11
[13] Page, S.J., Volkwein, J.C, Vinson, R.P., Joy, G.J.,
Mischler, S.E., Tuchman, D.P., and McWilliams,
L.J.. 2008. “Equivalency of a Personal Dust Monitor
to the Current United States Coal Mine Respirable
Dust Sampler.” Journal of Environmental Monitoring
:JEM 10 (1): 96–101. doi.org/10.1039/b714381h.
[14] MSHA 2010. “Coal Mine Dust Sampling Devices”
Federal Register, Vol. 75, No. 65, pp. 17512–17529.
[15] U.S. Department of Health and Human Services,
Centers for Disease Control and Prevention, National
Institute for Occupational Safety and Health, letter
from Steven E. Mischler et al. to Alan Matta, Product
Manager, Air Quality Instruments, Thermo Fisher
Scientific, Inc., re: Approval of the Model PDM 3600
TEOM instrument, dated September 6, 2011.
[16] MSHA 2014. “Lowering Miners’ Exposure to
Respirable Coal Mine Dust, Including Continuous
Personal Dust Monitors” Federal Register, Vol. 79,
No. 84, pp 24813–24994.
[17] Thermo Fisher Scientific, 2014. “Model PDM3700,
Personal Dust Monitor.” (Franklin, MA: Thermo
Fisher Scientific, Air Quality Instruments).
[18] MSHA 2013. “Standard Method No. P7, Infrared
Determination of Quartz in Respirable Coal Mine
Dust.”
[19] NIOSH, 2020. NIOSH Manual of Analytical
Methods (NMAM), 5th Edition. Web book: www
.cdc.gov/niosh/nmam.
[20] Ainsworth, S.M. 2005. “Infrared Analysis of
Respirable Coal Mine Dust for Quartz: Thirty-Five
Years.” Journal of ASTM International 2(4): 12231.
doi:10.1520/JAI12231.
[21] Larsen, D.J., Von Doenhoff, L.J., and Crable, J.V.
1972. “The Quantitative Dermination of Quartz
in Coal Dust by Infrared Spectroscopy,” American
Industrial Hygiene Association Journal, 33:6, 367–
372, doi: 10.1080/0002889728506666.
[22] Huggins, C.W., Shedd, K.B., Snyder, J.G.,
Lang, H.W., and Tomb, T.F. 1985. “Interagency
Comparison of Respirable Quartz Analysis,” U.S.
Department of the Interior, Bureau of Mines Open
File Report 111-85.
[23] Anderson, C.C., 1983. “Collaborative Tests of Two
Methods for Determining Free Silica in Airborne
Dust,” SRI International, U.S. Department of Health
and Human Services, Cincinnati, OH.
[24] OSHA, 2016. “Crystalline Silica Quartz and
Cristobalite, Method ID-142.” Sampling and
Analytical Methods. www.osha.gov/chemicaldata
/sampling-analytical-methods.
[25] Tuchman, D.P., 1992 “Research Toward Direct
Analysis of Quartz Dust on Filters Using FTIR
Spectroscopy.” USBM Informational Circular 9309.
(Pittsburgh, PA: U.S. Department of the Interior,
U.S. Bureau of Mines).
[26] Tuchman, D.P., Volkwein, J.C., and Vinson, R.P..
2008. “Implementing Infrared Determination of
Quartz Particulates on Novel Filters for a Prototype
Dust Monitor.” Journal of Environmental Monitoring
10 (5): 671–78. doi.org/10.1039/b803804j.
[27] Miller, A.L., Drake, P.L., Murphy, N.C., Noll, J
D., and Volkwein, J.C. 2012. “Evaluating Portable
Infrared Spectrometers for Measuring the Silica
Content of Coal” Dust. J. Environ. Monit., 14(1):
48–55. doi: 10.1039/c1em10678c.
[28] Miller, A.L., Drake, P.L., Murphy, N.C., Cauda,
E.G., LeBouf, R.F., and Markevicius, G. 2013.
