Feasibility of the quantification of respirable crystalline silica by mass on aerosol sampling filters using Raman microscopy

Airborne respirable crystalline silica (RCS) is a hazard that can affect the health of workers and more sensitive measurements are needed for the assessment of worker exposure. To investigate the use of Raman microscopy for the analysis of RCS particulate collected on filters, aliquots of quartz or cristobalite suspended in isopropanol were pipetted onto silver filters. Samples were measured by arbitrarily selecting positions along the filter and collecting spectra at 50 discrete points. The calculated limits of quantification on test samples were between ~0.066 – 0.161 µg and 0.106 – 0.218 µg for quartz and cristobalite respectively. Three respirable quartz calibration dusts (A9950, NIST 1878 and Quin B) with different mass median aerodynamic particle sizes obtained similar Raman response relationships per unit mass. The difference between NIST 1878 and Quin B was not significant (p=0.22). The intermediate measurement precision of replicate samples was 10 - 25% over the measured range for quartz (0.25 – 10 µg) and could potentially be improved. Results from mixtures of quartz and cristobalite were within 10 % of their theoretical values. Results from samples of 5 % quartz in calcite were close to the theoretical quartz mass. The upper measurement limit for a mixture of 20 % RCS in the light absorbing mineral hematite (Fe2O3) was 5 µg. These data show that Raman spectroscopy is a viable option for the quantification of the mass of respirable crystalline silica on filters with a limit of detection approaching 1/10th of that obtained with other techniques. The improvement in sensitivity may enable the measurement of particulate in samples from low concentration environments (e.g. inside a mask) or from miniature samplers operating at low flow rates.

[1]  D. Thornton,et al.  Using Raman Microspectroscopy to Determine Chemical Composition and Mixing State of Airborne Marine Aerosols over the Pacific Ocean , 2014 .

[2]  G. Pratesi,et al.  Raman Characterization of Ambient Airborne Soot and Associated Mineral Phases , 2014 .

[3]  Hoeil Chung,et al.  Wide area coverage Raman spectroscopy for reliable quantitative analysis and its applications. , 2013, The Analyst.

[4]  G. Evans,et al.  Occupational cancer burden in Great Britain , 2012, British Journal of Cancer.

[5]  Anna Trakoli IARC Monographs on the Evaluation of Carcinogenic Risks to Humans. Volume 99: Some Aromatic Amines, Organic Dyes, and Related Exposures. International Agency for Research on Cancer , 2012 .

[6]  K. Shinoda,et al.  Quantitative analysis of binary mineral mixtures using Raman microspectroscopy: Calibration curves for silica and calcium carbonate minerals and application to an opaline silica nodule of volcanic origin , 2009 .

[7]  Chantal Dion,et al.  An International comparison of the crystallinity of calibration materials for the analysis of respirable alpha-quartz using X-ray diffraction and a comparison with results from the infrared KBr disc method. , 2009, The Annals of occupational hygiene.

[8]  S. Potgieter-Vermaak,et al.  Preliminary Evaluation of Micro-Raman Spectrometry for the Characterization of Individual Aerosol Particles , 2006, Applied spectroscopy.

[9]  E Hnizdo,et al.  Chronic obstructive pulmonary disease due to occupational exposure to silica dust: a review of epidemiological and pathological evidence , 2003, Occupational and environmental medicine.

[10]  B. Jolliff,et al.  Raman Spectroscopy as a Method for Mineral Identification on Lunar Robotic Exploration Missions , 1995 .

[11]  R. Hemley,et al.  Raman spectroscopic study of microcrystalline silica , 1994 .

[12]  A Seaton,et al.  Control of substances hazardous to health. , 1989, BMJ.