Ich Long Ngo | Computational Methods | Research Excellence Award

Published on by Physicist Particle

Research Excellence Award

Ich Long Ngo
Ich Long Ngo
Affiliation Hanoi University of Science and Technology
Country Vietnam
Scopus ID 56465015200
Documents 38
Citations 941
h-index 18
Subject Area Computational Methods
Event Global Particle Physics Excellence Awards

Ich Long Ngo is a Vietnamese researcher and associate professor affiliated with Hanoi University of Science and Technology. His academic work primarily focuses on computational methods, heat transfer engineering, thermal conductivity enhancement, microfluidics, electrohydrodynamic systems, and polymer composite materials. His publication portfolio includes contributions to internationally indexed journals in thermal sciences, fluid mechanics, and mechanical engineering.[1] His research activities also encompass electro-conjugate fluid micropumps, geothermal management systems, and computational optimization for engineering applications.[2]

Abstract

The Research Excellence Award recognition for Ich Long Ngo reflects his sustained scholarly contributions in computational methods and thermal-fluid engineering. His academic output includes investigations into polymer composites, microfluidic systems, electrohydrodynamic micropumps, and thermal conductivity optimization. Through computational modeling, numerical simulations, and engineering experimentation, his work has contributed to the development of predictive correlations and optimized engineering designs for thermal management and fluid dynamics systems.[3] His publication record demonstrates interdisciplinary engagement across mechanical engineering, computational fluid dynamics, and materials science.[4]

Keywords

Computational Methods, Thermal Conductivity, Microfluidics, Electrohydrodynamic Systems, Heat Transfer, Polymer Composites, Fluid Engineering, Thermal Sciences, Mechanical Engineering, Numerical Simulation

Introduction

Computational engineering methods have become central to modern developments in heat transfer, energy systems, and microfluidic technologies. Researchers working in this field contribute to both theoretical modeling and practical engineering optimization. Ich Long Ngo has developed research activities that combine finite element analysis, numerical simulation, and experimental validation to investigate thermal conductivity enhancement, electro-conjugate fluid systems, and fluidic transport phenomena.[5]

His research has been published in journals including Physics of Fluids, International Journal of Heat and Mass Transfer, Applied Thermal Engineering, and Journal of Fluids Engineering. These studies contribute to understanding the transport behavior of fluids, optimization of composite materials, and development of engineering correlations applicable to industrial and energy systems.[6]

Research Profile

According to ORCID and Scopus records, Ich Long Ngo has served as Associate Professor and Senior Lecturer in Mechanical Engineering at Hanoi University of Science and Technology since 2009.[7] He obtained his Doctor of Philosophy degree in Mechanical Engineering from Yeungnam University, Republic of Korea, and completed his Master of Science degree at Changwon National University.[8]

His research profile includes publications addressing heat transfer optimization, polymer composite conductivity, microfluidic droplet formation, electro-conjugate fluid micropumps, and geothermal engineering systems. His interdisciplinary approach integrates computational analysis with experimentally validated engineering methodologies.[9]

  • Associate Professor at Hanoi University of Science and Technology
  • Research specialization in thermal-fluid engineering and computational methods
  • Author and co-author of peer-reviewed engineering publications
  • Contributor to electro-conjugate fluid micropump research initiatives
  • Active participant in computational heat transfer and microfluidic studies

Research Contributions

A major component of Ngo’s research contributions involves predictive modeling for thermal conductivity enhancement in heterogeneous composite systems. His studies developed generalized correlations and numerical models for polymer composites reinforced with hybrid fillers and nanofillers.[10]

His investigations into electro-conjugate fluid micropumps and microfluidic devices contributed to understanding flow optimization and electrode geometries for electrohydrodynamic applications.[11] These studies explored fluidic performance enhancement using hydrodynamic-shaped electrodes and computational optimization strategies.

Ngo has also contributed to geothermal management systems and LED thermal management applications through computational and experimental approaches.[12] His work on generalized engineering correlations supports engineering prediction methodologies applicable to thermal sciences and heat transfer analysis.

  • Thermal conductivity prediction models for polymer composites
  • Microfluidic droplet dynamics and flow-focusing systems
  • Electro-conjugate fluid micropump optimization
  • Finite element analysis for thermal management systems
  • Computational fluid dynamics and wake transition studies
  • Geothermal heat exchanger design optimization

Publications

Selected publications associated with Ich Long Ngo include peer-reviewed journal articles in thermal sciences, fluid engineering, and computational modeling.[13]

  1. “A Comprehensive Study on Improving the Electrohydrodynamic Performance of Electroconjugate Fluid Micropumps Using Hydrodynamic-Shaped Electrodes.” Journal of Fluids Engineering (2026).
    DOI: https://doi.org/10.1115/1.4070397
  2. “Achieving High Power and Energy Efficiency for Microfluidic Fuel Cells with Flow-through Porous Electrodes.” International Journal of Precision Engineering and Manufacturing-Green Technology (2026).
    DOI: https://doi.org/10.1007/s40684-025-00822-0
  3. “A generalized correlation for predicting microdroplet sizes in a squeezer T-junction microfluidic device.” Physics of Fluids (2025).
    DOI: https://doi.org/10.1063/5.0294584
  4. “A new design of electro-conjugate fluid micropumps with Venturi and teardrop-shaped electrodes.” Physics of Fluids (2024).
    DOI: https://doi.org/10.1063/5.0221203
  5. “Experimental study on thermal management of surface mount device–LED chips.” Applied Thermal Engineering (2023).
    DOI: https://doi.org/10.1016/j.applthermaleng.2022.119846

