10
[30] Rosa A F, Rubio J (2018) On the role of nanobubbles
in particle–bubble adhesion for the flotation of quartz
and apatitic minerals. Minerals Eng (127): 178–184.
[31] Nazari S, Gholami A, Khoshdast H, Li J L ,He Y Q,
and Hassanzadeh A (2023) Advanced simulation of
quartz flotation using micro-nanobubbles by hybrid
serving of historical data (HD) and deep learning
(DL) methods. Minerals 2023, 13, 128.
[32] Chipakwe V, Karlkvist T, Rosenkranz J, Chelgani S
C (2023) Exploring the effect of a polyacrylic acid-
based grinding aid on magnetite-quartz flotation sep-
aration. Separation and Purification Technology 305
(2023) 122530.
[33] Chipili C, Bhondayi C (2023) Bubble loading in a
fluidized column: effects of bubble size, particle size,
contact angle and particle density. Mineral Processing
and Extractive Metallurgy Review, 1–13.
[34] Ahmadi R, Darban A K, Abdollahy M, Fan M M
(2014) Nano-microbubble flotation of fine and
ultrafine chalcopyrite particles. J Min Sci Technol
24:559–66.
[35] Rulyov N, Nessipbay T, Dulatbek T, Larissa S,
Zhamikhan K (2018) Effect of microbubbles as
flotation carriers on fine sulphide ore beneficia-
tion. Mineral Process and Extractive Metall 127
(3):133–139.
[36] Chipakwe V., Sandb A, Chelgani S C (2021)
Nanobubble assisted flotation separation of complex
Pb–Cu–Zn sulfide ore—Assessment of process readi-
ness. Separation Science and Technology 1–9.
[37] Fan M, Milbourne J, Hobert A, Letkiewicz R (2023)
Enhanced flotation of ultrafine copper/gold/silver
minerals using optimized reagent schemes and Eriez
column/Stackcell high-intensity flotation technolo-
gies. SME Annual Conference Feb. 26 -Mar. 01,
2023, Denver, CO.
[38] Kazemi F ,Bahrami A, Ghorbani Y ,Danesh A ,
Abdollahi M, Falah H ,Salehi M (2023) The inter-
action and synergic effect of particle size on flota-
tion efficiency: A comparison study of recovery by
size, and by liberation between lab and industrial
scale data. Rudarsko-geološko-naftni zbornik (The
Mining-Geology-Petroleum Engineering Bulletin)
UDC: 622–699.
[39] Mahani A N, Karamoozian M, Chegeni M J, Meymand
M M (2023) Effect of stable nano-microbubbles on
sulfide copper flotation and reduction of chemicals
dosage. Journal of Mining and Environment (JME),
jme.shahroodut.ac.ir/article_2848.html.
[40] Zinjenab Z T, Azimi E, Shadman M, Hosseini M
R, Abbaszadeh M, Namgar S M (2023) Nano-
microbubbles and feed size interaction in lead and
zinc sulfide minerals flotation. Chemical Engineering
and Processing -Process Intensification, Volume
189, July 2023, 109401.
[41] Shadman M, Hosseini M R, Zinjenab Z T, Azimi E
(2023) Significant reduction in collector consump-
tion by implementing ultrafine bubbles in lead and
zinc rougher flotation. Powder Technology, Volume
414, 118096.
[42] Fan M M, Tao D (2012) A pilot-scale study of effects
of nanobubbles on phosphate flotation. In: Zhang
P, Miller J D, El-Shall H E, editors. Beneficiation
of phosphates: new thought, new technology, new
development. Littleton (CO): Soc for Min, Metall,
and Explor pp. 21–31.
[43] Hobert A, Dohm E, Tallarico F, Dede (2019)
Improved flotation recovery and selectivity of an
ultra-fine Brazilian phosphate ore using Eriez’ col-
umn flotation technology. SYMPHOS 2019.
[44] Reis A S, Reis F A M, Demuner L R, Barrozo M A S
(2019) Effect of bubble size on the performance flota-
tion of fine particles of a low-grade Brazilian apatite
ore. Powder Tech. 356:884–891.
[45] Nakhaie F (2023) Application of nano bubbles in col-
umn flotation: Beneficiation of iron and phosphate
slimes. Conference: IMCET 2022 /ANTALYA /
TURKEY /March 22—25.
[46] Reis A S, Mendes T F, Júnior I P, Barrozo M A
(2023) Influence of bubble size on performance of
apatite flotation of different particle sizes. Particulate
Science and Technology, Volume 41, Issue 7, Pages
1044–1052.
[47] Fan M M, Zhao Y, Tao D (2012) Fundamental studies
of nanobubble generation and applications in flota-
tion. In: Separation Technologies for Minerals, Coal,
and Earth Resources, Society for Mining, Metallurgy,
and Exploration, Littleton, CO, pp.457–469.
[48] Fan M M, Tao D, Zhao Y M, Honaker R (2013)
Effect of nanobubbles on the flotation of different
sizes of coal particle. Minerals and Metallurgical
Processing 30 (3):157–167.
[49] Tao D, Fan M M (2010) Enhanced fine coal column
flotation using cavitation concept. Proceedings of XVI
International Coal Preparation Congress. Society for
Mining, Metallurgy, and Exploration. PP: 413–420.
[50] Fan M M, Tao D (2014) Effect of nanobubbles on
flotation of different density coal. 2014 SME Annual
Meeting, February 23 –26, Salt Lake City, Utah.
