Structural ( n, m) determination of isolated single-wall carbon nanotubes by resonant Raman scattering.
TL;DR: It is shown that the Raman scattering technique can give complete structural information for one-dimensional systems, such as carbon nanotubes, by measuring one radial breathing mode frequency omega(RBM) and using the theory of resonant transitions.
Abstract: We show that the Raman scattering technique can give complete structural information for one-dimensional systems, such as carbon nanotubes. Resonant confocal micro-Raman spectroscopy of an (n,m) individual single-wall nanotube makes it possible to assign its chirality uniquely by measuring one radial breathing mode frequency omega(RBM) and using the theory of resonant transitions. A unique chirality assignment can be made for both metallic and semiconducting nanotubes of diameter d(t), using the parameters gamma(0) = 2.9 eV and omega(RBM) = 248/d(t). For example, the strong RBM intensity observed at 156 cm(-1) for 785 nm laser excitation is assigned to the (13,10) metallic chiral nanotube on a Si/SiO2 surface.
Figures (5)
FIG. 3. (a) Measured frequency vs intensity for the RBM peaks observed at 42 different spots on the sample (Fig. 1). (b) Calculated energy separation Eii as a function of 1#dt , g0 ! 2.9 eV, and vRBM ! 248#dt . Circles are for metallic SWNTs (EMii ), and crosses for semiconducting SWNTs (E S ii). 
FIG. 2. Raman spectra from three different spots on the Si substrate, showing only one resonant nanotube and one RBM frequency for each of 3 spots. The RBM frequencies (widths) and !n, m" assignment for each resonant SWNT are displayed. The 303 cm21 feature comes from the Si substrate. Inset (a) shows Raman spectra from one spot on the sample, including 303, 521, and 963 cm21 Raman features from the Si substrate. Inset (b) shows a zoom of the corresponding G-band region. 
TABLE II. Possible chiralities predicted for semiconducting nanotubes and their vRBM (calculated and observed) in the resonant window 1.48 , ES22 , 1.68 eV. 
FIG. 1. AFM images of the sample. The small particles are iron catalysts. The inset shows the diameter distribution of the sample taken from 40 observed SWNTs. 
TABLE I. Possible chiralities predicted for metallic nanotubes and their calculated vRBM in the resonant window 1.48 , EM11 , 1.68 eV. We also display the observed vRBM, with the number of times each appears between parentheses.
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TL;DR: The use of Raman spectroscopy to reveal the remarkable structure and the unusual electronic and phonon properties of single wall carbon nanotubes (SWNTs) is reviewed comprehensively in this article.
3,835 citations
TL;DR: This paper presents a probabilistic procedure for estimating the polymethine content of carbon dioxide using a straightforward two-step procedure, and shows good results in both the stationary and the liquid phase.
Abstract: Liming Dai,*,†,‡ Yuhua Xue,†,‡ Liangti Qu,* Hyun-Jung Choi, and Jong-Beom Baek* †Center of Advanced Science and Engineering for Carbon (Case4Carbon), Department of Macromolecular Science and Engineering, Case Western Reserve University, 10900 Euclid Avenue, Cleveland, Ohio 44106, United States Key Laboratory of Cluster Science, Ministry of Education of China, Beijing Key Laboratory of Photoelectronic/Electrophotonic Conversion Materials, Department of Chemistry, School of Science, Beijing Institute of Technology, Beijing 100081, People’s Republic of China School of Energy and Chemical Engineering/Center for Dimension-Controllable Covalent Organic Frameworks, Ulsan National Institute of Science and Technology (UNIST), 100 Banyeon, Ulsan, 689-798, South Korea
1,967 citations
TL;DR: Carbon nanotubes are unique tubular structures of nanometer diameter and large length/diameter ratio as mentioned in this paper, which can be metallic or semiconducting depending on their structural parameters.
Abstract: Carbon nanotubes are unique tubular structures of nanometer diameter and large length/diameter ratio. The nanotubes may consist of one up to tens and hundreds of concentric shells of carbons with adjacent shells separation of ∼0.34 nm. The carbon network of the shells is closely related to the honeycomb arrangement of the carbon atoms in the graphite sheets. The amazing mechanical and electronic properties of the nanotubes stem in their quasi-one-dimensional (1D) structure and the graphite-like arrangement of the carbon atoms in the shells. Thus, the nanotubes have high Young’s modulus and tensile strength, which makes them preferable for composite materials with improved mechanical properties. The nanotubes can be metallic or semiconducting depending on their structural parameters. This opens the ways for application of the nanotubes as central elements in electronic devices including field-effect transistors (FET), single-electron transistors and rectifying diodes. Possibilities for using of the nanotubes as high-capacity hydrogen storage media were also considered. This report is intended to summarize some of the major achievements in the field of the carbon nanotube research both experimental and theoretical in connection with the possible industrial applications of the nanotubes.
