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008 120806s2012 enk o 000 0 eng d
016 7 015956352|2Uk
019 801440805|a870683790|a875271131
020 9781848168022|q(electronic book)
020 1848168020|q(electronic book)
020 9781848168015
020 1848168012
024 8 9786613784162
035 (OCoLC)804661858|z(OCoLC)801440805|z(OCoLC)870683790
|z(OCoLC)875271131
037 378416|bMIL
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049 RIDW
050 4 TJ853.4.M53|bE98 2012eb
072 7 TEC|x021000|2bisacsh
082 04 620.106
090 TJ853.4.M53|bE98 2012eb
245 00 Extended-nanofluidic systems for chemistry and
biotechnology /|cKazuma Mawatari [and others].
264 1 London :|bImperial College Press,|c[2012]
264 4 |c©2012
300 1 online resource (187 pages)
336 text|btxt|2rdacontent
337 computer|bc|2rdamedia
338 online resource|bcr|2rdacarrier
347 text file|2rdaft
500 7.1.2. Separation by pressure-driven flow or shear-driven
flow.
504 Includes bibliographical references and index.
505 0 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.
505 8 3.1.4. 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.
505 8 3.3.6. 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.
505 8 5.2.1.1. 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.
505 8 6.1.4. 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.
520 For 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.
546 Text in English.
588 0 Print version record.
590 eBooks on EBSCOhost|bEBSCO eBook Subscription Academic
Collection - North America
650 0 Nanofluids.|0https://id.loc.gov/authorities/subjects/
sh2007001902
650 0 Biotechnology.|0https://id.loc.gov/authorities/subjects/
sh85014263
650 7 Nanofluids.|2fast|0https://id.worldcat.org/fast/1742507
650 7 Biotechnology.|2fast|0https://id.worldcat.org/fast/832729
655 0 Electronic books.
655 4 Electronic books.
700 1 Mawatari, Kazuma.|0https://id.loc.gov/authorities/names/
nb2012019369
700 1 Tsukahara, Takehiko.
700 1 Kitamori, Takehiko.
776 08 |iPrint version:|aMawatari, Kazuma.|tExtended-Nanofluidic
Systems For Chemistry and Biotechnology.|dSingapore :
World Scientific, ©2012|z9781848168015
856 40 |uhttps://rider.idm.oclc.org/login?url=http://
search.ebscohost.com/login.aspx?direct=true&scope=site&
db=nlebk&AN=479876|zOnline eBook. Access restricted to
current Rider University students, faculty, and staff.
856 42 |3Instructions for reading/downloading this eBook|uhttp://
guides.rider.edu/ebooks/ebsco
901 MARCIVE 20231220
948 |d20160607|cEBSCO|tebscoebooksacademic|lridw
994 92|bRID
