Nanoscience and nanotechnology are the study and application of extremely small things and can be used across all the other science fields, such as chemistry, biology, physics, materials science, and engineering. In the International System of Units, the prefix “nano” means one billionth, (or 10^-9) of a meter. The Figure 1 illustrates clearly the nanoscale.

Figure 1. The « Nano » scale.

Nanoparticles are abundant in nature, as they are produced in many natural processes, including photochemical reactions, volcanic eruptions, forest fires, simple erosion and by plants and animals. Any groups of atoms or molecules present in nature have a “nano” size such as amino acids, proteins, DNA, viruses, etc. Those are organic molecules with carbon atoms, hydrogen atoms and oxygen atoms mainly.

In fact, each material “exists” at the nanoscale. During a long time, humans have not been able to produce with a sufficient control material at nanoscale such as nature is doing since millions of years. Other sources of nanoparticles can be identified and originates from the man-made activity such as incidental nanoparticles generated as unwanted by-products from combustion processes (e.g.: charcoal burning, incinerators,…).

Materials at nanoscale behave differently than at macroscale and nanoparticles often presents incredible properties based on “quantum effects” and other simple physical effects such as expanded surface area. The integration of the nanoparticles inside a matrix leads to improve specific properties depending on the nature of the nanoparticles and the matrix in which the nanoparticles are integrated (polycarbonates, polystyrene, polyethylene, natural rubber, polyurethane, epoxies, etc.). Each type of nanoparticle will improve a different set of properties (electrical, mechanical, thermal, etc.).

Figure 2. Sources of nanoparticles.

In summary, “nano” is just a question of size and not of material or composition.

The definition of a nanomaterial does not make the consensus yet. In 2011, the European Commission adopted a recommendation on the definition of a nanomaterial in 3 steps [COMMISSION RECOMMENDATION of 18 October 2011 on the definition of nanomaterial(Text with EEA relevance) (2011/696/EU)]:

• a natural, incidental or manufactured material
• That contains particles, in an unbound state or as an aggregate or as an agglomerate
• and where, for 50% or more of the particles in the number size distribution, one or more external dimensions is in the size range 1 nm – 100 nm.”

It is finally quite recently that humans have developed techniques for manufacturing nanoparticles in a controllable and reproducible way; what are called today engineered nanoparticles (“ENP”).

Figure 3 illustrates that nanoparticles look very different. Spheres, rods, fibers, stars, cups,… are various shapes that have been identified.

Figure 3. Different material shapes at the nanoscale. From left to right: spherical gold nanoparticles, carbon blacks agglomerates, silicone oxide stars, nanofibrils of cellulose.

The Figure 4 presents different carbon materials at the nanoscale. Those materials are only composed of carbon atoms but their primary structure is very different.

3D carbon atoms layout could lead to various structures such as nanodiamond, graphite (several hundreds of layers of graphene), carbon blacks, tubular carbon nanotubes, graphene layer (1D material), fullerene, carbon fibers etc.

• 
  Nanodiamond
• 
  Fullerene C60
• 
  SWNT
• 
  MWNT
• 
  Graphene

Figure 4. Main carbon allotropes.
Source: “Environmental Applications of Carbon-Based Nanomaterials”, Environmental Science & Technology, 42, 5843 (2008)

Those primary structures represent the different possibilities of perfect carbon atoms layout. In reality, carbon allotropes contain defects and agglomerates of carbon allotropes slighty differ from their primary structure. Carbon black agglomerates have various complex and stochastic 3D structures. NC7000™ multiwall carbon nanotube (MWCNT) agglomerates have a spaghetti-like structure.

Depending on the manufacturing parameters and processes, a large variety of multiwall carbon nanotubes structures can be produced. Those structures differ in the following parameters:

1. Size and shape: Length, diameter, state of aggregates/agglomerates, number of walls, flexibility…
2. Surface chemistry: functionnalization, capped or uncapped…
3. Purity level: metallic contaminants, molecules adsorbed onto the particle…

Concerns have been raised about a similarity between MWCNTs and asbestos. MWCNTs form a large family of products differing in terms of structure, length, shape, diameter, state of agglomeration.

Figure 5 illustrates the variety of multiwall carbon nanotubes and compares them to asbestos. Asbestos fibers are very sharp long fibers. Long and straight MWCNTs look like asbestos and has raised health questions (Mitsui MWNT-7). However, a vast majority of commercial MWCNTS are curvy/curled, entangled and short and do not show asbestos like forms. In fact NC7000 and hyperion fibrils are representative of this class of not-asbestos like materials.

Figure 5. Variety of multiwall carbon nanotubes structures.  NC7000™ MWCNT agglomerates, Hyperion fibrils MWCNT agglomerates, Mitsui MWCNT-7 MWCNT and Asbestos.

In conclusion, multiwall carbon nanotubes are extremely various materials and their toxicological profiles (hazard) have to be assessed on case by case basis. Therefore, results of toxicological profiles (hazard) assessment achieved with NC7000™ cannot be extrapolated for other multiwall carbon nanotubes.