 | Nanotech 2007 Vol. 3
Technical Proceedings of the 2007 NSTI Nanotechnology Conference and Trade Show, Volume 3
Chapter 4: Micro and Nano Fluidics |
| - | Fabrication of 1D nanochannels with thin glass wafers for single molecule studies |
| | H. Hoang, I. Segers-Nolten, N. Tas, M. de Boer, V. Subramaniam and M. Elwenspoek |
| | Mesa+ Institute for Nanotechnology, NL |
| - | Nanodroplet Impact on Liquid Substrates via Molecular Dynamics |
| | D. Lussier, N.M.P. Kakalis and Y. Ventikos |
| | University of Oxford, UK |
| - | Embeddable Low-Voltage Micropump using Electroosmosis of the Second Kind |
| | T. Heldal, T. Volden, J. Auerswald and H. Knapp |
| | IQ Micro Inc., CH |
| - | Novel piezo motor enables positive displacement microfluidic pump |
| | D. Henderson |
| | New Scale Technologies, US |
| - | Chaotic advection induced by a magnetic chain in a rotating magnetic field |
| | T.G. Kang, M.A. Hulsen, P.D. Anderson, J.M.J den Toonder and H.E.H. Meijer |
| | Eindhoven University of Technology, NL |
| - | Separation dynamics of binary liquid mixtures - Theory & Experiment |
| | P. Truman, F. Varnik, P. Uhlmann, M. Stamm and D. Raabe |
| | Institute of Polymer Research, DE |
| - | Dynamics and distribution of counterions in the vicinity of a flexible polyelectrolyte |
| | T.S. Lo, B. Khusid, J. Koplik and A. Acrivos |
| | New Jersey Institute of Technology, US |
| - | A Microfluidic Array with Micro Cell Sieves for Cell Cytotoxicity Screening |
| | Z.H. Wang, M.C. Kim, M. Marquez and T. Thorsen |
| | Massachusetts Institute of Technology, US |
| - | Development of Immunoassay Microfluidic Chip Using Serial-flow Method |
| | J. Hsieh, H-L Yin, Y-C Huang, H-H Hsu, Y-S Lin and T-T Huang |
| | Instrument Technology Research Center, TW |
| - | A method for the highly parallel analysis of gene expression of single cells |
| | W.R.A. Meuleman, N. Milner, D.W.K. Lueerssen and E.M. Southern |
| | Oxford Gene Technology, UK |
| - | Automated Microfluidic Chip and System for the Synthesis of Radiopharmaceuticals on Human-Dose Scales |
| | R.M. van Dam, A.M. Elizarov, E. Ball, C.K-F Shen, H. Kolb, J. Rolland, L. Diener, D. Williams, B. Edgecombe, T. Stephen and J.R. Heath |
| | Siemens Molecular Imaging Biomarker Research, US |
| - | Microfluidic Cell Culture System for Live Cell Imaging |
| | M.J. Powell, L.K. Higashi, A.A. Cabasug, S.M. Giffin and R.K. Alley |
| | Nanopoint Inc., US |
| - | Multifunctional Microvalves Control by Optical Illumination on Nanoheaters and its Application in Centrifugal Microfluidic Devices |
| | J-M Park, Y-K Cho, B-S Lee, J-G Lee and C. Ko |
| | Samsung Advanced Institute of Technology, KR |
| - | Methods of energizing micro flows by acoustic and electric fields |
| | F. Schönfeld, D. Dadic, S. Hardt, R. Püschl and F. Schmitz |
| | Institut für Mikrotechnik Mainz / IMM, DE |
| - | Droplet-based Segregation and Extraction of Concentrated Samples |
| | C.R. Buie, P. Buckley, J. Hamilton, K.D. Ness and K.A. Rose |
| | Lawrence Livermore National Laboratory, US |
| - | Liquid transport detection using single FET devices |
| | P. Truman, P. Uhlmann and M. Stamm |
| | Institute of Polymer Research, DE |
| - | Numerical and Experimental Investigation of Three-Dimensional Hydrodynamic Focusing in Polydimethylsiloxane (PDMS) Microchannels |
| | C-C Chang and R-J Yang |
| | National Cheng Kung University, TW |
| - | Molecular Dynamics Simulations of Nano-Droplet Wetting on a Solid Surface |
| | N. Sedighi, S. Murad and S.K. Aggarwal |
| | University of Illinois at Chicago, US |
| - | Lithographic fabricated ultra hydrophobic and porous plant-like surfaces for bio chip applications |
| | O. Mertsch, A.D. Walter, B. Loechel and D. Schondelmaier |
| | BESSY GmbH, DE |
| - | A Microfluidic Mixer for Chaotic Mixing of Magnetic Particles |
| | M. Zolgharni, S.M. Azimi, M.R. Bahmanyar and W. Balachandran |
| | Brunel University, UK |
| - | Enhancement of micro-flow mixing using DC nonlinear electrokinetic vortices |
| | J-K Chen and R-J Yang |
| | National Cheng Kung University, TW |
| - | Quick “easy?!” determination of the diameter of nanocapillaries |
| | A. Lutfurakhmanov, R. Sailer, I. Akhatov and D.L. Schulz |
| | North Dakota State University, US |
