Crossref Citations
This article has been cited by the following publications. This list is generated based on data provided by Crossref.
Crozier, P. A.
Tolle, J.
Kouvetakis, J.
and
Ritter, Cole
2004.
Synthesis of uniform GaN quantum dot arrays via electron nanolithography of D2GaN3.
Applied Physics Letters,
Vol. 84,
Issue. 18,
p.
3441.
Sharma, Renu
and
Crozier, Peter A.
2005.
Handbook of Microscopy for Nanotechnology.
p.
531.
Sharma, Renu
2005.
An Environmental Transmission Electron Microscope for in situ Synthesis and Characterization of Nanomaterials.
Journal of Materials Research,
Vol. 20,
Issue. 7,
p.
1695.
Ketharanathan, Sutharsan
Sharma, Renu
and
Drucker, Jeff
2005.
Nanoscale electron stimulated chemical vapor deposition of Au in an environmental transmission electron microscope.
Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena,
Vol. 23,
Issue. 6,
p.
2403.
Li, Peng
Liu, Jingyue
Nag, Nabin
and
Crozier, Peter A.
2005.
Atomic-Scale Study of in Situ Metal Nanoparticle Synthesis in a Ni/TiO2 System.
The Journal of Physical Chemistry B,
Vol. 109,
Issue. 29,
p.
13883.
Sharma, Renu
Rez, Peter
Treacy, Michael M. J.
and
Stuart, Steven J.
2005.
In situ observation of the growth mechanisms of carbon nanotubes under diverse reaction conditions.
Microscopy,
Vol. 54,
Issue. 3,
p.
231.
VAN DORP, W. F.
VAN SOMEREN, B.
HAGEN, C. W.
KRUIT, P.
and
CROZIER, P. A.
2006.
Diffraction patterns of artificial two‐dimensional crystals synthesized in situ in an environmental scanning transmission electron microscope.
Journal of Microscopy,
Vol. 221,
Issue. 3,
p.
159.
Crozier, Peter A.
2007.
Nanoscale Oxide Patterning with Electron−Solid−Gas Reactions.
Nano Letters,
Vol. 7,
Issue. 8,
p.
2395.
Crozier, Peter A.
Wang, Ruigang
and
Sharma, Renu
2008.
In situ environmental TEM studies of dynamic changes in cerium-based oxides nanoparticles during redox processes.
Ultramicroscopy,
Vol. 108,
Issue. 11,
p.
1432.
Crozier, Peter A.
2008.
Proximity effects in nanoscale patterning with high resolution electron beam induced deposition.
Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena,
Vol. 26,
Issue. 1,
p.
249.
Utke, Ivo
Hoffmann, Patrik
and
Melngailis, John
2008.
Gas-assisted focused electron beam and ion beam processing and fabrication.
Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena,
Vol. 26,
Issue. 4,
p.
1197.
Li, Yongdan
Li, Douxing
and
Wang, Gaowei
2011.
Methane decomposition to COx-free hydrogen and nano-carbon material on group 8–10 base metal catalysts: A review.
Catalysis Today,
Vol. 162,
Issue. 1,
p.
1.
Crozier, Peter A.
and
Chenna, Santhosh
2011.
In situ analysis of gas composition by electron energy-loss spectroscopy for environmental transmission electron microscopy.
Ultramicroscopy,
Vol. 111,
Issue. 3,
p.
177.
Crozier, Peter A.
2011.
Scanning Transmission Electron Microscopy.
p.
537.
Tao, Franklin (Feng)
and
Crozier, Peter A.
2016.
Atomic-Scale Observations of Catalyst Structures under Reaction Conditions and during Catalysis.
Chemical Reviews,
Vol. 116,
Issue. 6,
p.
3487.
Boniface, Maxime
Plodinec, Milivoj
Schlögl, Robert
and
Lunkenbein, Thomas
2020.
Quo Vadis Micro-Electro-Mechanical Systems for the Study of Heterogeneous Catalysts Inside the Electron Microscope?.
Topics in Catalysis,
Vol. 63,
Issue. 15-18,
p.
1623.
Dai, Jie
Sun, Yifei
Liu, Zhewei
Zhang, Yiyuan
Duan, Sibin
and
Wang, Rongming
2024.
Using In situ Transmission Electron Microscopy to Study Strong Metal‐Support Interactions in Heterogeneous Catalysis.
Angewandte Chemie,
Vol. 136,
Issue. 42,
Dai, Jie
Sun, Yifei
Liu, Zhewei
Zhang, Yiyuan
Duan, Sibin
and
Wang, Rongming
2024.
Using In situ Transmission Electron Microscopy to Study Strong Metal‐Support Interactions in Heterogeneous Catalysis.
Angewandte Chemie International Edition,