7
[10] Azam, S., V. Kurashov, J.H. Golbeck, S. Bhattacharyya,
S. Zheng, and S. Liu (2023), “Comparative studies of
environmentally persistent free radicals on nano-sized
coal dusts,” Science of the Total Environment, 878,
163163.
[11] LaBranche, N., C. Keles, E. Sarver, K. Johnstone,
and D. Cliff (2021), “Characterization of Particulates
from Australian Underground Coal Mines,” Minerals,
11, 447.
[12] Li, M, R. Wang, G. Li, X, Song, H. Yang, and H. Lai
(2022), “Comprehensive Chemical Dust Suppressant
Performance Evaluation and Optimization Method,”
Int. J. Environ. Res. Public Health, 19, 5617.
[13] National Institute for Occupations Safety and Health
(2023), Minng Program, www.cdc.gov/niosh/mining
/researchprogram/index.html, accessed 11/16/23.
[14] Mine Safety and Health Administration (2023),
Respirable Crystalline Silica, Notice of Rule Making,
www.msha.gov/regulations/rulemaking/silica,
accessed 11/13/2023.
[15] Deng, Y., L. Xu, H. Lu, H. Wang, and Y. Shi (2018),
“Direct measurement of the contact angle of water
droplet on quartz in a reservoir rock with atomic
force microscopy,” Chemical Engineering Science
177, 445–454.
[16] Szyszka, D. (2012), “Study of contact angle of liquid
on solid surface and solid on liquid surface,” Mining
Science 135, 131–146.
[17] Kowalczyk, D., S. Slomkowski, M.M. Chehimi, and
M. Delamar (1996), “Adsorption of aminopropyl-
triethoxy silane on quartz: an XPS and contact angle
measurements study,” International journal of adhe-
sion and adhesives 16 (4), 227–232.
[18] Janczuk, B. and A. Zdziennicka (1994), “A study on
the components of surface free energy of quartz from
contact angle measurements,” Journal of materials
science 29 (13), 3559–3564.
[19] Xie, R., Y. Zhu, J. Liu, and Y. Li (2021), “A self-
assembly mixed collector system and the mechanism
for the flotation separation of spodumene from feld-
spar and quartz,” Minerals Engineering 171, 107082.
[20] Vidyadhar, A., N. Kumari, and R. P. Bhagat (2012),
“Flotation of quartz and hematite: adsorption mecha-
nism of mixed cationic/anionic collector systems,”
XXVI International Mineral Processing Congress,
New Delhi, India, 244–251.
[21] Zhao, Y., W. Xu, G. Mei, M. Yu, S. Yang, and Z.
He (2022), “Flotation separation of quartz from
phosphorite using an imidazole ionic liquid collec-
tor and its adsorption mechanism,” Physicochemical
Problems of Mineral Processing 58.
[22] Yukselen-Aksoy, Y. and A. Kaya, (2011), “A study of
factors affecting the zeta potential of kaolinite and
quartz powder.” Environmental Earth Sciences 62
(4), 697–705.
[23] Arnold, B.J. (1995), A Guide to Coal Handling,
Electric Power Research Institute, TR-105110, Final
Report.
[24] Finch, J., N. Sendler, and B. Uytiepo (1993), “Coal
Dust Suppression Using Residual Foam Technology,”
Coal Handling Systems: State of the Art III, Pensacola,
FL, Electric Power Research Institute.
[25] duPlessis, J.J.L. (2016), “Effectiveness of applying
dust suppression palliatives on haul roads,” Journal
of the Mine Ventilation Society of South Africa, June,
pp. 15–19.
[26] Piechota, T., J van Ee, J. Batista, K. Stave, and D.
James (2002), “Potential Environmental Impacts of
Dust Suppressants: Avoiding Another Times Beach,”
EPA/600/R-04/031.
[27] Zhao, Z., P. Chang, G. Xu, Q. Xie, and A. Ghosh
(2022), “Comparison of static tests and dynamic tests
for coal dust surfactants evaluation: A review,” Fuel,
330, 125625.
[28] Roe, D.C. (1992), “Laboratory Techniques for
Evaluating Chemical Dust Control Programs,” Coal
Handling Systems: State of the Art II, Pensacola, FL,
Electric Power Research Institute, TR-100828.
[29] Xu, G., Y. Chen, J. Eksteen, and J. Xu (2018),
“Surfactant-aided coal dust suppression: A Review of
evaluation methods and influencing factors,” Science
of the Total Environment, 639, 1060–1076.
[30] Arnold, B.J., S. Bhattacharyya, M. Rezaee, S. Azam,
A. Eskanlou (2023), Reduction or Elimination of
Coal Mining Related Respirable Dust Toxicity by
Selection and Proper Application of Dust Control
Additives, NIOSH BAA: 75D301-21-R-71744,
Milestone Report 2, submitted October 31, 2023.
