Shalan Alkarni

434 total citations
38 papers, 341 citations indexed

About

Shalan Alkarni is a scholar working on Biomedical Engineering, Computational Mechanics and Mechanical Engineering. According to data from OpenAlex, Shalan Alkarni has authored 38 papers receiving a total of 341 indexed citations (citations by other indexed papers that have themselves been cited), including 28 papers in Biomedical Engineering, 20 papers in Computational Mechanics and 19 papers in Mechanical Engineering. Recurrent topics in Shalan Alkarni's work include Nanofluid Flow and Heat Transfer (28 papers), Fluid Dynamics and Turbulent Flows (16 papers) and Heat Transfer Mechanisms (16 papers). Shalan Alkarni is often cited by papers focused on Nanofluid Flow and Heat Transfer (28 papers), Fluid Dynamics and Turbulent Flows (16 papers) and Heat Transfer Mechanisms (16 papers). Shalan Alkarni collaborates with scholars based in Saudi Arabia, Pakistan and South Korea. Shalan Alkarni's co-authors include Nehad Ali Shah, Nehad Ali Shah, Mansoor H. Alshehri, Abderrahim Wakif, Sayed M. Eldin, Jamshad Ahmad, Sonia Akram, Jae Dong Chung, M. Faizan and Aurang Zaib and has published in prestigious journals such as Energies, Chaos Solitons & Fractals and The European Physical Journal C.

In The Last Decade

Shalan Alkarni

30 papers receiving 317 citations

Peers

Shalan Alkarni

SNP

Amnah S. Al‐Johani Saudi Arabia

H. Ashraf Pakistan

J. B. Aarseth Norway

C.B. Baxi United States

Liliana Restuccia Italy

O. P. Chandna Canada

S. Grohmann Germany

Haibiao Zheng China

J. Patrick Kelley United States

Hassan Akhlaghi Iran

Amnah S. Al‐Johani Saudi Arabia

Shalan Alkarni

238 ×1.1

188 ×1.1

172 ×1.2

31 ×0.5

SNP

31 ×1.2

Citations per year, relative to Shalan Alkarni Shalan Alkarni (= 1×) peers Amnah S. Al‐Johani

Countries citing papers authored by Shalan Alkarni

Since Specialization

Citations

This map shows the geographic impact of Shalan Alkarni's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by Shalan Alkarni with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Shalan Alkarni more than expected).

Fields of papers citing papers by Shalan Alkarni

Since Specialization

Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Shalan Alkarni. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by Shalan Alkarni. The network helps show where Shalan Alkarni may publish in the future.

Co-authorship network of co-authors of Shalan Alkarni

This figure shows the co-authorship network connecting the top 25 collaborators of Shalan Alkarni. A scholar is included among the top collaborators of Shalan Alkarni based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with Shalan Alkarni. Shalan Alkarni is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

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20 of 20 papers shown

Ullah, Zia, et al.. (2025). Radiative heat and mass transfer of second-grade nanofluid slip flow with variable thermal properties. AIP Advances. 15(3).

Shatnawi, Taqi A. M., Aamir Khan, Sajjad Hussain, & Shalan Alkarni. (2025). Numerical simulation for magnetized non-isothermal nanofluid flow in hexagonal curved cavity with heated obstacle. Chaos Solitons & Fractals. 201. 117265–117265.

Yousaf, Z., et al.. (2025). Role of electromagnetic fields and Gauss–Bonnet gravity in the development of inhomogeneities in collapsing fluids. Physics of the Dark Universe. 49. 102058–102058.