[30] Rosa A F, Rubio J (2018) On the role of nanobubbles
in particle–bubble adhesion for the flotation of quartz
and apatitic minerals. Minerals Eng (127): 178–184.
[31] Nazari S, Gholami A, Khoshdast H, Li J L ,He Y Q,
and Hassanzadeh A (2023) Advanced simulation of
quartz flotation using micro-nanobubbles by hybrid
serving of historical data (HD) and deep learning
(DL) methods. Minerals 2023, 13, 128.
[32] Chipakwe V, Karlkvist T, Rosenkranz J, Chelgani S
C (2023) Exploring the effect of a polyacrylic acid-
based grinding aid on magnetite-quartz flotation sep-
aration. Separation and Purification Technology 305
(2023) 122530.
[33] Chipili C, Bhondayi C (2023) Bubble loading in a
fluidized column: effects of bubble size, particle size,
contact angle and particle density. Mineral Processing
and Extractive Metallurgy Review, 1–13.
[34] Ahmadi R, Darban A K, Abdollahy M, Fan M M
(2014) Nano-microbubble flotation of fine and
ultrafine chalcopyrite particles. J Min Sci Technol
24:559–66.
[35] Rulyov N, Nessipbay T, Dulatbek T, Larissa S,
Zhamikhan K (2018) Effect of microbubbles as
flotation carriers on fine sulphide ore beneficia-
tion. Mineral Process and Extractive Metall 127
(3):133–139.
[36] Chipakwe V., Sandb A, Chelgani S C (2021)
Nanobubble assisted flotation separation of complex
Pb–Cu–Zn sulfide ore—Assessment of process readi-
ness. Separation Science and Technology 1–9.
[37] Fan M, Milbourne J, Hobert A, Letkiewicz R (2023)
Enhanced flotation of ultrafine copper/gold/silver
minerals using optimized reagent schemes and Eriez
column/Stackcell high-intensity flotation technolo-
gies. SME Annual Conference Feb. 26 -Mar. 01,
2023, Denver, CO.
[38] Kazemi F ,Bahrami A, Ghorbani Y ,Danesh A ,
Abdollahi M, Falah H ,Salehi M (2023) The inter-
action and synergic effect of particle size on flota-
tion efficiency: A comparison study of recovery by
size, and by liberation between lab and industrial
scale data. Rudarsko-geološko-naftni zbornik (The
Mining-Geology-Petroleum Engineering Bulletin)
UDC: 622–699.
[39] Mahani A N, Karamoozian M, Chegeni M J, Meymand
M M (2023) Effect of stable nano-microbubbles on
sulfide copper flotation and reduction of chemicals
dosage. Journal of Mining and Environment (JME),
jme.shahroodut.ac.ir/article_2848.html.
[40] Zinjenab Z T, Azimi E, Shadman M, Hosseini M
R, Abbaszadeh M, Namgar S M (2023) Nano-
microbubbles and feed size interaction in lead and
zinc sulfide minerals flotation. Chemical Engineering
and Processing -Process Intensification, Volume
189, July 2023, 109401.
[41] Shadman M, Hosseini M R, Zinjenab Z T, Azimi E
(2023) Significant reduction in collector consump-
tion by implementing ultrafine bubbles in lead and
zinc rougher flotation. Powder Technology, Volume
414, 118096.
[42] Fan M M, Tao D (2012) A pilot-scale study of effects
of nanobubbles on phosphate flotation. In: Zhang
P, Miller J D, El-Shall H E, editors. Beneficiation
of phosphates: new thought, new technology, new
development. Littleton (CO): Soc for Min, Metall,
and Explor pp. 21–31.
[43] Hobert A, Dohm E, Tallarico F, Dede (2019)
Improved flotation recovery and selectivity of an
ultra-fine Brazilian phosphate ore using Eriez’ col-
umn flotation technology. SYMPHOS 2019.
[44] Reis A S, Reis F A M, Demuner L R, Barrozo M A S
(2019) Effect of bubble size on the performance flota-
tion of fine particles of a low-grade Brazilian apatite
ore. Powder Tech. 356:884–891.
[45] Nakhaie F (2023) Application of nano bubbles in col-
umn flotation: Beneficiation of iron and phosphate
slimes. Conference: IMCET 2022 /ANTALYA /
TURKEY /March 22—25.
[46] Reis A S, Mendes T F, Júnior I P, Barrozo M A
(2023) Influence of bubble size on performance of
apatite flotation of different particle sizes. Particulate
Science and Technology, Volume 41, Issue 7, Pages
1044–1052.
[47] Fan M M, Zhao Y, Tao D (2012) Fundamental studies
of nanobubble generation and applications in flota-
tion. In: Separation Technologies for Minerals, Coal,
and Earth Resources, Society for Mining, Metallurgy,
and Exploration, Littleton, CO, pp.457–469.
[48] Fan M M, Tao D, Zhao Y M, Honaker R (2013)
Effect of nanobubbles on the flotation of different
sizes of coal particle. Minerals and Metallurgical
Processing 30 (3):157–167.
[49] Tao D, Fan M M (2010) Enhanced fine coal column
flotation using cavitation concept. Proceedings of XVI
International Coal Preparation Congress. Society for
Mining, Metallurgy, and Exploration. PP: 413–420.
[50] Fan M M, Tao D (2014) Effect of nanobubbles on
flotation of different density coal. 2014 SME Annual
Meeting, February 23 –26, Salt Lake City, Utah.