Research Impact

The scholarly impact of Ich Long Ngo’s work is reflected through citations, journal visibility, and interdisciplinary collaboration in computational engineering and thermal sciences.[14] His studies on thermal conductivity prediction models and electrohydrodynamic systems contribute to ongoing research in efficient thermal management and microfluidic optimization.

His publications have appeared in internationally recognized engineering journals, supporting academic discussions in heat transfer engineering, polymer composites, and fluid mechanics.[15] His contributions to computational analysis and predictive correlations continue to support engineering modeling methodologies in applied sciences.

Award Suitability

Ich Long Ngo’s research profile demonstrates sustained engagement in computational methods and thermal-fluid engineering research. His publication record, interdisciplinary research activities, and contributions to numerical modeling align with the objectives commonly associated with research excellence recognition programs.[16]

The combination of experimental and computational methodologies present in his work illustrates academic contributions relevant to energy systems, microfluidic technologies, and thermal management engineering. These characteristics support consideration for professional recognition within computational engineering and applied mechanics disciplines.

Conclusion

Ich Long Ngo has contributed to research areas involving computational methods, thermal sciences, and fluid engineering through publications addressing thermal conductivity enhancement, microfluidics, and electro-conjugate fluid systems. His academic activities at Hanoi University of Science and Technology and his publication portfolio in international engineering journals demonstrate continued participation in computational and applied engineering research.[17]

References

  1. Elsevier. (n.d.). Scopus author details: Ich Long Ngo, Author ID 56465015200. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=56465015200
  2. ORCID. (n.d.). Ich Long Ngo ORCID Profile.
    https://orcid.org/0000-0003-2406-5725
  3. Ngo, I.L., et al. (2026). A Comprehensive Study on Improving the Electrohydrodynamic Performance of Electroconjugate Fluid Micropumps Using Hydrodynamic-Shaped Electrodes. Journal of Fluids Engineering.
    https://doi.org/10.1115/1.4070397
  4. Ngo, I.L., et al. (2026). Achieving High Power and Energy Efficiency for Microfluidic Fuel Cells with Flow-through Porous Electrodes.
    https://doi.org/10.1007/s40684-025-00822-0
  5. Ngo, I.L., et al. (2025). A generalized correlation for predicting microdroplet sizes in a squeezer T-junction microfluidic device. Physics of Fluids.
    https://doi.org/10.1063/5.0294584
  6. Ngo, I.L., et al. (2024). A new design of electro-conjugate fluid micropumps with Venturi and teardrop-shaped electrodes. Physics of Fluids.
    https://doi.org/10.1063/5.0221203
  7. ORCID. (n.d.). Employment details of Ich Long Ngo.
    https://orcid.org/0000-0003-2406-5725
  8. ORCID. (n.d.). Education and qualifications of Ich Long Ngo.
    https://orcid.org/0000-0003-2406-5725
  9. Elsevier. (n.d.). Research publications and citation profile.
    https://www.scopus.com/authid/detail.uri?authorId=56465015200
  10. Ngo, I.L.; Byon, C. (2019). An investigation on effective thermal conductivity of hybrid-filler polymer composites.
    https://doi.org/10.1016/j.ijheatmasstransfer.2019.118605
  11. Ngo, I.L.; Lai, T.K. (2026). Electroconjugate fluid micropump optimization research.
    https://doi.org/10.1115/1.4070397
  12. Ngo, I.L.; Ngo, V.H. (2022). A new design of ground heat exchanger with insulation plate for effectively geothermal management.
    https://doi.org/10.1016/j.geothermics.2022.102512
  13. Elsevier and Crossref indexed journal publications associated with Ich Long Ngo.
    https://www.scopus.com/authid/detail.uri?authorId=56465015200
  14. Scopus Preview. (2026). Citation metrics and scholarly indicators.
    https://www.scopus.com/authid/detail.uri?authorId=56465015200
  15. ORCID and Crossref publication metadata records.
    https://orcid.org/0000-0003-2406-5725
  16. Global Tech Excellence. (2026). Global Particle Physics Excellence Awards.

    Global Tech Excellence Awards


  17. Compiled academic profile data from Scopus and ORCID records for Ich Long Ngo.
    https://orcid.org/0000-0003-2406-5725

Abeer Aly | Computational Methods | Best Researcher Award

Published on by Physicist Particle

Dr. Abeer Aly | Computational Methods | Best Researcher Award

Dr. abeer aly, higher canal institute of engineering and technology, Egypt

Dr. abeer aly is a seasoned academic and researcher with a Ph.D. in Theoretical Physics from Mansoura University, Egypt. With extensive teaching and administrative experience, she has held pivotal roles in various higher education institutions. Her research interests lie in the computational analysis of electronic and magnetic material properties, and she has significantly contributed to solid-state physics and theoretical modeling. Currently, she is affiliated with the Higher Technological Institute, New Heliopolis, where she continues her academic and research endeavors.