Mustafa, G., Faisal Javed, S. K. Maurya, et al.. (2024). Joule-Thomson expansion, motion of particles and QPOs around Bardeen-AdS black hole immersed in a fluid of strings. Journal of High Energy Astrophysics. 44. 437–456. 15 indexed citations

Ramzan, Muhammad, et al.. (2024). Influence of inclined magnetic field and surface catalyzed reactions on a ternary hybrid nanofluid rotating flow with irreversibility analysis. ZAMM ‐ Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik. 104(11). 2 indexed citations

Alkarni, Shalan, et al.. (2024). Machine learning approach of Casson hybrid nanofluid flow over a heated stretching surface. AIMS Mathematics. 9(7). 18746–18762. 7 indexed citations

Shah, Nehad Ali, Dumitru Vieru, Constantin Fetecău, & Shalan Alkarni. (2024). Exact solutions to vorticity of the fractional nonuniform Poiseuille flows. Open Physics. 22(1). 1 indexed citations

Panda, Subhajit, et al.. (2024). Improving heat transfer efficiency via optimization and sensitivity assessment in hybrid nanofluid flow with variable magnetism using the Yamada–Ota model. Open Physics. 22(1). 4 indexed citations

Li, Shuguang, Nazia Shahmir, Muhammad Ramzan, Shalan Alkarni, & Seifedine Kadry. (2024). Analyzing variable characteristics effects on an unsteady hybrid nanofluid flow over a rotating sphere near a stagnation point with thermal stratification — A comparative study. Modern Physics Letters B. 39(20).

10.

Javed, Faisal, et al.. (2024). Particle motion and thermal fluctuations of charged AdS black holes surrounded by exotic fluid with modified Chaplygin equation of state. Physics of the Dark Universe. 47. 101723–101723. 5 indexed citations

11.

Ullah, Zia, et al.. (2024). Thermally and chemically reactive boundary layer flow past a wedge moving in a nanofluid with activation energy and thermophoretic diffusion effects. AIP Advances. 14(10). 7 indexed citations

12.

Ahmad, Shafiq, et al.. (2024). Novel insight of thermal radiation and slip boundary condition on the micropolar ternary hybrid nanofluid flow over an oblique stagnation region of a lubricated surface. Modern Physics Letters B. 39(23). 2 indexed citations

13.

Gul, M. Zeeshan, Faisal Javed, M. Sharif, & Shalan Alkarni. (2024). Exploring the viability of charged spheres admitting non-metricity and matter source. The European Physical Journal C. 84(11). 6 indexed citations

14.

Sahoo, Rajesh Kumar, S. R. Mishra, Shalan Alkarni, & Nehad Ali Shah. (2024). Characteristics of induced magnetic field on the time-dependent MHD nanofluid flow through parallel plates. Nanotechnology Reviews. 13(1). 2 indexed citations

15.

Ullah, Zia, et al.. (2024). Consequences of thermal conductivity and thermal density on heat and mass transfer in the nanofluid boundary layer flow toward a stretching sheet in the presence of a magnetic field. AIP Advances. 14(10). 5 indexed citations

16.

Ullah, Zia, et al.. (2024). Analysis of activation energy, chemical reaction, and variable density on magnetically driven heat transportation: Applications in nanofluid lubrication and machining. AIP Advances. 14(10). 3 indexed citations

17.

Srilatha, Pudhari, et al.. (2023). A Free Convective Two-Phase Flow of Optically Thick Radiative Ternary Hybrid Nanofluid in an Inclined Symmetrical Channel through a Porous Medium. Symmetry. 15(8). 1615–1615. 11 indexed citations

18.

Hanumagowda, B. N., et al.. (2023). The Onset of Darcy–Brinkman Convection in a Porous Layer with Mutual Impact of Thermal Non-Equilibrium and Non-Uniform Temperature Gradients. Symmetry. 15(9). 1695–1695. 1 indexed citations

19.

Hanumagowda, B. N., Pudhari Srilatha, S. V. K. Varma, et al.. (2023). A Thermal Analysis of a Convective–Radiative Porous Annular Fin Wetted in a Ternary Nanofluid Exposed to Heat Generation under the Influence of a Magnetic Field. Energies. 16(17). 6155–6155. 6 indexed citations

20.

Chandan, K., et al.. (2023). Analysis of Heat Transfer Behavior of Porous Wavy Fin with Radiation and Convection by Using a Machine Learning Technique. Symmetry. 15(8). 1601–1601. 34 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

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