Relevant Literature (click on each title for link)

• Band Gap Fluorescence from Individual Single-Walled Carbon Nanotubes, M. O'Connell et al., Science 297, 593 (2002)
• Structure-Assigned Optical Spectra of Single-Walled Carbon Nanotubes, S. M. Bachilo et al., Science 298, 2361 (2002)
  
• Dependence of Optical Transition Energies on Structure for SWCNT in Aqueous Suspension: An Empirical Katuaura Plot,

           R. B. Weisman and S. M. Bachilo, Nano Lett. 3, 1235 (2003)

• Down the Tubes We Glow, D. Bradley, Spectroscopy now (2004)
• Simplifying Carbon Nanotube Identification, R. Bruce Weisman, The Industrial Physicist 24 (2004)
• Carbon Nanotubes, R. B. Weisman and S. Subramoney, The Electrochemical Society's Interface 15, 42 (2006)
• Efficient Fluorimetric Analyzer for SWCNT,ER. B. Weisman et al, WO/2007/001461 (2007)
• Optical Spectroscopy of SWCNT,ER. B. Weisman (2008)
• Fluorimetric Characterization of SWCNT, R. B. Weisman, Analytical & Bioanalytical Chemistry 396, 1015 (2010)

Publications using the NanoSpectralyzer

2009

• High Population of Individualized SWCNTs through the Adsorption of Water-Soluble Perylenes, C. Backes et al, JACS (2009) 131, 2172
• Coating Individual SWCNT with Nylon 6,10 through Emulsion Polymerization, W. C.  Chen et al, Applied Materials & INterfaces (2009) 1, 1821
• Environmentally Friendly Functionalization of SWCNT in molten urea, C. D.  Doyle and J. M. Tour, Carbon (2009) 47, 3215
• Solution Manipulation of SWCNT and Their Applications in Electrochemistry, D. Wang, Ph.D. Thesis, Ohio University (2009)
• Diameter Tuning of SWCNT with Reaction Temperature Using a Co Monometallic Catalyst, N. Li, J. Phys. Chem. C (2009) 113, 10070
• Effect of Chromium Addition to the Co-MCM-41 Catalyst in the Synthesis of SWCNT, C. Z. Loebick et al, Applied Catalysis A: General (2009) doi:10.1016/j.apcata.2009.08.004
• Long-Term Improvements to Photoluminescence and Dispersion Stability by Flowing SDS-SWNT Suspensions through Microfluidic Channels, C. A. Silvera-Batista et al, JACS (2009) 131, 12721

• Do Inner Shells of Double-Walled Carbon Nanotubes Fluoresce? D.A. Tsyboulski et al, Nano Lett (2009) 9, 3282
• In Vivo Therapeutic Silencing of Hypoxia-Inducible Factor 1 Alpha (HIF-1 ) Using Single-Walled Carbon Nanotubes Noncovalently Coated with siRNA,

                   G. Bartholomeusz et al, Nano Research (2009) 2, 279

• Multidomain Peptides as SWCNT Surfactants in Cell Culture, E.L. Bakota et al, Biomacromolecules (2009) 10, 2201
• Strategy for High Concentration Nanodispersion of SWCNT with Diameter Selectivity,   C. Biswas et al, J. Phys. Chem. C (2009) 113, 10044
• Selective Enhancement of Carbon Nanotube Photoluminescence by Resonant Energy Transfer,   Ahmad et al, Chem. Phys. Chem. (2009) 10, 905
• Fluorescence Quenching of SWCNTs with Transition-Metal Ions, J. Brege et al, J. Phys. Chem. C (2009) 113, 4270
• Investigation of Optimal Parameters for Oxide-Assisted Growth of Vertically Aligned SWCNTs, C. Pint et al, J. Phys. Chem. C (2009) 113, 4125

2008

• Swelling the Micelle Core Surrounding SWCNTs with Water-immiscible Organic Solvents, R. Wang at al, JACS (2008) 130, 16330
• Improving the Effectiveness of Interfacial Trapping in Removing SWCNT Bundles, R.K. Wang et al, JACS (2008) 130, 14721
• Structure-dependent Reactivity of SWCNTs with benzenediazonium salts, C. Doyle et al, JACS 130, 6795 (2008)
• Self-Assembling Peptide Coatings Designed for Highly Luminescent Suspension of SWCNT, D.A. Tsyboulski et al, JACS (2008) 130, 17134
• Selective photochemical functionalization of surfactant-dispersed SWCNT in water, N.T. Alvarez et al, JACS (2008) 130, 14227
• Efficient photosensitized energy transfer and near-IR fluorescence from porphyrin–SWNT complexes, J. Casey et al, J. Materials Chem. (2008) 18, 1510
• Preferred Functionalization of Metallic and Small-diameter SWCNTs via reductive alkylation, D. Wunderlich et al, J. Materials Chem. (2008) 18, 1493
• Preferred Functionalization of Metallic and Small-diameter SWCNTs by Nucleophilic Addition of Organolithium and Magnesium Compounds Followed by Reoxidation,

  D. Wunderlich et al, Eur. J. Chem. (2008) 14, 1607

• Stable Luminescence from Individual Carbon Nanotubes in Acidic, Basic, and Biological Environments, J. Duque et al, JACS (2008) 130, 2626
• Antenna chemistry with metallic SWCNT, J. Duque et al, JACS (2008) 130, 15340
  
• Spectroscopic Studies of Carbon Nanotubes, R. Zhang, M.S. Thesis, Ohio University (2008)

2007 & earlier

• Temperature and pH-responsive SWCNT Dispersions, D. Wang and L. Chen, Nano Lett (2007) 7, 1480
• Interfacial Trapping of SWCNT Bundles, R.K. Wang et al, JACS (2007) 129, 15124
• Fluorescence Quenching of SWCNT in SDBS Surfactant Suspension by Metal Ions: Quenching Efficiency as a Function of Metal and Nanotube Identity,

  J. J. Brege et al, J. Phys. Chem. (2007) 111, 17812

• SWCNT PEG-eggs: SWCNTs in Biocompatible Shell-crosslinked Micelles, R. Wang et al, Carbon (2007) 45, 2388
• Structure-dependent Fluorescence Efficiencies of Individual SWCNTs, D.A. Tsyboulski et al, Nano Lett (2007) 7, 3080
• Peptides that Non-covalently Functionalize SWCNTs to give controlled solubility characteristics, L.S. Witus et al, J. Materials Chem. (2007) 17, 1909

• Templated Synthesis of SWCNT and Metal Nanoparticle Assemblies in Solution, D. Wang et al, JACS (2006) 128, 15078
• Dielectrophoresis Field Flow Fractionation of SWCNT, H. Peng et al, JACS (2006) 128, 8397
• Functionalization of SWCNT "On Water", B. K. Price and J. M. Tour, JACS (2006) 128, 12899
• Mammalian Pharmacokinetics of Carbon Nanotubes Using Intrinsic Near-infrared Fluorescence, P. Cherukuri et al, PNAS (2006) 103, 18882
• Developing Implantable Optical Biosensors, K.J. Ziegler, Trends in Biotechnol (2005) 23, 440

Additional References

• SWCNTs in the Intact Organism: Near-IR Imaging and Biocompatibility Studies in Drosophila, T.K. Leeuw et al, Nano Lett 7, 2650 (2007)