“Deposition Uniformity of Coal Dust on Filters
and Its Effect on the Accuracy of FTIR Analyses for
Silica,” Aerosol Science and Technology, 47:7, 724–
733. doi: 10.1080/02786826.2013.787157.
[29] Weakley A.T., Miller A.L., Griffiths P.R., Bayman S.J.
2014. “Quantifying silica in filter-deposited mine
dusts using infrared spectra and partial least squares
regression.” Anal Bioanal Chem. Jul 406(19):4715–
24. doi: 10.1007/s00216-014-7856-y.
[30] Miller, A.L., Murphy, N.C., Bayman, S.J., Briggs,
Z.P., Kilpatrick, A.D., Quinn, C.A., Wadas, M.R.,
Cauda, E.G., and Griffiths, P.R. 2015. “Evaluation
of Diffuse Reflection Infrared Spectrometry for
End-of-Shift Measurement of α-quartz in Coal
Dust Samples,” Journal of Occupational and
Environmental Hygiene, 12:7, 421–430, doi:
10.1080/15459624.2015.1011328.
[31] Miller A.L., Weakley A.T., Griffiths P.R., Cauda
E.G., Bayman, S. 2017. “Direct-on-Filter α-Quartz
Estimation in Respirable Coal Mine Dust
Using Transmission Fourier Transform Infrared
Spectrometry and Partial Least Squares Regression.”
Appl Spectrosc. 2017 May 71(5):1014–1024. doi:
10.1177/0003702816666288.
[32] NIOSH. 2021. “FAST -Field Analysis of Silica
Tool” by Cauda, E., Chubb, L., Britton, J., Fritz, J.,
and Cole, G., (Pittsburgh, PA: U.S. Department of
Health and Human Services, Public Health Service,
Centers for Disease Control and Prevention, National
Institute for Occupational Safety and Health) DHHS
(NIOSH) Publication No. 2021-118, 2021 Jun
:software.
[13] Page, S.J., Volkwein, J.C, Vinson, R.P., Joy, G.J.,
Mischler, S.E., Tuchman, D.P., and McWilliams,
L.J.. 2008. “Equivalency of a Personal Dust Monitor
to the Current United States Coal Mine Respirable
Dust Sampler.” Journal of Environmental Monitoring
:JEM 10 (1): 96–101. doi.org/10.1039/b714381h.
[14] MSHA 2010. “Coal Mine Dust Sampling Devices”
Federal Register, Vol. 75, No. 65, pp. 17512–17529.
[15] U.S. Department of Health and Human Services,
Centers for Disease Control and Prevention, National
Institute for Occupational Safety and Health, letter
from Steven E. Mischler et al. to Alan Matta, Product
Manager, Air Quality Instruments, Thermo Fisher
Scientific, Inc., re: Approval of the Model PDM 3600
TEOM instrument, dated September 6, 2011.
[16] MSHA 2014. “Lowering Miners’ Exposure to
Respirable Coal Mine Dust, Including Continuous
Personal Dust Monitors” Federal Register, Vol. 79,
No. 84, pp 24813–24994.
[17] Thermo Fisher Scientific, 2014. “Model PDM3700,
Personal Dust Monitor.” (Franklin, MA: Thermo
Fisher Scientific, Air Quality Instruments).
[18] MSHA 2013. “Standard Method No. P7, Infrared
Determination of Quartz in Respirable Coal Mine
Dust.”
[19] NIOSH, 2020. NIOSH Manual of Analytical
Methods (NMAM), 5th Edition. Web book: www
.cdc.gov/niosh/nmam.
[20] Ainsworth, S.M. 2005. “Infrared Analysis of
Respirable Coal Mine Dust for Quartz: Thirty-Five
Years.” Journal of ASTM International 2(4): 12231.
doi:10.1520/JAI12231.
[21] Larsen, D.J., Von Doenhoff, L.J., and Crable, J.V.
