11
[51] Wang School of Chemical Engineering and
Technology, China University of Mining &
Technology, Xuzhou, Jiangsu, China Y W, Xing
School of Chemical Engineering and Technology,
China University of Mining &Technology, Xuzhou,
Jiangsu, China Y W, Gui X H, Cao Y J, Xu National
Engineering Research Center of Coal Preparation
and Purification, Xuzhou, Jiangsu, China X H
(2018) The characterization of flotation selectiv-
ity of different size coal fractions. International
Journal of Coal Preparation and Utilization.
38(7):337–354National Engineering Research
Center of Coal Preparation and Purification, Xuzhou,
Jiangsu, ChinaCorrespondenceguixiahui1985
@163.com.
[52] Felicia F P, Yu X (2015) Pico–nano bubble col-
umn flotation using static mixer-venturi tube for
Pittsburgh No. 8 coal seam. Int J of Min Sci and Tech
25 (3):347–354.
[53] Ebrahimi H, Karamoozian M, Saghravani S F
(2020) Interaction of applying stable micro-nano
bubbles and ultrasonic irradiation in coal flotation.
Int. J. of Coal Preparation and Utilization 40(2):
1–15.
[54] Li P W, Zhang M, Wang L, Wei Y, Fan R (2020) Effect
of nanobubbles on the slime coating of kaolinite in
coal flotation. ACS omega 5 (38): 24773–24779.
[55] Han H, Liu A, Wang H F (2020) Effect of hydrody-
namic cavitation assistance on different stages of coal
flotation. Minerals 10(3):221.
[56] Ma F Y, Tao D P, Tao Y J, Liu S Y (2021) An innova-
tive flake graphite upgrading process based on HPGR,
stirred grinding mill, and nanobubble column flota-
tion. Int. J. of Mining Science and Technology 31:
1046–1055.
[57] Tang C L, Ma F Y, Wu TY, Zhang D, Wang Y, Zh
ao T L, Fan Z L, Liu X Y (2023) Study on sur-
face physical and chemical mechanism of nanobub-
ble enhanced flotation of fine graphite. Journal of
Industrial and Engineering Chemistry, Volume 122,
Pages 389–396.
[58] Ma F, Tao D (2023) A study of mechanisms
of nanobubble-enhanced flotation of graphite.
Nanomaterials 2022, 12(19), 3361.
[59] Zhang D, Ma F, Tao Y (2023) Study on effect of
nanobubble on ultra-fine flake graphite (UFG) flota-
tion. Particulate Science and Technology. Volume 41,
2023 -Issue 7, Pages 1062–1070.
[60] Wang Y F, Pan Z C, Luo X M, Qin W Q, Jiao F (2019)
Effect of nanobubbles on adsorption of sodium oleate
on calcite surface. Minerals Eng 133 (15): 127–137.
[61] Zhou J Z, Li H H, Chow R S, Liu Q X, Xu Z H,
Masliyah J (2019) Role of mineral flotation technol-
ogy in improving bitumen extraction from mined
Athabasca oil sands—II. Flotation hydrodynamics
of water‐based oil sand extraction. The Canadian
Journal of Chemical Engineer 97(7):1–23.
[62] Li W, Lin H, Yang Y, Shang Z, Li Q, Ma Y, Liu A,
Jiang M (2021) Enhanced separation of oil and solids
in oily sludge by froth flotation at normal tempera-
ture. Processes 9(12):2163.
[63] Etchepare R, Oliveira H, Azevedo A, Rubio J (2017)
Separation of emulsified crude oil in saline water by
dissolved air flotation with micro and nanobubbles.
Sep Purif Technol 186:326–32.
[64] Lim M W, Lau E V, Poh P E (2018) Micro-
macrobubbles interactions and its application in flo-
tation technology for the recovery of high-density oil
from contaminated sands. J of Petroleum Science and
Engineering 161:29–37.
[65] Wang C, Lü Y, C Song C, Zhang D, Rong F, He L
(2022) Separation of emulsified crude oil from pro-
duced water by gas flotation: A review. 845: 157304.
[66] Colic M (2024) The influence of various param-
eters on petroleum oil removal from produced water
with novel nanobubbles/microbubbles flotation.
International Petroleum Technology Conference,
IPTC, 12–14 February 2024, Dhahran Expo. Paper
Number (IPTC-24290-MS.
[67] Lin F (2023) Design and construction of a continu-
ous pilot flotation facility: A case study for water-
based oil sand extraction. Petroleum Research 8
(2023) 309–315.
[68] Zhou W, Niu J, Xiao W, Ou L (2019) Adsorption of
bulk nanobubbles on the chemically surface-modified
muscovite minerals. Ultrasonics sonochemistry 51:
31–39.
[69] Shao H, Li P, Sobhy A, Ling X, Tao D, Zhang M
(2023) Effects of pure and modified nanobubbles
on the reverse flotation of kaolinite from hematite.
Mineral Processing and Extractive Metallurgy Review
(IF 5 )Published online: doi.org/10.1080/08827508
.2023.2260932.
[70] Wei P, Ren L, Zhang Y, Bao S (2021) Influence of
microbubble on fine wolframite flotation. Minerals
11(1079), Page 1–13.
