LEADER 05398nam  2200673 a 450 
001 9910809253803321
005 20240516212033.0
010   $a1-281-60347-3
010   $a9786613784162
010   $a1-84816-802-0
035   $a(CKB)2670000000229965
035   $a(EBL)982501
035   $a(OCoLC)804661858
035   $a(SSID)ssj0000695464
035   $a(PQKBManifestationID)12330145
035   $a(PQKBTitleCode)TC0000695464
035   $a(PQKBWorkID)10678793
035   $a(PQKB)10875705
035   $a(MiAaPQ)EBC982501
035   $a(WSP)00002710
035   $a(Au-PeEL)EBL982501
035   $a(CaPaEBR)ebr10583630
035   $a(CaONFJC)MIL378416
035   $a(EXLCZ)992670000000229965
100   $a20120808d2012      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 00$aExtended-nanofluidic systems for chemistry and biotechnology /$fKitamori Takehiko ... [et al.]
205   $a1st ed.
210   $aLondon $cImperial College Press$d2012
215   $a1 online resource (187 p.)
300   $aDescription based upon print version of record.
311   $a1-84816-801-2 
320   $aIncludes bibliographical references and index.
327   $aCONTENTS; Chapter 1. Introduction; References; Chapter 2. Microchemical Systems; References; Chapter 3. Fundamental Technology: Nanofabrication Methods; 3.1. Top-Down Fabrication; 3.1.1. Introduction; 3.1.2. Bulk nanomachining techniques; 3.1.2.1. Combination of lithography and wet etching; 3.1.2.2. Combination of lithography and dry etching; 3.1.2.3. Other lithographic techniques; 3.1.2.4. Direct nanofabrication; 3.1.3. Surface machining techniques; 3.1.3.1. Utilization of polysilicon as a sacrificial material; 3.1.3.2. Utilization of metals and polymers as sacrificial materials
327   $a3.1.4. Imprinting and embossing nanofabrication techniques3.1.5. New strategies of nanofabrication; 3.1.5.1. Non-lithographic techniques; 3.1.5.2. Hybrid-material techniques; 3.1.6. Combination of lift-off and lithography; 3.2. Local Surface Modification; 3.2.1. Modification using VUV; 3.2.2. Modification using an electron beam; 3.2.3. Modification using photochemical reaction; 3.3. Bonding; 3.3.1. Introduction; 3.3.2. Wafer bond characterization methods; 3.3.3. Wafer direct bonding; 3.3.4. Wafer direct bonding mechanism; 3.3.5. Surface requirements for wafer direct bonding
327   $a3.3.6. Low temperature direct bonding by surface plasma activation3.3.7. Anodic bonding; References; Chapter 4. Fundamental Technology: Fluidic Control Methods; 4.1. Basic Theory; 4.2. Pressure-Driven Flow; 4.3. Shear-Driven Flow; 4.4. Electrokinetically-Driven Flow; 4.5. Conclusion and Outlook; References; Chapter 5. Fundamental Technology: Detection Methods; 5.1. Single Molecule Detection Methods; 5.1.1. Optical detection methods; 5.1.2. Electrochemical methods; 5.2. Measurement of Fluidic Properties; 5.2.1. Nonintrusive flow measurement techniques
327   $a5.2.1.1. Streaming potential/current measurement in pressure-driven flows5.2.1.2. Current monitoring in electroosmotic flow; 5.2.2. Optical flow imaging techniques using a tracer; 5.2.2.1. Properties of flow tracers; 5.2.2.2. Scalar image velocimetry; 5.2.2.3. Nanoparticle image velocimetry; 5.2.2.4. Laser-induced fluorescence photobleaching anemometer with stimulated emission depletion; References; Chapter 6. Basic Nanoscience; 6.1. Liquid Properties; 6.1.1. Introduction; 6.1.2. Viscosities of liquids confined in extended nanospaces; 6.1.3. Electrical conductivity in extended nanospaces
327   $a6.1.4. Streaming current/potential in extended nanospaces6.1.5. Ion transport in extended nanospaces; 6.1.6. Gas/liquid phase transition phenomena in extended nanospaces; 6.1.7. Structures and dynamics of liquids confined in extended nanospaces; 6.2. Chemical Reaction; 6.2.1. Enzymatic reaction; 6.2.2. Keto-enol tautomeric equilibrium; 6.2.3. Nanoparticle synthesis; 6.2.4. Nano DNA hybridization; 6.2.5. Nano redox reaction; 6.3. Liquid Properties in Intercellular Space; References; Chapter 7. Application to Chemistry and Biotechnology; 7.1. Separation; 7.1.1. Separation by electrophoresis
327   $a7.1.2. Separation by pressure-driven flow or shear-driven flow
330   $aFor the past decade, new research fields utilizing microfluidics have been formed. General micro-integration methods were proposed, and the supporting fundamental technologies were widely developed. These methodologies have made various applications in the fields of analytical and chemical synthesis, and their superior performances such as rapid, simple, and high efficient processing have been proved. Recently, the space is further downscaling to 101-103nm scale (we call the space extended-nano space). The extended-nano space located between the conventional nanotechnology (100-101nm) and micr
606   $aNanofluids
606   $aMicrofluidics
606   $aFluidic devices
615  0$aNanofluids.
615  0$aMicrofluidics.
615  0$aFluidic devices.
676   $a620.106
701   $aTakehiko$b Kitamori$01688999
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910809253803321
996   $aExtended-nanofluidic systems for chemistry and biotechnology$94063672
997   $aUNINA