| - | Scaling Relation between Current through Suspensions of Carbon-doped TiO2 Nanoparticles in Silicone Oil and Reciprocal of Shear Rate under Combined Electric and Shear Fields |
| | Z.Y. Qiu, Y. Shen, L.W. Zhou and Y.H. Zhu |
| | City College of New York, US |
| - | A Microsystem and Model for Continuous Immunomagnetic Cell Sorting |
| | E.P. Furlani |
| | University at Buffalo (SUNY), US |
| - | Simulation on biological cell transport in the microfluidic devices |
| | M.C. Kim, Z.H. Wang, R.H.W. Lam and T. Thorsen |
| | Massachusetts Institute of Technology, US |
| - | Three-Dimensional Transient Motion of Spherical and Deformable Droplet in L-Shaped Rectangular Microchannel |
| | C.W. Kang, J.S. Hua and J. Lou |
| | Institute of High Performance Computing, SG |
| - | A Microfluidic Device for Opto-Electrochemical Sensing |
| | T.-J.M. Luo, Y. Choi and U. Huh |
| | North Carolina State University, US |
| - | Using epoxy resin to fabricate a master for microfluidic devices in poly(dimethylsiloxane) |
| | Y-J Pan and R-J Yang |
| | National Cheng Kung University, TW |
| - | 200um-class Polymeric Microneedle Fabricated by a Micro Injection Molding Technique |
| | J-J Kang, S-H Lee, T-S Jung and Y-M Heo |
| | Korea Institute of Industrial Technology, KR |
| - | Control of Micro-Fluidic Flow using 3D Features |
| | L.E. Bullock and A.E. Robinson |
| | University of Massachusetts Dartmouth, US |
| - | Design & Fabrication of Ceramic Microarrays Using Powder Injection Molding |
| | S.V. Atre, C. Wu, S.J. Park and K. Simmons |
| | Oregon Nanoscience & Microtechnologies Institute, US |
| - | New sample injection methods for chip electrophoresis |
| | A. Gaspar, M. Piyasena and F.A. Gomez |
| | California State University Los Angeles, US |
| - | Combining Additive and Substractive techniques in the design and fabrication of Microfluidic devices |
| | L. Levine |
| | ALine, Inc., US |
| - | Magnetically Controlled Valve for Flow Manipulation in Polymeric Microfluidic Devices |
| | A. Gaspar, M.E. Piyasena and F.A. Gomez |
| | California State University, Los Angeles, US |
| - | Design, Fabrication & Testing of a Ceramic Microreactor for Nanoparticle Synthesis |
| | K. Jain, C. Wu, S. Atre, S. Kimura, G. Jovanovic, V. Sprenkle, N. Canfield, V. Narayanan and S. Roy |
| | Oregon Nanoscience & Microtechnologies Institute, US |
| - | Micro and nano flow usage in future nuclear reactors |
| | L. Popa-Simil |
| | LAVM Inc., US |
| - | On-site Screening of Avian Influenza Virus (AIV) by Polystyrene Microfluidic Chip Immunoassay |
| | Y. Zhao, M. Zou, Q. Xue and P. Zhou |
| | The Chinese Academy of Inspection and Quarantine, CN |
| - | Pattern Characteristic by Electrostatic Drop-On-Demand Ink-jet Printing Using Capillary Inkjet Head System |
| | J. Choi, S.U. Son, Y. Kim, S. Lee, Y. Kim, H.S. Ko and D. Byun |
| | Sungkyunkwan University, KR |
| - | Levitation of a Charged Microdroplet |
| | A. Schildknecht and E.P. Hofer |
| | University of Ulm, DE |
| - | Fabrication and Application in Microfluidics of Novel Transparent Preceramic Polymer Derived Glass Microcannels and Substrates |
| | D-P Kim, J-H Park and J. Perumal |
| | Chungnam National University, KR |
| - | A platform for assembly of electro-hydrodynamic microfluidics |
| | A. Kumar, B. Khusid, C. James and A. Acrivos |
| | New Jersey Institute of Technology, US |
| - | Filtration and emulsification with nanoengineered membranes |
| | C.J.M. van Rijn and W. Nijdam |
| | University of Wageningen, NL |
| - | Microfluidic Valve-Controllable Magnetic Bead Receptacle: A Novel Platform for DNA Sequencing |
| | H. Esfandyarpour and R.W. Davis |
| | Stanford Genome Technology Center, US |
| - | Chaotic mixing using periodic and aperiodic sequences of mixing protocols in a micromixer |
| | T.G. Kang, M.K. Singh, T.H. Kwon and P.D. Anderson |
| | Eindhoven University of Technology, NL |
| - | Fixed-Valve Micropump Simulation and Optimization |
| | F.K. Forster and T. Walter |
| | University of Washington, US |
| - | Particle Electrophoresis in Closed-both-end Capillary and Likely Charged Particle Aggregation Induced by AC Electric Field |
| | Z.Y. Qiu and Y. Shen |
| | City College of New York, US |
| ISBN: | 1-4200-6184-4 |
| Pages: | 732 |
| Hardcopy: | $199.99 |
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