The ISI citation summary for Dr. Gang Feng's journal publications (by 03/19/2015)

Citations in Each Year



Results found: 23 
Sum of the Times Cited : 779
Sum of Times Cited without self-citations : 758
Average Citations per Item : 33.87
h-index : 10

Publication Highlights

Journal Papers (Recent)


1.      Xu, Y., Fleischer, A., and Feng, G., Reinforcing and shape stabilizing of phase-change material via graphene oxide aerogel. Carbon, 2016, In Press.

2.      Jung, J., Qaiser, N., Feng, G., Hwang, B., Kim, T., Han, S., Size-Dependent Hardness of Five-fold Twin Structured Ag Nanowires. Physical Chemistry Chemical Physics, 2016, In Press.

3.      Yu, L., Yan, Z.Y., Yang, H.C., Chai, X.Z., Li, B.Q., Moeendarbari, S., Hao, Y.W., Zhang, D., Feng, G., Han, P., Gilbert, D. A., Liu, K.,Buchanan, K.S., Cheng, X.M., Magnetization Reversal of Nickel Three-Dimensional Anti-sphere Arrays. Nanomagnetics, 2016, Volume PP, 1-4.

4.      Maganosc, D., Feng, G., Yu, L., Cheng, X., and Gianola, D., Isochemical control over structural state and mechanical properties in Pd-based metallic glass by sputter deposition at elevated temperatures. APL Materials, 2016, Volume 4, 086104.



1.      Zhang, D., Zhang, L., Lee, D., Cheng, X., and Feng, G., Reinforcing nanocolloidal crystals by tuning interparticle bonding via atomic layer deposition. Acta Materialia, 2015, Volume 95, 216-223.

2.      Zhang, D., Zhang, L., Lee, D., Cheng, X., and Feng, G., Suppressing unstable deformation of nanocolloidal crystals with atomic layer deposition. Materials Science and Engineering: A, 2015, Volume 639, 514-518.

3.      Zhang, D., Huang, Y.-R., Xu, Y., Lee, D., and Feng, G., Comparing sintering and atomic layer deposition as methods to mechanically reinforce nanocolloidal crystals. Journal of Materials Research, 2015, Volume 30, 3717-3727.

4.      Huang, Y.-R., Jiang, Y., Hor, J. L., Gupta, R., Zhang, L., Stebe, K. J., Feng, G., Turner, K. T., and Lee, D., Polymer nanocomposite films with extremely high nanoparticle loadings via capillary rise infiltration (CARI). Nanoscale, 2015, Volume 7, 798-805.

5.      Cho, Y., Lee, S. Y., Ellerthorpe, L., Feng, G., Lin, G. J., Wu, G. X., Yin, J., and Yang, S., Elastoplastic inverse opals as power-free mechanochromic sensors for force recording. Advanced Functional Materials, 2015, Volume 25, 6041-6049.

6.      Streller, F., Wabiszewski, G. E., Mangolini, F., Feng, G., and Carpick, R. W., Tunable, source-controlled formation of platinum silicides and nanogaps from thin precursor films. Advanced Materials Interfaces, 2014, Volume 1, 1300120.

7.      Kelly, W., Scully, J., Zhang, D., Feng, G., Lavengood, M., Condon, J., Knighton, J., and Bhatia, R., Understanding and modeling alternating tangential flow filtration for perfusion cell culture. Biotechnology Progress, 2014, Volume 30, 1291-1300.

8.      He, M.-R., Felfer, P. J., Dasgupta, S., Samudrala, S. K., Malone, P. J., Feng, G., Hemker, K. J., Cairney, J. M., and Gianola, D. S., Understanding the mechanical behavior of nanocrystalline Al–O thin films with complex microstructures. Acta Materialia, 2014, Volume 77, 269-283.

9.      Brugarolas, T., Gianola, D. S., Zhang, L., Campbell, G. M., Bassani, J. L., Feng, G., and Lee, D., Tailoring and understanding the mechanical properties of nanoparticle-shelled bubbles. ACS Applied Materials & Interfaces, 2014, Volume 6, 11558-11572.

10.  Zhang, L., Feng, G., Zeravcic, Z., Brugarolas, T., Liu, A. J., and Lee, D., Using shape anisotropy to toughen disordered nanoparticle assemblies. ACS Nano, 2013, Volume 7, 8043-8050.

11.  Wendelin, J. W., Feng, G., and Nix, W. D., A laboratory experiment using nanoindentation to demonstrate the indentation size effect. Journal of Materials Education, 2013, Volume 35, 135-143.

