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Nanoparticle Analysis

Nanoparticle Applications

Nanotechnology is not an industry, but rather a broad based field of study focused on materials and applications occurring at a very small scale. In general most people accept that nanotechnology deals with structures that are 100 nanometers (nm) or smaller and involves developing materials or devices within that size. Tools such as the SZ-100 Nanoparticle Analyzer utilize dynamic light scattering technology to characterize these materials.

Nanotechnology is extremely diverse, ranging from novel extensions of conventional device physics, to completely new approaches based upon molecular self-assembly and to developing new materials with dimensions on the nanoscale. Materials reduced to the nanoscale can show different properties compared to what they exhibit on a macroscale, enabling unique applications.

Visit our What is a Nanoparticle page to read about the scope of nanotechnology.

Particle technology intersects nanotechnology when scientists need to determine the particle size distribution and zeta potential (surface chemistry) of materials in the nanoscale. Examples of particles at the nanoscale that have generated interest include (but certainly not limited to):

  • Carbon nanotubes (see Figure 1)
  • Quantum dots (see Figure 2)
  • Gold nanoparticles
  • Nanoparticles for drug delivery

Figure 1: Carbon Nanotube Structures

 

Figure 2: Quantum Dots Undergoing Fluorescence

Nanoparticle Sizing Techniques and Instruments

Particle size analysis in the range below 100 nm can be performed using a variety of techniques. Within the HORIBA product line the following systems function on the nanoscale:

HORIBA SZ-100 dynamic light scattering system

  • 0.3 nm - 8 µm size measurement range
  • Particle size, zeta potential, molecular weight, A2 all in one system


HORIBA LA-960 laser diffraction system

  • 10 nm - 5,000 µm size measurement range
  • Can measure both below and well above the nanoscale to monitor agglomeration/aggregation and foreign particle contamination


Figure 3 shows the size scale from 1 Angstrom to 1 meter along with the dynamic range of each system mentioned above. As you can see, there is overlap in the sub 100 nm range. Each technique and system has specific advantages depending on the application.

Figure 3: Size Range for Nanoparticle Detection

Fluorescence of Nanoparticles

HORIBA provides several other analytical systems appropriate for nanotechnology applications including the NanoLog Spectrofluorometer for nanomaterials.

> More information on the NanoLog®.

Photoluminescence (PL) excitation-emission matrix of single wall carbon nanotubes (SWCNT) that can be used to obtain diameter information.

Gold Nanoparticle Standards

NIST has recently created a series of gold nanoparticles with certified mean diameters. The three new materials (gold spheres nominally 10, 30 and 60 nanometers in diameter) were developed in cooperation with the National Cancer Institute's Nanotechnology Characterization Laboratory (NCL). RM8011, RM8012 and RM8013 can be purchased from the NIST website and be used to verify the performance of particle size analysis instruments. See NIST Particle Size Standards for a complete list of particle size standards available through NIST.

National Nanotechnology Initiative

The National Nanotechnology Initiative (NNI) is a government program established in 2001 to coordinate federal nanotechnology research and development.

The goals of the NNI include:

  • Advance a world-class nanotechnology research and development program
  • Foster the transfer of new technologies into products for commercial and public benefit
  • Develop and sustain educational resources, a skilled workforce and the supporting infrastructure and tools to advance nanotechnology
  • Support responsible development of nanotechnology

The NNI website provides much useful information for anyone interested in nanotechnology and wishing to learn how the United States is supporting research centers across the country.

Visit the National Nanotechnology Initiative website.

Related Notes

Particle Size Analysis of Gold Nanoparticles
DescriptionGold nanoparticles are of great interest for researchers in many fields. The size distribution of the particles is an important physical characteristic that influences particle behavior. The most common technique to measure the size of gold nanoparticles is DLS. The HORIBA SZ-100 system has proven to be an excellent choice for accurate and reproducible particle size analysis of gold nanoparticles.
Size 0.46 MB
FiletypePDF
Sizing Silica Particles by DLS
DescriptionThe utility of silica nanoparticles is often determined by the particle size. Dynamic light scattering provides fast, accurate and repeatable nanoparticle size information and therefore is an important tool for the nanoparticle technologist. Here, two different size silica particles are characterized with the SZ-100 in order to demonstrate the accuracy and utility of the instrument.
Size 0.57 MB
FiletypePDF

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