Application of Transmitted Kikuchi Diffraction in Studying Nano-oxide and Ultrafine Metallic Grains

被引:32
作者
Abbasi, Majid [1 ]
Kim, Dong-Ik [1 ]
Guim, Hwan-Uk [2 ]
Hosseini, Morteza [3 ]
Danesh-Manesh, Habib [3 ]
Abbasi, Mehrdad [4 ]
机构
[1] Korea Inst Sci & Technol, High Temp Energy Mat Res Ctr, Seoul 02792, South Korea
[2] Korea Basic Sci Inst, Taejon 34133, South Korea
[3] Shiraz Univ, Dept Mat Sci & Engn, Shiraz, Iran
[4] Amirkabir Univ Technol, Dept Min & Met, Tehran, Iran
来源
ACS NANO | 2015年 / 9卷 / 11期
关键词
transmitted Kikuchi diffraction; transmitted EBSD; orientation imaging in TEM; nanograins; ultrafine grains; accumulative roll bonding; oxidation; ELECTRON BACKSCATTER DIFFRACTION; TRANSMISSION ELECTRON; ORIENTATION MAPS; SCATTER DIFFRACTION; BOUNDARY ENERGY; THIN-FILMS; EBSD; MICROSCOPY; PHASE; PATTERNS;
D O I
10.1021/acsnano.5b04296
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
Transmitted Kikuchi diffraction (TKD) is an emerging SEM-based technique that enables investigation of highly refined grain structures. It offers higher spatial resolution by utilizing conventional electron backscattered diffraction equipment on electron-transparent samples. A successful attempt has been made to reveal nano-oxide grain structures as well as ultrafine severely deformed metallic grains. The effect of electron beam current was studied. Higher beam currents enhance pattern contrast and intensity. Lower detector exposure times could be employed to accelerate the acquisition time and minimize drift and carbon contamination. However, higher beam currents increase the electron interaction volume and compromise the spatial resolution. Lastly, TKD results were compared to orientation mapping results in TEM (ASTAR). Results indicate that a combination of TKD and EDS is a capable tool to characterize nano-oxide grains such as Al2O3 and Cr2O3 with similar crystal structures.
引用
收藏
页码:10991 / 11002
页数:12
相关论文
共 70 条
[21]  
Goran D., 2015, 5 BRUK EBSD WORKSH M
[22]   Materials interface engineering for solution-processed photovoltaics [J].
Graetzel, Michael ;
Janssen, Rene A. J. ;
Mitzi, David B. ;
Sargent, Edward H. .
NATURE, 2012, 488 (7411) :304-312
[23]   Combining structural and chemical information at the nanometer scale by correlative transmission electron microscopy and atom probe tomography [J].
Herbig, M. ;
Choi, P. ;
Raabe, D. .
ULTRAMICROSCOPY, 2015, 153 :32-39
[24]   Bond strength optimization of Ti/Cu/Ti clad composites produced by roll-bonding [J].
Hosseini, M. ;
Manesh, H. Danesh .
MATERIALS & DESIGN, 2015, 81 :122-132
[25]   Identifying suboxide grains at the metal-oxide interface of a corroded Zr-1.0%Nb alloy using (S)TEM, transmission-EBSD and EELS [J].
Hu, Jing ;
Garner, Alistair ;
Ni, Na ;
Gholinia, Ali ;
Nicholls, Rebecca J. ;
Lozano-Perez, Sergio ;
Frankel, Philipp ;
Preuss, Michael ;
Grovenor, Chris R. M. .
MICRON, 2015, 69 :35-42
[26]   Thermal stability of Ni/NiO multilayers [J].
Kacher, Josh ;
Elizaga, Patricia ;
House, Stephen D. ;
Hattar, Khalid ;
Nowell, Matt ;
Robertson, I. M. .
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 2013, 568 :49-60
[27]   Transmission EBSD from 10 nm domains in a scanning electron microscope [J].
Keller, R. R. ;
Geiss, R. H. .
JOURNAL OF MICROSCOPY, 2012, 245 (03) :245-251
[28]   Grain Boundary Mapping in Polycrystalline Graphene [J].
Kim, Kwanpyo ;
Lee, Zonghoon ;
Regan, William ;
Kisielowski, C. ;
Crommie, M. F. ;
Zettl, A. .
ACS NANO, 2011, 5 (03) :2142-2146
[29]   Estimation of dislocation density from precession electron diffraction data using the Nye tensor [J].
Leff, A. C. ;
Weinberger, C. R. ;
Taheri, M. L. .
ULTRAMICROSCOPY, 2015, 153 :9-21
[30]   Grain-Boundary-Enhanced Carrier Collection in CdTe Solar Cells [J].
Li, Chen ;
Wu, Yelong ;
Poplawsky, Jonathan ;
Pennycook, Timothy J. ;
Paudel, Naba ;
Yin, Wanjian ;
Haigh, Sarah J. ;
Oxley, Mark P. ;
Lupini, Andrew R. ;
Al-Jassim, Mowafak ;
Pennycook, Stephen J. ;
Yan, Yanfa .
PHYSICAL REVIEW LETTERS, 2014, 112 (15)
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