[10] Azam, S., V. Kurashov, J.H. Golbeck, S. Bhattacharyya,
S. Zheng, and S. Liu (2023), “Comparative studies of
environmentally persistent free radicals on nano-sized
coal dusts,” Science of the Total Environment, 878,
163163.
[11] LaBranche, N., C. Keles, E. Sarver, K. Johnstone,
and D. Cliff (2021), “Characterization of Particulates
from Australian Underground Coal Mines,” Minerals,
11, 447.
[12] Li, M, R. Wang, G. Li, X, Song, H. Yang, and H. Lai
(2022), “Comprehensive Chemical Dust Suppressant
Performance Evaluation and Optimization Method,”
Int. J. Environ. Res. Public Health, 19, 5617.
[13] National Institute for Occupations Safety and Health
(2023), Minng Program, www.cdc.gov/niosh/mining
/researchprogram/index.html, accessed 11/16/23.
[14] Mine Safety and Health Administration (2023),
Respirable Crystalline Silica, Notice of Rule Making,
www.msha.gov/regulations/rulemaking/silica,
accessed 11/13/2023.
[15] Deng, Y., L. Xu, H. Lu, H. Wang, and Y. Shi (2018),
“Direct measurement of the contact angle of water
droplet on quartz in a reservoir rock with atomic
force microscopy,” Chemical Engineering Science
177, 445–454.
[16] Szyszka, D. (2012), “Study of contact angle of liquid
on solid surface and solid on liquid surface,” Mining
Science 135, 131–146.
[17] Kowalczyk, D., S. Slomkowski, M.M. Chehimi, and
M. Delamar (1996), “Adsorption of aminopropyl-
triethoxy silane on quartz: an XPS and contact angle
measurements study,” International journal of adhe-
sion and adhesives 16 (4), 227–232.
[18] Janczuk, B. and A. Zdziennicka (1994), “A study on
the components of surface free energy of quartz from
contact angle measurements,” Journal of materials
science 29 (13), 3559–3564.
[19] Xie, R., Y. Zhu, J. Liu, and Y. Li (2021), “A self-
assembly mixed collector system and the mechanism
for the flotation separation of spodumene from feld-
spar and quartz,” Minerals Engineering 171, 107082.
[20] Vidyadhar, A., N. Kumari, and R. P. Bhagat (2012),
“Flotation of quartz and hematite: adsorption mecha-
nism of mixed cationic/anionic collector systems,”
XXVI International Mineral Processing Congress,
New Delhi, India, 244–251.
[21] Zhao, Y., W. Xu, G. Mei, M. Yu, S. Yang, and Z.
He (2022), “Flotation separation of quartz from
phosphorite using an imidazole ionic liquid collec-
tor and its adsorption mechanism,” Physicochemical
Problems of Mineral Processing 58.
[22] Yukselen-Aksoy, Y. and A. Kaya, (2011), “A study of
factors affecting the zeta potential of kaolinite and
quartz powder.” Environmental Earth Sciences 62
(4), 697–705.
[23] Arnold, B.J. (1995), A Guide to Coal Handling,
Electric Power Research Institute, TR-105110, Final
Report.
[24] Finch, J., N. Sendler, and B. Uytiepo (1993), “Coal
Dust Suppression Using Residual Foam Technology,”
Coal Handling Systems: State of the Art III, Pensacola,
FL, Electric Power Research Institute.
[25] duPlessis, J.J.L. (2016), “Effectiveness of applying
dust suppression palliatives on haul roads,” Journal
of the Mine Ventilation Society of South Africa, June,
pp. 15–19.
[26] Piechota, T., J van Ee, J. Batista, K. Stave, and D.
James (2002), “Potential Environmental Impacts of
Dust Suppressants: Avoiding Another Times Beach,”
EPA/600/R-04/031.
[27] Zhao, Z., P. Chang, G. Xu, Q. Xie, and A. Ghosh
(2022), “Comparison of static tests and dynamic tests
for coal dust surfactants evaluation: A review,” Fuel,
330, 125625.
[28] Roe, D.C. (1992), “Laboratory Techniques for
Evaluating Chemical Dust Control Programs,” Coal
Handling Systems: State of the Art II, Pensacola, FL,
Electric Power Research Institute, TR-100828.
[29] Xu, G., Y. Chen, J. Eksteen, and J. Xu (2018),
“Surfactant-aided coal dust suppression: A Review of
evaluation methods and influencing factors,” Science
of the Total Environment, 639, 1060–1076.
[30] Arnold, B.J., S. Bhattacharyya, M. Rezaee, S. Azam,
A. Eskanlou (2023), Reduction or Elimination of
Coal Mining Related Respirable Dust Toxicity by
Selection and Proper Application of Dust Control
Additives, NIOSH BAA: 75D301-21-R-71744,
Milestone Report 2, submitted October 31, 2023.