12.  Warzoha, R. J., Zhang, D., Feng, G., and Fleischer, A. S., Engineering interfaces in carbon nanostructured mats for the creation of energy efficient thermal interface materials. Carbon, 2013, Volume 61, 441-457.

13.  Min Han, S., Feng, G., Young Jung, J., Joon Jung, H., Groves, J. R., Nix, W. D., and Cui, Y., Critical-temperature/Peierls-stress dependent size effects in body centered cubic nanopillars. Applied Physics Letters, 2013, Volume 102, 041910.

14.  Zhang, L., Prosser, J. H., Feng, G., and Lee, D., Mechanical properties of atomic layer deposition-reinforced nanoparticle thin films. Nanoscale, 2012, Volume 4, 6543-6552.

15.  Askari, D., and Feng, G., Finite element analysis of nanowire indentation on a flat substrate. Journal of Materials Research, 2012, Volume 27, 586-591.

16.  Montalbano, T., and Feng, G., Nanoindentation characterization of the cement lines in ovine and bovine femurs. Journal of Materials Research, 2011, Volume 26, 1036-1041.

17.  Dafinone, M. I., Feng, G., Brugarolas, T., Tettey, K. E., and Lee, D., Mechanical reinforcement of nanoparticle thin films using atomic layer deposition. Acs Nano, 2011, Volume 5, 5078-5087.


Journal Papers (Previous)

Feng, G; Freund, LB, Formation energies and equilibrium configurations of dislocation arrays with alternating Burgers vectors in layered heterostructures, Journal of Crystal Growth; 2010; v.312, no. 12-13, p.1997-2007.

Feng, G; Qu, S; Huang, Y; Nix, WD, A quantitative analysis for the stress field around an elastoplastic indentation/contact, Journal of Materials Research; 2009; v.24, no.3, p.704-718.

Feng, G; Budiman, AS; Tamura, N; Patel, JR; Nix, WD, Indentation size effects in single crystal Cu as revealed by synchrotron X-ray microdiffraction, Journal of Applied Physics; 2008; v.104, Art. No. 043501.

Chiu, Y; Feng, G; Tang, B; Ngan, AHW, An alternative method for continuous property measurement during depth-sensing indentation, International Journal of Surface Science and Engineering; 2007; v.1, no.1, p.144-154.

Feng, G; Qu, S; Huang, Y; Nix, WD, An analytical expression for the stress field around an elastoplastic indentation/contact, Acta Materialia; 2007; v.55, n.9, p.2929-2938.

Nix, WD; Greer, JR; Feng, G; Lilleodden, ET, Deformation at the nanometer and micrometer length scales: effects of strain gradients and dislocation starvation, Thin Solid Films; 2007; v.515, no.6, p.3152-3157.

Feng, G; Yoon, Y; Lee, C; Nix, WD, A study of the mechanical properties of nanowires using nanoindentation, Journal of Applied Physics; 2006; v.99, no.7, Art. No. 074304.

Huang, Y; Zhang, F; Hwang, KC; Nix, WD; Pharr, GM; Feng, G, A model of size effects in nano-indentation, Journal of the Mechanics and Physics of Solids; 2006; v.54, no.8, p.1668-1686.

Feng, G; Nix, WD, Indentation size effect in MgO, Scripta Materialia; 2004; v.51, no.6, p.599-603.

O'Hayre, R; Feng, G; Nix, WD; Prinz, FB, Quantitative impedance measurement using atomic force microscopy, Journal of Applied Physics; 2004; v.96, no.6, p.3540-3549.

Feng, G; Ngan, AHW, Effects of creep and thermal drift on modulus measurement using depth-sensing indentation, Journal of Materials Research; 2002; v.17, no.3, p.660-668.

Feng, G; Ngan, AHW, Creep and strain burst in indium and aluminium during nanoindentation,Scripta Materialia; 2001; v.45, no.8, p.971-976.


Conference Proceeding Papers

Ngan, AHW; Feng, G; Tang, B; Li, H; Wo, PC, Time-dependent plasticity in the submicron regime,Proceedings of IUTAM Symposium on Size Effects on Material and Structural Behavior at Micron- and Nano-Scales; 2004; p.115-124.

Feng, G; Ngan, AHW, The effects of creep on elastic modulus measurement using nanoindentation,Materials Research Society Symposium Proceedings; 2001; v.649, p.Q7.1.1-Q7.1.6.



Feng, G; Ngan. AHW, Patent: Method for Measuring Elastic Properties, (US 2003/0094034 A1, EP 1314970 A2).