_index.current | 149 |
| abstract_inverted_index.dynamic | 182 |
| abstract_inverted_index.further | 18 |
| abstract_inverted_index.highest | 113 |
| abstract_inverted_index.maximum | 92 |
| abstract_inverted_index.predict | 181 |
| abstract_inverted_index.samples | 38, 72 |
| abstract_inverted_index.Abstract | 0 |
| abstract_inverted_index.Finally, | 165 |
| abstract_inverted_index.compared | 193 |
| abstract_inverted_index.diameter | 11 |
| abstract_inverted_index.equation | 169 |
| abstract_inverted_index.ethylene | 65 |
| abstract_inverted_index.included | 171 |
| abstract_inverted_index.increase | 115 |
| abstract_inverted_index.measured | 82 |
| abstract_inverted_index.mixture. | 70 |
| abstract_inverted_index.observed | 96 |
| abstract_inverted_index.particle | 26, 173 |
| abstract_inverted_index.prepared | 74 |
| abstract_inverted_index.previous | 195 |
| abstract_inverted_index.relation | 24 |
| abstract_inverted_index.requires | 17 |
| abstract_inverted_index.research | 19 |
| abstract_inverted_index.two-step | 77 |
| abstract_inverted_index.According | 1 |
| abstract_inverted_index.Nanofluid | 71 |
| abstract_inverted_index.Viscosity | 79 |
| abstract_inverted_index.diameter, | 174 |
| abstract_inverted_index.empirical | 168 |
| abstract_inverted_index.influence | 8 |
| abstract_inverted_index.irregular | 13 |
| abstract_inverted_index.nanofluid | 29, 37 |
| abstract_inverted_index.particles | 103 |
| abstract_inverted_index.potential | 160 |
| abstract_inverted_index.prepared, | 40 |
| abstract_inverted_index.suggested | 179 |
| abstract_inverted_index.viscosity | 16, 93, 114, 130 |
| abstract_inverted_index.stability. | 30 |
| abstract_inverted_index.technique. | 78 |
| abstract_inverted_index.viscosity, | 183 |
| abstract_inverted_index.Considering | 109 |
| abstract_inverted_index.determined. | 46 |
| abstract_inverted_index.literature, | 6 |
| abstract_inverted_index.viscosities | 43 |
| abstract_inverted_index.nanoparticle | 10 |
| abstract_inverted_index.temperature, | 172 |
| abstract_inverted_index.concentration | 107, 176 |
| abstract_inverted_index.correlations. | 196 |
| abstract_inverted_index.measurements, | 111 |
| abstract_inverted_index.nanoparticles | 49 |
| abstract_inverted_index.experimentally | 45 |
| abstract_inverted_index./EG–water-based | 36 |
| cited_by_percentile_year.max | 97 |
| cited_by_percentile_year.min | 90 |
| countries_distinct_count | 0 |
| institutions_distinct_count | 4 |
| sustainable_development_goals[0].id | https://metadata.un.org/sdg/6 |
| sustainable_development_goals[0].score | 0.8199999928474426 |
| sustainable_development_goals[0].display_name | Clean water and sanitation |
| citation_normalized_percentile.value | 0.74353825 |
| citation_normalized_percentile.is_in_top_1_percent | False |
| citation_normalized_percentile.is_in_top_10_percent | False |