AAAR 37th Annual Conference October 14 - October 18, 2019 Oregon Convention Center Portland, Oregon, USA
Abstract View
Real-Time Measurement of Airborne Carbon Nanotubes
Lina Zheng, PRAMOD KULKARNI, Centers for Disease Control and Prevention, NIOSH
Abstract Number: 839 Working Group: Instrumentation and Methods
Abstract With growing applications of carbon nanomaterials, there is a concern over health risks presented by inhalation of carbon nanotube (CNT) aerosol in workplace atmospheres. Current methods used for CNT aerosol measurement lack selectivity to the specific form of carbonaceous component or allotrope of interest. Moreover, the detection limits of these methods are also inadequate for short-term monitoring. Here, we describe, for the first time, a near real-time, field-portable instrument for selective quantification of airborne CNT concentration. The approach uses an automated cyclical scheme involving collect-analyze-ablate steps to obtain continuous near real-time measurement using Raman spectroscopy. The method achieves significantly lower detection limits by employing corona-assisted particle microconcentration for efficient coupling with laser Raman spectroscopy. A combination of techniques involving: i) use of characteristic Raman peaks, ii) distinct ratio of disordered and graphitic peaks, and iii) principal component classification and regression is employed to identify and quantify the specific form of the aerosolized carbonaceous nanomaterial. We show that the approach is capable of selectively quantifying trace single-walled CNT in the presence of interferents such as diesel particulate matter. The detection limit of the method for single-walled CNTs was 60 ng m-3, corresponding to a 10-min aerosol collection period, which is significantly lower than that for the NIOSH Method 5040 (~0.15 µg m-3 for an 8-hour collection on a 25-mm filter at 4 L min-1), a commonly used method for elemental carbon. We demonstrate the automated real-time capability of this field-portable method by continuously measuring a transient single-walled CNT aerosol.