| Prediction of TiO2 nanoparticle phase and shape transitions controlled by surface chemistry AS Barnard, LA Curtiss Nano letters 5 (7), 1261-1266, 2005 | 631 | 2005 |
| Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds C Bradac, T Gaebel, N Naidoo, MJ Sellars, J Twamley, LJ Brown, ... Nature nanotechnology 5 (5), 345, 2010 | 401 | 2010 |
| Ultra Nanocrystalline Diamond: Synthesis, Properties and Applications AS Barnard, OA Shenderova, DM Gruen William Andrew Publishing, New York, 2006 | 326* | 2006 |
| A model for the phase stability of arbitrary nanoparticles as a function of size and shape AS Barnard, P Zapol The Journal of chemical physics 121 (9), 4276-4283, 2004 | 272 | 2004 |
| Effects of particle morphology and surface hydrogenation on the phase stability of TiO2 AS Barnard, P Zapol Physical Review B 70 (23), 235403, 2004 | 233 | 2004 |
| Modeling the morphology and phase stability of TiO2 nanocrystals in water AS Barnard, P Zapol, LA Curtiss Journal of Chemical Theory and Computation 1 (1), 107-116, 2005 | 206 | 2005 |
| Crystallinity and surface electrostatics of diamond nanocrystals AS Barnard, M Sternberg Journal of Materials Chemistry 17 (45), 4811-4819, 2007 | 201 | 2007 |
| Nanogold: a quantitative phase map AS Barnard, NP Young, AI Kirkland, MA Van Huis, H Xu ACS nano 3 (6), 1431-1436, 2009 | 191 | 2009 |
| Modelling of nanoparticles: approaches to morphology and evolution AS Barnard Reports on Progress in Physics 73 (8), 086502, 2010 | 179 | 2010 |
| Equilibrium morphology of face-centered cubic gold nanoparticles> 3 nm and the shape changes induced by temperature AS Barnard, XM Lin, LA Curtiss The Journal of Physical Chemistry B 109 (51), 24465-24472, 2005 | 151 | 2005 |
| Diamond standard in diagnostics: nanodiamond biolabels make their mark AS Barnard Analyst 134 (9), 1751-1764, 2009 | 150 | 2009 |
| Naturally occurring iron oxide nanoparticles: morphology, surface chemistry and environmental stability H Guo, AS Barnard Journal of Materials Chemistry A 1 (1), 27-42, 2013 | 146 | 2013 |
| Shaping Nanometer‐Scale Architecture Through Surface Chemistry ZV Saponjic, NM Dimitrijevic, DM Tiede, AJ Goshe, X Zuo, LX Chen, ... Advanced Materials 17 (8), 965-971, 2005 | 145 | 2005 |
| Self-assembly in nanodiamond agglutinates AS Barnard Journal of Materials Chemistry 18 (34), 4038-4041, 2008 | 139 | 2008 |
| Predicting the energetics, phase stability, and morphology evolution of faceted and spherical anatase nanocrystals AS Barnard, P Zapol The Journal of Physical Chemistry B 108 (48), 18435-18440, 2004 | 128 | 2004 |
| Nanodiamond photoemitters based on strong narrow‐band luminescence from silicon‐vacancy defects II Vlasov, AS Barnard, VG Ralchenko, OI Lebedev, MV Kanzyuba, ... Advanced Materials 21 (7), 808-812, 2009 | 127 | 2009 |
| Coexistence of bucky diamond with nanodiamond and fullerene carbon phases AS Barnard, SP Russo, IK Snook Physical Review B 68 (7), 073406, 2003 | 125 | 2003 |
| Size dependent phase stability of carbon nanoparticles: Nanodiamond versus fullerenes AS Barnard, SP Russo, IK Snook The Journal of chemical physics 118 (11), 5094-5097, 2003 | 124 | 2003 |
| Anatase and rutile surfaces with adsorbates representative of acidic and basic conditions AS Barnard, P Zapol, LA Curtiss Surface science 582 (1-3), 173-188, 2005 | 119 | 2005 |
| Confirmation of the electrostatic self-assembly of nanodiamonds LY Chang, E Ōsawa, AS Barnard Nanoscale 3 (3), 958-962, 2011 | 103 | 2011 |
