Dr. Sutrasno Kartohardjono
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Dr. Sutrasno Kartohardjono

Professor
Universitas Indonesia, Indonesia

Highest Degree
Ph.D. in Chemical Engineering from University of New South Wales, Australia

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Biography

Dr. Sutrasno Kartohardjono is currently working as Head of Chemical Engineering Department Universitas Indonesia. He obtained his Ph.D. in Chemical Engineering from same University. His main area of interest related to Membrane Contactor for Gas-Liquid or Liquid-Liquid Processes. His area of expertise includes Membrane, Contactor, CO2 Removal, Ammonia Removal, Gas Separation, Natural Gas Processing, Dissolve Oxygen Removal, and Gas Dehydration. He has published 21 research articles in journals as author/co-author.

Area of Interest:

Engineering
100%
Membrane
62%
Ammonia Removal
90%
Gas Separation
75%
Natural Gas Processing
55%

Research Publications in Numbers

Books
0
Chapters
0
Articles
0
Abstracts
0

Selected Publications

  1. Kartohardjono, S., K.A. Sembiring, Rexy, R. Syandika, F. Ghasani and N. Saksono, 2017. CO2 absorption from its mixture through super-hydrophobic membrane contactor. J. Environ. Sci. Technol., 10: 25-34.
    CrossRef  |  Direct Link  |  
  2. Hatijah, B., M. Irfan, M. Irfan, W.J. Lau & S. Kartohardjono, 2017. Quantitative analysis of MWCNT agglomeration in polymeric- based membranes using atomic force microscope. Surf. Interface Anal., 49: 55-62.
    CrossRef  |  Direct Link  |  
  3. Saksono, N., S. Kartohardjono and T. Yuniawati, 2016. High performance plasma electrolysis reactor for hydrogen generation using a NaOH-methanol solution. Int. J. Tech., 7: 1421-1429.
    CrossRef  |  Direct Link  |  
  4. Mokhtar, N.M., W.J. Lau, A.F. Ismail, S. Kartohardjono and S.O. Lai et al., 2016. The potential of direct contact membrane distillation for industrial textile wastewater treatment using PVDF-Cloisite 15A nanocomposite membrane. Chem. Eng. Res. Design, 111: 284-293.
    Direct Link  |  
  5. Mohammed Ali, B., N. Suwartha, E. Kusrini, , S. Kartohardjono and M. Suryanegara et al ., 2016. Accelerating Technology Development: Engaging Stakeholders and International Networking J. Tech., 7: 1128-1131.
    CrossRef  |  Direct Link  |  
  6. Kartohardjono, S., R. Darmawan, M.F. Karyadi and N. Saksono, 2016. CO2 absorption through super-hydrophobic hollow fiber membrane contactors. J. Environ. Sci. Technol., 9: 214-219.
    CrossRef  |  Direct Link  |  
  7. Yuswan, M., M. Mirza, G. Dinda, and K. Sutrasno, 2015. Simulation of ignition delay time of compressed natural gas combustion. Int. J. Automot. Mech. Eng., 12: 3125-3140.
    Direct Link  |  
  8. Muharam, Y., M. Mahendra, F. Giffari and S. Kartohardjono, 2015. Effects of injection temperature and pressure on combustion in an existing otto engine using CNG fuel J. Environ. Sci. Technol., 8: 25-34.
    CrossRef  |  Direct Link  |  
  9. Kartohardjono, S., M.I. Fermi, Y. Yuliusman, K. Elkardiana and A.P. Sangaji, et al ., 2015. The Removal of Dissolved Ammonia from Wastewater through a Polypropylene Hollow Fiber Membrane Contactor. Int. J. Tech., 7: 1146-1152.
    CrossRef  |  
  10. Kartohardjono, S., G.M. Damaiati and C.T. Rama, 2015. Effects of absorbents on ammonia removal from wastewater through hollow fiber membrane contactor. J. Environ. Sci. Technol., 8: 225-231.
    Direct Link  |  
  11. Pereira, C., S.A. Handaya and K. Sutrasno, 2014. Thermodynamic analysis for liquefaction of natural gas using the C3-MR refrigeration process. Int. J. Chem. Eng. Applic., 5: 17-22.
    Direct Link  |  
  12. Saksono, N., S.B.F. Abqari and S. Kartohardjono, 2013. Effect of process condition in plasma electrolysis of chloralkali production. Int. J. Chem. Eng. Applic., 4: 266-270.
  13. Saksono, N., B.P. Adiwidodo, E.F. Karamah and S. Kartohardjono, 2013. Contact glow discharge electrolysis system for treatment of wastewater containing ammonia. J. Environ. Sci. Technol., 6: 41-49.
    Direct Link  |  
  14. Kartohardjono, S., P.L. Handayani, S. Deflin, Y. Nuraeni and B. Setijo, 2012. Ammonia removal from wastewater throughcombination of absorption process in the membranecontactor and advance oxydation process in HybridePlasma-ozone reactor. J. Environ. Sci. Eng., 1: 1101-1107.
    Direct Link  |  
  15. Kartohardjono, S., M.H. Putri, S. Fahmiati, E. Fitriasari, C. Ajeng and S. Bismo, 2012. Combination of ozonation process and absorption through membrane contactor using natural hot spring water as absorbent to remove ammonia from wastewater. J. Environ. Sci. Engin. A, 1: 428-433.
    Direct Link  |  
  16. Kartohardjono, S., Yuliusman and D.S. Budhie, 2011. Preliminary studies on the selective absorption of CO2 from CH4 through hollow fiber membrane contactor using aqueous extract of noni fruit (Morinda Citrifolia). Int. J. Technol., 2: 247-255.
  17. Kartohardjono, S., A. Rabekka and S. Bismo, 2011. Combination vacuum and sweep gas processes to remove dissolved oxygen from water through hollow fiber membrane contactors. J. Mater. Sci. Eng., 1: 62-68.
  18. Kartohardjono, S., P.A. Nata, E. Prasetio and Yuliusman, 2009. Performance of hollow fiber membrane gas-liquid contactor to absorb CO2 using diethanolamine (DEA). J. Makara Seri Teknol., 13: 86-90.
  19. Bismo, S., S. Kartohardjono, N. Saksono, E.F. Karamah and A. Rahardjo, 2008. Some aspects of lake water treatment to produce clean water using integration processes of adsorption. Filtrat. Ozonat. World Applied Sci. J., 7: 472-478.
  20. Kartohardjono, S., 2006. Mass transfer model in sealed end hydrophobic microporous (Polypropylene) hollow fiber membrane Gas-liquid contactor. J. Teknol., 20: 143-150.
  21. Kartohardjono, S. and V. Chen, 2005. Mass transfer and fluid hydrodynamics in sealed end hydrophobic hollow fiber membrane gas-liquid contactors. J. Applied Membrane Sci. Technol., 2: 1-12.