[71] Tsave P K, Kostoglou M, Karapantsios T D, Lazaridis
N K (2023) Enhancing fines recovery by hybrid
[51] Wang School of Chemical Engineering and
Technology, China University of Mining &
Technology, Xuzhou, Jiangsu, China Y W, Xing
School of Chemical Engineering and Technology,
China University of Mining &Technology, Xuzhou,
Jiangsu, China Y W, Gui X H, Cao Y J, Xu National
Engineering Research Center of Coal Preparation
and Purification, Xuzhou, Jiangsu, China X H
(2018) The characterization of flotation selectiv-
ity of different size coal fractions. International
Journal of Coal Preparation and Utilization.
38(7):337–354National Engineering Research
Center of Coal Preparation and Purification, Xuzhou,
Jiangsu, ChinaCorrespondenceguixiahui1985
@163.com.
[52] Felicia F P, Yu X (2015) Pico–nano bubble col-
umn flotation using static mixer-venturi tube for
Pittsburgh No. 8 coal seam. Int J of Min Sci and Tech
25 (3):347–354.
[53] Ebrahimi H, Karamoozian M, Saghravani S F
(2020) Interaction of applying stable micro-nano
bubbles and ultrasonic irradiation in coal flotation.
Int. J. of Coal Preparation and Utilization 40(2):
1–15.
[54] Li P W, Zhang M, Wang L, Wei Y, Fan R (2020) Effect
of nanobubbles on the slime coating of kaolinite in
coal flotation. ACS omega 5 (38): 24773–24779.
[55] Han H, Liu A, Wang H F (2020) Effect of hydrody-
namic cavitation assistance on different stages of coal
flotation. Minerals 10(3):221.
[56] Ma F Y, Tao D P, Tao Y J, Liu S Y (2021) An innova-
tive flake graphite upgrading process based on HPGR,
stirred grinding mill, and nanobubble column flota-
tion. Int. J. of Mining Science and Technology 31:
1046–1055.
[57] Tang C L, Ma F Y, Wu TY, Zhang D, Wang Y, Zh
ao T L, Fan Z L, Liu X Y (2023) Study on sur-
face physical and chemical mechanism of nanobub-
ble enhanced flotation of fine graphite. Journal of
Industrial and Engineering Chemistry, Volume 122,
Pages 389–396.
[58] Ma F, Tao D (2023) A study of mechanisms
of nanobubble-enhanced flotation of graphite.
Nanomaterials 2022, 12(19), 3361.
[59] Zhang D, Ma F, Tao Y (2023) Study on effect of
nanobubble on ultra-fine flake graphite (UFG) flota-
tion. Particulate Science and Technology. Volume 41,
2023 -Issue 7, Pages 1062–1070.
[60] Wang Y F, Pan Z C, Luo X M, Qin W Q, Jiao F (2019)
Effect of nanobubbles on adsorption of sodium oleate
on calcite surface. Minerals Eng 133 (15): 127–137.
[61] Zhou J Z, Li H H, Chow R S, Liu Q X, Xu Z H,
Masliyah J (2019) Role of mineral flotation technol-
ogy in improving bitumen extraction from mined
Athabasca oil sands—II. Flotation hydrodynamics
of water‐based oil sand extraction. The Canadian
Journal of Chemical Engineer 97(7):1–23.
[62] Li W, Lin H, Yang Y, Shang Z, Li Q, Ma Y, Liu A,
Jiang M (2021) Enhanced separation of oil and solids
in oily sludge by froth flotation at normal tempera-
ture. Processes 9(12):2163.
[63] Etchepare R, Oliveira H, Azevedo A, Rubio J (2017)
Separation of emulsified crude oil in saline water by
dissolved air flotation with micro and nanobubbles.
Sep Purif Technol 186:326–32.
[64] Lim M W, Lau E V, Poh P E (2018) Micro-
macrobubbles interactions and its application in flo-
tation technology for the recovery of high-density oil
from contaminated sands. J of Petroleum Science and
Engineering 161:29–37.
[65] Wang C, Lü Y, C Song C, Zhang D, Rong F, He L
(2022) Separation of emulsified crude oil from pro-
duced water by gas flotation: A review. 845: 157304.
[66] Colic M (2024) The influence of various param-
eters on petroleum oil removal from produced water
with novel nanobubbles/microbubbles flotation.
International Petroleum Technology Conference,
IPTC, 12–14 February 2024, Dhahran Expo. Paper
Number (IPTC-24290-MS.
[67] Lin F (2023) Design and construction of a continu-
ous pilot flotation facility: A case study for water-
based oil sand extraction. Petroleum Research 8
(2023) 309–315.
[68] Zhou W, Niu J, Xiao W, Ou L (2019) Adsorption of
bulk nanobubbles on the chemically surface-modified
muscovite minerals. Ultrasonics sonochemistry 51:
31–39.
[69] Shao H, Li P, Sobhy A, Ling X, Tao D, Zhang M
(2023) Effects of pure and modified nanobubbles
on the reverse flotation of kaolinite from hematite.
Mineral Processing and Extractive Metallurgy Review
(IF 5 )Published online: doi.org/10.1080/08827508
.2023.2260932.
[70] Wei P, Ren L, Zhang Y, Bao S (2021) Influence of
microbubble on fine wolframite flotation. Minerals
11(1079), Page 1–13.
[71] Tsave P K, Kostoglou M, Karapantsios T D, Lazaridis
N K (2023) Enhancing fines recovery by hybrid