Release characteristics of single-wall carbon nanotubes during manufacturing and handling

“…Collecting end-product materials from chemical synthesis [23]; batch collection by industrial cyclone [24]; emptying and tipping powder materials from bucket to bucket [25]; scooping spilt materials off a table [25]; opening a furnace and transferring materials to vials [6]; manually loading and unloading trays [6]; dumping materials into a mixing tank [6]; detaching and removing CNTs from growth substrate using a razor blade [26]; sieving powders with a vibratory sieve shaker [27,28] Physical & chemical synthesis Gas-phase production of metal-based nanoparticles [29]; flame spray pyrolysis technique (FSP) [30,31]; induced coupled plasma with electric atomizer [32,33]; reaction collection [23]; electric arc reaction [34]; hot-wall reaction [19]; combustion reaction [35]; chemical vapor deposition (CVD) [26,[36][37][38][39]; water-assisted CVD [40] Weighing & mixing…”

“…Spraying and filtration of CNT solutions [37]; spraying solution onto a bulk absorbent [6]; changing a spray dryer drum [6]; spraying a suspension [9]; flame-spraying for surface coating and modification [50]; sonicating materials with different surface coatings in a hood [6]; sonication in an unventilated enclosure [7]; pelletizing and bagging products in a warehouse [51]; purification and functionalization [47] integrating MWCNT powder in coatings, dispersions, and plastics [52] [53], Al2O3 [53], CeO2 [53], iron oxides [6], Mn [6], Ag [6,54], Co [6], Si [19]; Carbonaceous: carbon black [23], CNT [26], SWCNT [25,40,55], MWCNT [6,28,37,47], carbon nanofibers (CNFs) [6,48], carbon nanopearls [6], nano diamond [27], carbon nanodiscs/carbon nanocones [28], nanoscale graphene platelets [56].…”

Airborne engineered nanomaterials in the workplace—a review of release and worker exposure during nanomaterial production and handling processes

“…Collecting end-product materials from chemical synthesis [23]; batch collection by industrial cyclone [24]; emptying and tipping powder materials from bucket to bucket [25]; scooping spilt materials off a table [25]; opening a furnace and transferring materials to vials [6]; manually loading and unloading trays [6]; dumping materials into a mixing tank [6]; detaching and removing CNTs from growth substrate using a razor blade [26]; sieving powders with a vibratory sieve shaker [27,28] Physical & chemical synthesis Gas-phase production of metal-based nanoparticles [29]; flame spray pyrolysis technique (FSP) [30,31]; induced coupled plasma with electric atomizer [32,33]; reaction collection [23]; electric arc reaction [34]; hot-wall reaction [19]; combustion reaction [35]; chemical vapor deposition (CVD) [26,[36][37][38][39]; water-assisted CVD [40] Weighing & mixing…”

“…Spraying and filtration of CNT solutions [37]; spraying solution onto a bulk absorbent [6]; changing a spray dryer drum [6]; spraying a suspension [9]; flame-spraying for surface coating and modification [50]; sonicating materials with different surface coatings in a hood [6]; sonication in an unventilated enclosure [7]; pelletizing and bagging products in a warehouse [51]; purification and functionalization [47] integrating MWCNT powder in coatings, dispersions, and plastics [52] [53], Al2O3 [53], CeO2 [53], iron oxides [6], Mn [6], Ag [6,54], Co [6], Si [19]; Carbonaceous: carbon black [23], CNT [26], SWCNT [25,40,55], MWCNT [6,28,37,47], carbon nanofibers (CNFs) [6,48], carbon nanopearls [6], nano diamond [27], carbon nanodiscs/carbon nanocones [28], nanoscale graphene platelets [56].…”

Airborne engineered nanomaterials in the workplace—a review of release and worker exposure during nanomaterial production and handling processes

“…In the case of carbon nanotubes, various accounts of release during synthesis can be found in the literature [164], including an increase in peak concentration at CVD extraction points [60], while others report no emission [160]. If exposure to airborne individual carbon nanotubes cannot be excluded, they generally occur as agglomerates or aggregate Overview of Workplace Exposure to Nanomaterials Table 4 List of published studies on occupational exposure to various types of engineered and incidental nanomaterials (P: production; D: downstream manipulation; U: use as input material in industrial processes; M: maintenance and end-of-life operations; I: incidental) clusters [1].…”

“…Indeed, depending on the degree of agitation, large variations in the emitted particle size are obtained [136]. It may be noted that good correlations were obtained for particle size distribution profile between transfer, harvesting, and packing operations and vortex shaking laboratory tests [160]. An increase from 1% to 12% in the amount of emitted nanoparticles was observed when the pressure was raised from 0 to 140 kPa in a pressurized beaker experiment simulating a leak.…”

Overview of Workplace Exposure to Nanomaterials

“…This indicates a potential hazard for workers handling MWCNTs. CNTs released in workplaces are often determined using thermal carbon analysis methods, such as National Institute for Occupational Safety and Health (NIOSH) method 5040 [5][6][7][8][9][10] or the IMPROVE protocol 11) , also used for quantifying CNTs [12][13][14][15] . In addition, by measuring respirable-sized MWCNT dust using both a black carbon monitor (BCM) and thermal carbon analysis, a relationship between the analytical methods was detected 16) .…”

Exposure assessment of carbon nanotubes at pilot factory focusing on quantitative determination of catalytic metals