1,610 citations
TL;DR: Carbon nanotubes exhibit many unique intrinsic physical and chemical properties and have been intensively explored for biological and biomedical applications in the past few years as mentioned in this paper, and a comprehensive review of the main results from our and other groups in this field can be found in this paper.
Abstract: Carbon nanotubes exhibit many unique intrinsic physical and chemical properties and have been intensively explored for biological and biomedical applications in the past few years. In this comprehensive review, we summarize the main results from our and other groups in this field and clarify that surface functionalization is critical to the behavior of carbon nanotubes in biological systems. Ultrasensitive detection of biological species with carbon nanotubes can be realized after surface passivation to inhibit the non-specific binding of biomolecules on the hydrophobic nanotube surface. Electrical nanosensors based on nanotubes provide a label-free approach to biological detection. Surface-enhanced Raman spectroscopy of carbon nanotubes opens up a method of protein microarray with detection sensitivity down to 1 fmol/L. In vitro and in vivo toxicity studies reveal that highly water soluble and serum stable nanotubes are biocompatible, nontoxic, and potentially useful for biomedical applications. In vivo biodistributions vary with the functionalization and possibly also size of nanotubes, with a tendency to accumulate in the reticuloendothelial system (RES), including the liver and spleen, after intravenous administration. If well functionalized, nanotubes may be excreted mainly through the biliary pathway in feces. Carbon nanotube-based drug delivery has shown promise in various In vitro and in vivo experiments including delivery of small interfering RNA (siRNA), paclitaxel and doxorubicin. Moreover, single-walled carbon nanotubes with various interesting intrinsic optical properties have been used as novel photoluminescence, Raman, and photoacoustic contrast agents for imaging of cells and animals. Further multidisciplinary explorations in this field may bring new opportunities in the realm of biomedicine.
1,538 citations
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03 May 2006
TL;DR: In this paper, the authors discuss the development of single-walled carbon nanotubes as AFM probes and the application of nanotube probe tips in AFM imaging.
Abstract: The Element Carbon Frank Hennrich, Valerie Moore, Marco Rolandi, and Mike O'Connell Allotropes of Carbon History Structure Progress of Single-Walled Carbon Nanotube Research toward Application References Synthesis of Carbon Nanotubes David Mann Introduction CNT Synthesis Methods Overview Specifics of CVD Growth Method Recent Advances in SWCNT Growth Control Conclusion References Carbon Nanotube Peapod Materials Satishkumar B. Chikkannanavar, Brian W. Smith, and David E. Luzzi Introduction and Historical Perspective C60@SWNT Beyond C60: Other Hierarchical Nanotube Materials Ordered Phases of Fullerenes in Larger Nanotubes Double-Wall Carbon Nanotubes Conclusions and Future Prospects Acknowledgments References Carbon Nanotube Electronics and Devices Marcus Freitag Metallic Carbon Nanotubes Semiconducting Carbon Nanotubes Outlook and Challenges References Magnetic Properties Junichiro Kono and Stephan Roche Introduction Theoretical Perspectives Experimental Results Acknowledgments References Raman Spectroscopy of Single-Walled Carbon Nanotubes: Probing Electronic and Chemical Behavior Stephen K. Doorn, Daniel Heller, Monica Usrey, Paul Barone, and Michael S. Strano Introduction Resonance Raman Studies of Carbon Nanotubes Raman Characterization of Nanotube Samples and Nanotube Reactivity Conclusions References Electromechanical Properties and Applications of Carbon Nanotubes Randal J. Grow Introduction Piezoresistance Theory of Strain-Induced Band-Gap Changes in Carbon Nanotubes Electrical Measurements of Strain-Induced Band-Gap Changes in Suspended Tubes Electrical Measurements of Strain-Induced Band-Gap Changes in Tubes on a Surface Conclusion of Piezoresistance of Nanotubes Electrostatic actuation Nanoelectromechanical systems Conclusion References Carbon Nanotube-Enabled Materials Han Gi Chae, Jing Liu, and Satish Kumar Introduction Dispersion and Processing Issues Characterization of Polymer/CNT Composites CNT Films and Fibers Polymer/CNT Composite Films and Fibers Crystallization, Wrapping, Interaction, and Intercalation Concluding Remarks Acknowledgment References Functionalized Carbon Nanotubes in Composites Christopher A. Dyke and James M. Tour Introduction SWNT Preparation and Characterization Functionalized SWNTs Carbon Nanotube-Modified Composites Conclusions Acknowledgments References Carbon Nanotube Tips for Scanning Probe Microscopy C. Patrick Collier Carbon nanotubes as AFM probes Fabrication of nanotube probe tips AFM imaging with nanotube probes Applications of carbon nanotube probes Future directions Acknowledgments References Index
1,416 citations