1972. “The Quantitative Dermination of Quartz
in Coal Dust by Infrared Spectroscopy,” American
Industrial Hygiene Association Journal, 33:6, 367–
372, doi: 10.1080/0002889728506666.
[22] Huggins, C.W., Shedd, K.B., Snyder, J.G.,
Lang, H.W., and Tomb, T.F. 1985. “Interagency
Comparison of Respirable Quartz Analysis,” U.S.
Department of the Interior, Bureau of Mines Open
File Report 111-85.
[23] Anderson, C.C., 1983. “Collaborative Tests of Two
Methods for Determining Free Silica in Airborne
Dust,” SRI International, U.S. Department of Health
and Human Services, Cincinnati, OH.
[24] OSHA, 2016. “Crystalline Silica Quartz and
Cristobalite, Method ID-142.” Sampling and
Analytical Methods. www.osha.gov/chemicaldata
/sampling-analytical-methods.
[25] Tuchman, D.P., 1992 “Research Toward Direct
Analysis of Quartz Dust on Filters Using FTIR
Spectroscopy.” USBM Informational Circular 9309.
(Pittsburgh, PA: U.S. Department of the Interior,
U.S. Bureau of Mines).
[26] Tuchman, D.P., Volkwein, J.C., and Vinson, R.P..
2008. “Implementing Infrared Determination of
Quartz Particulates on Novel Filters for a Prototype
Dust Monitor.” Journal of Environmental Monitoring
10 (5): 671–78. doi.org/10.1039/b803804j.
[27] Miller, A.L., Drake, P.L., Murphy, N.C., Noll, J
D., and Volkwein, J.C. 2012. “Evaluating Portable
Infrared Spectrometers for Measuring the Silica
Content of Coal” Dust. J. Environ. Monit., 14(1):
48–55. doi: 10.1039/c1em10678c.
[28] Miller, A.L., Drake, P.L., Murphy, N.C., Cauda,
E.G., LeBouf, R.F., and Markevicius, G. 2013.
“Deposition Uniformity of Coal Dust on Filters
and Its Effect on the Accuracy of FTIR Analyses for
Silica,” Aerosol Science and Technology, 47:7, 724–
733. doi: 10.1080/02786826.2013.787157.
[29] Weakley A.T., Miller A.L., Griffiths P.R., Bayman S.J.
2014. “Quantifying silica in filter-deposited mine
dusts using infrared spectra and partial least squares
regression.” Anal Bioanal Chem. Jul 406(19):4715–
24. doi: 10.1007/s00216-014-7856-y.
[30] Miller, A.L., Murphy, N.C., Bayman, S.J., Briggs,
Z.P., Kilpatrick, A.D., Quinn, C.A., Wadas, M.R.,
Cauda, E.G., and Griffiths, P.R. 2015. “Evaluation
of Diffuse Reflection Infrared Spectrometry for
End-of-Shift Measurement of α-quartz in Coal
Dust Samples,” Journal of Occupational and
Environmental Hygiene, 12:7, 421–430, doi:
10.1080/15459624.2015.1011328.
[31] Miller A.L., Weakley A.T., Griffiths P.R., Cauda
E.G., Bayman, S. 2017. “Direct-on-Filter α-Quartz
Estimation in Respirable Coal Mine Dust
Using Transmission Fourier Transform Infrared
Spectrometry and Partial Least Squares Regression.”
Appl Spectrosc. 2017 May 71(5):1014–1024. doi:
10.1177/0003702816666288.
[32] NIOSH. 2021. “FAST -Field Analysis of Silica
Tool” by Cauda, E., Chubb, L., Britton, J., Fritz, J.,
and Cole, G., (Pittsburgh, PA: U.S. Department of
Health and Human Services, Public Health Service,
Centers for Disease Control and Prevention, National
Institute for Occupational Safety and Health) DHHS
(NIOSH) Publication No. 2021-118, 2021 Jun
:software.