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Adnan Darwish Ahmad | Stanley and Karen Pigman College of Engineering Skip to main
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Adnan received his Ph.D. in mechanical engineering from the University of Kentucky in 2021, where he joined the Institute of Research for Technology Development (IR4TD) as a research associate. At IR4TD, Adnan has worked on projects including lean research and optimizations through artificial intelligence (AI), atomization and coatings for automotive and other industries, renewable energy and power cycle modeling, and wildland fire research. He became True-Lean certified in 2019 and has assisted in running the lean systems laboratory since. In addition to his training at UK, Adnan received rigorous lean trainings at Toyota Motor Manufacturing Kentucky (TMMK), where he had the chance to implement the lean principles he learned, including 5S, standardization, 8-step problem-solving and Kaizen at IR4TD. Currently, he serves the role of technology transfer manager at the True lean program, collaborating with a team of lean researchers to develop an AI-based code that will function as the future predictive tool to forecast the lean implementation impact on the sustainability of US manufacturing businesses.

Education

Ph.D., University of Kentucky, Lexington, Kentucky, 2021

M.Sc, University of Kentucky, Lexington, Kentucky, 2020

B.Sc, University of Jordan, Amman, Jordan, 2015

Publications Selected Articles

  1. Al-Ghussain, L., Darwish Ahmad, A., Abubaker, A. M., & Hassan, M. A. (2022). Exploring the feasibility of green hydrogen production using excess energy from a country-scale 100% solar-wind renewable energy system. International Journal of Hydrogen Energy.
  2. Al-Ghussain, L., Darwish Ahmad, A., Abubaker, A. M., & Hassan, M. A. (2022). Techno-economic feasibility of thermal storage systems for the transition to 100% renewable grids. Renewable Energy.
  3. Hassan, M.A., Al-Ghussain, L., Darwish Ahmad, A., Abubaker, A. M. Khalil, A. (2022). Aggregated independent forecasters of half-hourly global horizontal irradiance. Renewable Energy
  4. Abubaker, A.M., Darwish Ahmad, A., Salaimeh, A., Akafuah, N. K., and Saito, K. (2022). A novel solar combined cycle integration: An exergy-based optimization using artificial neural network. Renewable Energy
  5. Darwish Ahmad, A., Abubaker, A. M., Salaimeh, A., Akafuah, N. K., Finney, M., Forthofer, J. M., & Saito, K. (2021). Ignition and burning mechanisms of live spruce needles. Fuel, 304, 121371.
  6. Abubaker, A. M., Darwish Ahmad, A., Singh, B. B., Akafuah, N. K., & Saito, K. (2021). Multi-objective linear-regression-based optimization of a hybrid solar-gas turbine combined cycle with absorption inlet-air cooling unit. Energy Conversion and Management, 240, 114266.
  7. Al-Ghussain, L., Darwish Ahmad, A., Abubaker, A. M., Abujubbeh, M., Almalaq, A., & Mohamed, M. A. (2021). A Demand-Supply Matching-Based Approach for Mapping Renewable Resources Towards 100% Renewable Grids in 2050. IEEE Access, 9, 58634-5865.
  8. Al-Ghussain, L., Darwish Ahmad, A., Abubaker, A. M., & Mohamed, M. A. (2021). An integrated photovoltaic/wind/biomass and hybrid energy storage systems towards 100% renewable energy microgrids in university campuses. Sustainable Energy Technologies and Assessments, 46, 101273.
  9. Al-Ghussain, L., Abubaker, A. M., & Darwish Ahmad, A. (2021). Superposition of Renewable-Energy Supply from Multiple Sites Maximizes Demand-Matching: Towards 100% Renewable Grids in 2050. Applied Energy, 284, 116402.
  10. Darwish Ahmad, A., Abubaker, A. M., Najjar, Y. S., Manaserh, Y. M.A., & (2020). Power boosting of a combined cycle power plant in Jordan: An integration of hybrid inlet cooling and solar systems. Energy Conversion and management, 214C, 112894.








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