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200 10$aIon exchange membranes$b[electronic resource] $epreparation, characterization, modification and application /$fToshikatsu Sata
210   $aCambridge $cRoyal Society of Chemistry$dc2004
215   $a1 online resource (325 p.)
300   $aDescription based upon print version of record.
311   $a0-85404-590-2 
320   $aIncludes bibliographical references and index.
327   $aIEM-PRE; IEM-1; 1.1&X; Background; Table 1; 1.2&X; References; mkr1; mkr2; mkr3; mkr4; mkr5; mkr6; mkr7; mkr8; mkr9; mkr10; mkr11; mkr12; mkr13; mkr14; mkr15; mkr16; mkr17; mkr18; mkr19; mkr20; mkr21; mkr22; mkr23; mkr24; mkr25; mkr26; mkr27; mkr28; mkr29; mkr30; IEM-2; 2.1&X; Introduction; 2.2&X; Flux Equation; Equation 3; Equation 4; Equation 5; Equation 6; Equation 6; Equation 7; Equation 9; Equation 10; Equation 11; Equation 12; Permselectivity of Ions Through the Ion Exchange Membrane; Equation 13; Equation 14; Equation 15; Equation 16; Equation 17; Equation 18; Equation 19
327   $aEquation 20 Equation 21; Equation 22; Equation 23; Equation 24; Equation 25; Equation 26; Equation 27; Equation 28; Equation 29; Equation 30; Equation 31; Equation 32; Equation 33; Equation 34; Equation 35; Membrane Potential; Figure 1; Equation 36; Equation 39; Equation 40; Equation 41; Equation 43; Equation 44; Figure 2; Equation 49; Equation 50; Bionic Potential; Equation 51; Equation 52; Equation 53; Equation 54; Electrical Conductivity of Ion Exchange Membrane; Equation 56; Equation 57; Equation 58; Diffusion of Electrolyte Through Ion Exchange Membranes
327   $aEquation 57 Equation 58; Equation 59; Equation 60; Equation 61; Equation 62; Equation 63; Equation 66; Equation 68; Equation 69; Equation 70; Equation 71; Diffusion of Non-Electrolyte Through Ion Exchange Membranes; Equation 72;Self-diffusion Through Ion Exchange Membranes; Equation 74; Equation 75; Equation 76; Equation 77; Equation 78; Figure 3; Figure 4; Osmosis; Equation 79; Electro-osmosis; Figure 5; Equation 80; Equation 83; Equation 84; Equation 85; 2.12&X; Hydrodynamic Permeability of Solvent; Figure 6; Equation 86; Equation 87; Equation 88; Equation 89
327   $aEquation 90 Equation 93; Equation 94; Equation 95; Equation 96; Equation 97; Equation 98; Equation 99; Permselectivity of Ions with the Same Charge; Equation 8; Figure 7; Equation 101; Equation 102; Equation 105; Equation 106; Conclusions; References; mkr1; mkr2; mkr3; mkr4; mkr5; mkr6; mkr7; mkr8; mkr9; mkr10; mkr11; mkr12; mkr13; mkr14; mkr15; mkr16; mkr17; mkr18; mkr19; mkr20; mkr21; mkr22; mkr23; mkr24; mkr25; mkr26; IEM-3; 3.1&X; Introduction; 3.2&X; Classification of Ion Exchange Membranes; Table 1; 3.3&X
327   $aGeneral Explanation of Preparation Methods of Ion Exchange Membranes 3.3.1&Y; Heterogeneous Ion Exchange Membranes; 3.3.2&Y; Homogeneous Ion Exchange Membranes&Y; ; 3.3.2.1&Z; Ion Exchange Membranes Prepared by Condensation Reaction of Ionic Monomeric Com-pounds; Figure 1; 3.3.2.2&Z; Ion Exchange Membranes Prepared by Polymerization of Vinyl Monomers; Preparation of polymer block and slicing the block into films.&D-end; After styrene has been partially polymerized by heating, d; Figure 2; Table 2; Polymerization of vinyl monomers into films (coating method or paste method).&D-end1
327   $aHere, linear polymers without ion exchange
330   $aVarious separation membranes have been developed since their discovery over half a century ago, providing numerous benefits and fulfilling many applications in our everyday lives. They lend themselves to techniques ranging from microfiltration and gas separation, to what can be considered as the most advanced technique - ion exchange. This book, aimed at academic researchers, engineers and industrialists, contains a brief history of ion exchange and goes on to explain the preparation, characterization, modification and applications of these important membranes. Discussions include the use of
606   $aIon-permeable membranes
608   $aElectronic books.
