Journal Publications

18. A.A. Bakır, R. Atik, S. Özerinç, Mechanical properties of thermoplastic parts produced by fused deposition modeling: a review, Rapid Prototyping Journal, available online (2021).

17. E. Sonat, S. Özerinç, Failure Behavior of Scarf-Bonded Woven Fabric CFRP Laminates, Composite Structures, 258, 113205 (2021).

16. A. A. Bakır, R. Atik, S. Özerinç, Effect of fused deposition modeling process parameters on the mechanical properties of recycled polyethylene terephthalate parts, Journal of Applied Polymer Science, 138, 49709 (2021).

15. B. Kaygusuz, S. Özerinç, Improving the Ductility of PLA Parts Produced by Fused Deposition Modeling through PHA Additions, Journal of Applied Polymer Science 136, 48154 (2019).

14. S. Özerinç, Experimental measurements of interfacial strength at the nanoscale, Journal of the Faculty of Engineering and Architecture of Gazi University 34, 1645-1652 (2019).

13. M. Abboud, S. Özerinç, Size-independent strength of amorphous-HCP crystalline metallic nanolayers, Journal of Materials Research 34, 2275-2284 (2019).

12. J. Pikul, S. Özerinç, B. Liu, R. Zhang, P. Braun, V. Deshpande, W.P. King, High strength metallic wood from nanostructured nickel inverse opal materials, Scientific Reports 9, 719 (2019).

11. F. Sıkan, S.E. Atabay, A. Motallebzadeh, S. Özerinç, İ. Kalay, E. Kalay, Effect of Sm on Thermal and Mechanical Properties of Cu-Zr-Al Bulk Metallic Glasses, Materials Science & Engineering: A 743, 168-174 (2019).

10. M. Abboud, A. Motallebzadeh, N. Verma, S. Özerinç, Nanoscratch behavior of metallic glass-crystalline nanolayered composites, JOM 71, 593-601 (2019).

9. S. Özerinç, Finite element analysis of nanoindentation on nanolaminated materials, Eskişehir Technical University Journal of Science and Technology A - Applied Sciences and Engineering 19, 991-1000 (2018).

8. B. Kaygusuz, S. Özerinç, Investigation of the mechanical properties of 3D printed PLA-based structures, MATİM Journal 16, 1-6 (2018).

7. S. Özerinç, R.S. Averback & W.P. King, In situ Measurements of Irradiation-Induced Creep of Nanocrystalline Copper at Elevated Temperatures, Journal of the Minerals, metals, and Materials Society, 68, 2737 (2016).

6. S. Özerinç, H.J. Kim, R.S. Averback, W.P. King, Direct measurements of irradiation-induced creep in micropillars of amorphous Cu56Ti38Ag6, Zr52Ni48, Si and SiO2, Journal of Applied Physics, 117, 024310 (2015).

5. S. Mao, S. Özerinç, W.P. King, R.S. Averback, S.J. Dillon, Effect of irradiation damage on the shear strength of Cu-Nb interfaces, Scripta Materialia 90-91, 29-32 (2014).

4. S. Özerinç, R.S. Averback, W.P. King, In situ creep measurements on micropillar samples during heavy ion irradiation, Journal of Nuclear Materials 451, 104-110 (2014).

3. S. Özerinç, K. Tai, N.Q. Vo, P. Bellon, R.S. Averback, W.P. King, Grain boundary doping strengthens nanocrystalline copper alloys, Scripta Materialia 67, 720-723 (2012).

2. S. Özerinç, A.G. Yazıcıoğlu, S. Kakaç, Numerical analysis of laminar forced convection with temperature-dependent thermal conductivity of nanofluids and thermal dispersion, International Journal of Thermal Sciences 62, 138–148 (2012).

1. S. Özerinç, S. Kakaç, A.G. Yazıcıoğlu, Enhanced thermal conductivity of nanofluids: A state-of-the-art review, Microfluidics and Nanofluidics 8, 145-170 (2010).

Last Updated:
09/02/2021 - 07:31