Tissue Engineering And Nanotheranostics

b2815 Tissue Engineering and Nanotheranostics “9.61x6.69”

166 Tissue Engineering and Nanotheranostics

seeds and, therefore, influence the relative proportions of different Ag

seeds. For example, Cl– is a stronger ligand, the Cl–/O 2 pair dissolve

both multiply twinned and singly twinned seeds. Close monitoring of

the reaction process by UV–Visible spectroscopy and electron micros

copy revealed that twinned particles are formed first but later dis

solved by oxidative etching. Thus, after a certain reaction time,

singlecrystal seeds with a spherical profile predominate, and continue

growing into nanocubes with all facets being {100}.72,92 Meanwhile,

Br – is slightly weaker than Cl–, the Br – /O 2 pair will only dissolve mul

tiply twinned seeds, resulting in a right bipyramids dominated

solution.

3.2. Physical Methods

The major challenge of wetsynthesis lies in controlling the position

and orientation of nanoparticles with sufficiently high resolution

when nanoparticles placed on substrates. Unlike chemical synthesis,

lithography, deposition, and other forms of nanofabrication offer pre

cise control over deliberately varied shapes and configurations and

therefore open avenues to both fundamental investigations and appli

cations.^93 Conventional lithographic techniques such as electron beam

lithography (EBL) or focused ion beam lithography (FIB) utilize

polymeric resists to fabricate masks for deposition or etching of metal

with high resolution.94,95 Take EBL for example, a focused electron

beam is scanned over a substrate coated with a thin layer of resist

(EBL usually used PMMA as resist), exposing specific regions accord

ing to a programmed pattern.96,97 Halas and Nordlander et al. utilize

EBL to organize nanostructures with precise size and shape and to

generate complex optical phenomenon like Fano resonance.98–101

4. Technic to Detect Localized Surface

Plasmon Resonance

As a typical plasmon spectroscopy technique, darkfield microscopy

(DFM) coupled with spectrometer was developed for the observation

of metal nanoparticles. The primary advantage of this technique is

Tissue Engineering And Nanotheranostics

seeds and, therefore, influence the relative proportions of different Ag

seeds. For example, Cl– is a stronger ligand, the Cl–/O 2 pair dissolve

both multiply twinned and singly twinned seeds. Close monitoring of

the reaction process by UV–Visible spectroscopy and electron micros

copy revealed that twinned particles are formed first but later dis

solved by oxidative etching. Thus, after a certain reaction time,

singlecrystal seeds with a spherical profile predominate, and continue

growing into nanocubes with all facets being {100}.72,92 Meanwhile,

Br – is slightly weaker than Cl–, the Br – /O 2 pair will only dissolve mul

tiply twinned seeds, resulting in a right bipyramids dominated

solution.

3.2. Physical Methods

The major challenge of wetsynthesis lies in controlling the position

and orientation of nanoparticles with sufficiently high resolution

when nanoparticles placed on substrates. Unlike chemical synthesis,

lithography, deposition, and other forms of nanofabrication offer pre

cise control over deliberately varied shapes and configurations and

therefore open avenues to both fundamental investigations and appli

cations.^93 Conventional lithographic techniques such as electron beam

lithography (EBL) or focused ion beam lithography (FIB) utilize

polymeric resists to fabricate masks for deposition or etching of metal

with high resolution.94,95 Take EBL for example, a focused electron

beam is scanned over a substrate coated with a thin layer of resist

(EBL usually used PMMA as resist), exposing specific regions accord

ing to a programmed pattern.96,97 Halas and Nordlander et al. utilize

EBL to organize nanostructures with precise size and shape and to

generate complex optical phenomenon like Fano resonance.98–101

4. Technic to Detect Localized Surface

Plasmon Resonance

As a typical plasmon spectroscopy technique, darkfield microscopy

(DFM) coupled with spectrometer was developed for the observation

of metal nanoparticles. The primary advantage of this technique is

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Tissue Engineering And Nanotheranostics

seeds and, therefore, influence the relative proportions of different Ag

seeds. For example, Cl– is a stronger ligand, the Cl–/O 2 pair dissolve

both multiply twinned and singly twinned seeds. Close monitoring of

the reaction process by UV–Visible spectroscopy and electron micros­

copy revealed that twinned particles are formed first but later dis­

solved by oxidative etching. Thus, after a certain reaction time,

single­crystal seeds with a spherical profile predominate, and continue

growing into nanocubes with all facets being {100}.72,92 Meanwhile,

Br – is slightly weaker than Cl–, the Br – /O 2 pair will only dissolve mul­

tiply twinned seeds, resulting in a right bipyramids dominated

solution.

3.2. Physical Methods

The major challenge of wet­synthesis lies in controlling the position

and orientation of nanoparticles with sufficiently high resolution

when nanoparticles placed on substrates. Unlike chemical synthesis,

lithography, deposition, and other forms of nanofabrication offer pre­

cise control over deliberately varied shapes and configurations and

therefore open avenues to both fundamental investigations and appli­

cations.^93 Conventional lithographic techniques such as electron beam

lithography (EBL) or focused ion beam lithography (FIB) utilize

polymeric resists to fabricate masks for deposition or etching of metal

with high resolution.94,95 Take EBL for example, a focused electron

beam is scanned over a substrate coated with a thin layer of resist

(EBL usually used PMMA as resist), exposing specific regions accord­

ing to a programmed pattern.96,97 Halas and Nordlander et al. utilize

EBL to organize nanostructures with precise size and shape and to

generate complex optical phenomenon like Fano resonance.98–101

4. Technic to Detect Localized Surface

Plasmon Resonance

As a typical plasmon spectroscopy technique, dark­field microscopy

(DFM) coupled with spectrometer was developed for the observation

of metal nanoparticles. The primary advantage of this technique is

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Company

Features

Documentation

Resources

the reaction process by UV–Visible spectroscopy and electron micros

copy revealed that twinned particles are formed first but later dis

singlecrystal seeds with a spherical profile predominate, and continue

Br – is slightly weaker than Cl–, the Br – /O 2 pair will only dissolve mul

The major challenge of wetsynthesis lies in controlling the position

lithography, deposition, and other forms of nanofabrication offer pre

therefore open avenues to both fundamental investigations and appli

(EBL usually used PMMA as resist), exposing specific regions accord

As a typical plasmon spectroscopy technique, darkfield microscopy