PROFILE

Scopus  Profile

Orcid Profile 

Google Scholar profile

Educational Detail

Dr. abeer aly earned her Ph.D. in Physics (Theoretical Physics) from Mansoura University at Damietta in 2010, with a thesis focusing on Ab initio calculation of electronic and magnetic properties of RCo5 compounds. She completed her M.Sc. in Solid-State Physics in 2005 from Helwan University, where her research explored the electronic structure of materials using energy band calculation methods. Her academic journey began with a B.Sc. in Computer Science and Physics in 2000 from Helwan University, where she achieved an excellent grade in her graduation project on magnetic properties and database systems.

Professional Experience

Dr. abeer aly has over two decades of experience in academia, spanning teaching, research, and administrative roles. Currently, she serves at the Higher Technological Institute, New Heliopolis, Cairo. She previously held positions at the Higher Institute of Engineering, Automotive and Energy Technology, and the Higher Institute of Engineering and Technology. Notably, she served as Head of the Basic Science Department at El-Salam Institute (2018–2022) and contributed as a lecturer at several institutions, including October 6 University, El-Shorouk Academy, and Arab Open University.

Dr. aly has also excelled in administrative roles, such as Editorial Manager of a scientific journal and Head of Faculty Affairs for Scientific Research at Modern Academy. She has experience in curriculum coordination and department leadership, particularly in physics, mathematics, and computer science.

Research Interest

Dr. abeer aly’s research focuses on the theoretical analysis of electronic and magnetic properties of materials, particularly using ab initio and energy band calculation methods. Her work delves into the study of solid-state physics, magnetism, and the computational modeling of material properties, contributing to advancements in material science and theoretical physics.

Top Notable Publications

Structural, Electronic, and Mechanical Insights into Rb₂B’AgBr₆ (B’ = Ga, Al, In) Double Perovskites: Pathways to Lead-Free Optoelectronics

Authors: Gil Rebaza, A.V., Shankar, A., Aly, A.E.

Journal: Chemical Physics, Year: 2025, Volume: 591, Article: 112565

Citations: 0

Study of the Mechanical Properties of OsS₂ and Its Enhanced Optoelectronic Performance under Fe/Ru Doping

Authors: Thapa, B., Shankar, A., Aly, A.E., Patra, P.K.

Journal: Computational and Theoretical Chemistry, Year: 2024, Volume: 1233, Article: 114496

Citations: 0

Modulation of the Optoelectronic Properties of CdSe₂

Authors: Thapa, B., Patra, P.K., Aly, A.E., Das, M., Shankar, A.

Journal: Computational Condensed Matter, Year: 2022, Volume: 33, Article: e00745

Citations: 0

Experimental and Theoretical Investigation of Electronic and Optical Properties of CuAlₓGa₁₋ₓTe₂

Authors: Kassaa, A., Benslim, N., Otmani, A., Shankar, A., Aly, A.E.

Journal: Chemical Physics Letters, Year: 2022, Volume: 807, Article: 140086

Citations: 0

Magnetic and Optical Properties of Perovskite-Graphene Nanocomposites LaFeO₃-rGO: Experimental and DFT Calculations

Authors: Abdel-Aal, S.K., Aly, A.E., Chanduví, H.H.M., Atteia, E., Shankar, A.

Journal: Chemical Physics, Year: 2020, Volume: 538, Article: 110874

Citations: 21

Half-Metallicity in New Heusler Alloys Mn₂ScZ (Z = Si, Ge, Sn)

Authors: Ram, M., Saxena, A., Aly, A.E., Shankar, A.

Journal: RSC Advances, Year: 2020, Volume: 10(13), Pages: 7661–7670

Citations: 61

Study of Half-Metallicity, Structural and Mechanical Properties in Inverse Heusler Alloy Mn₂ZnSi₁₋ₓGeₓ and a Superlattice

Authors: Ram, M., Saxena, A., Aly, A.E., Shankar, A.

Journal: RSC Advances, Year: 2019, Volume: 9(63), Pages: 36680–36689

Citations: 9

Electronic and Piezoelectric Properties of Half-Heusler Compounds: A First Principles Study

Authors: Rai, D.P., Sandeep, Shankar, A., Patra, P.K., Thapa, R.K.

Journal: Journal of Physics: Conference Series, Year: 2016, Volume: 765(1), Article: 012005

Citations: 14

Electronic Band Structure and Spin-Density Maps of SmCo₅

Authors: Yehia, S., Aly, S.H., Aly, A.E.

Journal: Computational Materials Science, Year: 2008, Volume: 41(4), Pages: 482–485

Citations: 13

Conclusion

Dr. Abeer Aly’s strong academic background, extensive research contributions, and leadership experience position her as a highly suitable candidate for the Research for Best Researcher Award. Her expertise in computational and theoretical physics, combined with her dedication to academic and administrative excellence, align perfectly with the award’s criteria.