1.1 WHY A BOOK ON NANOTECHNOLOGY HEALTH AND SAFETY?

The spectre of possible harm—whether real or imagined—is threatening to slow the development of nanotechnology unless sound, independent and authoritative information is developed on what the risks are, and how to avoid them. In what may be unprecedented pre-emptive action in the face of a new technology, governments, industries and research organizations around the world are beginning to address how the benefits of emerging nanotechnologies can be realized while minimizing potential risks.

1.2 SOME SCENARIOS

• A small company specializes in the manufacture of relatively small quantities of high-quality powders in the micrometer size range for specialized niche markets. The company is too small to employ a person with health and safety training. The company president wishes to modify their production equipment to produce powders in the nanometer size range but has read of general concerns about the safety of nanoparticles. He asks his production manager to find out whether manufacturing nanopowders will present any new hazards to their workers.
• A university laboratory is conducting research on the use of carbon nanotubes (CNTs) as a new form of digital storage device. As part of this research, the laboratory technician must transfer small quantities of dry bulk CNTs from a 2 L jar to a beaker, weigh them on a balance, and disperse them in a solvent. These steps are now done on a laboratory bench, and the technician is concerned that she may be breathing in some CNTs that are being released from the powder.
• A plastics manufacturing company has recently begun pilot-scale testing of a new composite material, consisting of polyester reinforced with 2% by mass of alumina nanoparticles. The composite is produced in a twin-screw extruder. The polymer pellets are dumped into one hopper and the nanoalumina in another; they are fed by gravity into the throat of the extruder, where the pellets are melted by high temperature and pressure and mixed with the nanoalumina to form the nanocomposite. The extruder operator has noticed some of the alumina powder on various work surfaces around the hopper and is concerned that this may not be completely safe.
• A company uses the nanocomposite material produced above to make tennis racket frames. The pellets are fed into an injection molding machine which produces the tennis racket shape. However, extraneous material has to be cut off the frame with a saw and the frame must be sanded smooth. The plant occupational hygienist is concerned that these operations may release nanoparticles. In addition, the tennis racket manufacturer labels the product “contains nanomaterials for added strength” and is receiving anxious questions from consumers on their web site.
• An occupational hygienist working in the health and safety office at a large research university conducted a university-wide survey which found that more than 50 laboratories across the university claimed to be doing research with some type of nanoparticle. Many of the respondents stated that they did not know what practices should be followed when working with nanoparticles; the occupational hygienist decided that the university needed a policy on good work practices but he did not know how he would gather the information to develop such a policy.
• A research laboratory recently purchased a chemical vapor deposition furnace for making CNTs. While the furnace is a closed system during CNT production, at the end of a run, it must be opened and the CNT material must be scraped from the furnace walls into a drum. This process creates visible dust, which has caused the operator some anxiety.
• A research laboratory was working with quantum dots suspended in a solvent. During normal operations, the laboratory director was fairly confident that no nanoparticle exposure was occurring, since the particles were in liquid suspension. One day, however, a technician dropped a beaker containing the nanoparticle suspension, and the beaker shattered when it hit the floor. Since the laboratory had no emergency response plan in place, the laboratory director was unsure what steps to take to clean up the spill. She decided to evacuate all personnel from the lab, waited until the solvent had completely evaporated, swept up the broken glass and placed it in the lab’s broken glass receptacle. The workers were then allowed back in the lab.

• Uncertainty as to the adverse health effects, if any, associated with using a nanomaterial;
• Uncertainty as to the level of worker exposure, if any, from using a nanomaterial; and
• Uncertainty as to what steps (control methods) should be taken to ensure that worker exposures are controlled to an acceptable level.

1.3 ORGANIZATION OF THE MATERIAL