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200 00$aNanomedicine design of particles, sensors, motors, implants, robots, and devices /$fMark J. Schulz, Vesselin N. Shanov, Yeoheung Yun, editors
210  1$aBoston :$cArtech House,$dİ2009.
210  2$a[Piscataqay, New Jersey] :$cIEEE Xplore,$d[2009]
215   $a1 online resource (548 p.)
225 1 $aArtech House series engineering in medicine & biology
300   $aDescription based upon print version of record.
311   $a1-59693-279-1 
320   $aIncludes bibliographical references and index.
327   $aNanomedicine Design of Particles, Sensors, Motors, Implants, Robots, and Devices; Contents; Preface; Chapter 1 A Nanotechnology Framework for Medical Innovation; 1.1 Introduction; 1.2 Descriptive Systems Modeling; 1.2.1 Examples of Descriptive Systems Modeling; 1.3 Instrumentation Needed to Develop DSM; 1.4 Nanomaterials Made for Medicine; 1.5 Implantable Nanomedical Devices; 1.6 Nanorobots; 1.6.1 Nanorobots for Revolutionizing Medicine; 1.6.2 Nanorobot Factory; 1.6.3 Biological Nanorobots; 1.7 Biodegradable Metals for Temporary Implantable Nanomedical Devices
327   $a1.8 Integration of Nanodevices in the Body1.9 Safety and Ethical Implications of Nanomedicine; 1.10 Efficiently Working Together Using Shared Resources; 1.11 Chapter Summary and Conclusions; Problems; Acknowledgments; References; Endnote; Part 1 Nanoscale Materials and Particles; Chapter 2 Synthesis of Carbon Nanotube Materials for Biomedical Applications; 2.1 Introduction to Nanoscale Materials; 2.2 Synthesis of Long Carbon Nanotube Arrays; 2.3 Characterization of CNT Arrays; 2.3.1 Scanning Electron Microscopy and Transmission Electron Microscopy
327   $a2.3.2 Raman Spectroscopy and Thermal Gravimetric Analysis2.4 Patterned CNT Arrays; 2.5 Production Scale Up of CNT Arrays at UC; 2.5.1 Magnetron Sputtering for Substrate Preparation; 2.6 Spinning Carbon Nanotubes into Thread; 2.6.1 Mechanics of Array Spinning; 2.6.2 Direct Spinning of Thread from Long CNT Arrays; 2.6.3 Catalyst and Substrates for Growing of Spinable CNT Arrays; 2.6.4 Spinning Thread from DWCNT Arrays; 2.6.5 Pulling Ribbon from CNT Arrays; 2.6.6 Post-Treatment of the CNT Thread; 2.7 Mechanical and Electrical Characterization of CNT Thread; 2.7.1 Tensile Testing of CNT Thread
327   $a2.7.2 Electrical Properties of CNT Thread2.7.3 Temperature Dependence of the CNT Thread Resistance; 2.7.4 Electrical Properties of CNT Ribbon; 2.8 Nano-Handling of CNTs Using a Nanomanipulator Inside an ESEM; 2.8.1 Instrumentation; 2.8.2 Handling CNT Bundles; 2.8.3 Building Nanomedical Devices Using the Nanomanipulator; 2.9 Carbon Nanotube Threads in Wireless, Biomedical Sensor Applications; 2.9.1 Wireless Communication and the Modern World; 2.9.2 Development of CNT Thread-Based Antenna at UC; 2.9.3 Future Medical Application of the CNT Thread Antenna
327   $a2.10 Applications of CNT Materials in Nanomedicine2.10.1 Carbon Nanotube Array Immunosensor; 2.10.2 Carbon Nanotube Actuators; 2.10.3 Carbon Nanotube Materials as Scaffolds for Supporting Directional Neurite Growth; 2.11 Summary and Conclusions; Problems; Acknowledgments; References; Chapter 3 Functionalized Carbon Nanotubes as Multimodal Drug Delivery Systems for Targeted Cancer Therapy; 3.1 Introduction to Targeted Cancer Therapy; 3.1.1 Cancer Statistics; 3.1.2 Present-Day Cancer Treatment and Associated Problems; 3.1.3 A Brief Insight into Targeting Strategies
327   $a3.2 Carbon Nanotubes: A Versatile Material
330 8 $aAnnotation This resource outlines the new tools that are becoming available in nanomedicine. The book presents an integrated set of perspectives that describe where advancements are now and where they should be headed to put nanomedicine devices into applications as quickly as possible.
410  0$aArtech House engineering in medicine & biology series.
606   $aNanomedicine
606   $aNanotechnology
615  0$aNanomedicine.
615  0$aNanotechnology.
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701   $aSchulz$b Mark J$01140036
701   $aShanov$b Vesselin N$01561404
701   $aYun$b Yeoheung$01561405
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