Research Progress in Preparation of Nanoparticles by Laser Ablation in Liquid

Yongyi Chen; Lirong Bao; Hui Wang; Zheng Ning; Xiandong Zhong; Jinle Cao; Ruiqi Shen; Wei Zhang

doi:10.3788/CJL202148.0600002

Chinese Journal of Lasers, Volume. 48, Issue 6, 0600002(2021)

Research Progress in Preparation of Nanoparticles by Laser Ablation in Liquid

Yongyi Chen^1,2, Lirong Bao^1,2, Hui Wang^1,2, Zheng Ning², Xiandong Zhong², Jinle Cao^1,2, Ruiqi Shen^1,2, and Wei Zhang^1,2、*

Author Affiliations

¹Micro-Nano Energetic Devices Key Laboratory, Ministry of Industry and Information Technology, Nanjing, Jiangsu 210094, China

²School of Chemical Engineering, Nanjing University of Science and Technology, Nanjing, Jiangsu 210094, China

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Figures & Tables(20)

Fig. 1. Formation and cooling of nanodroplets^[9]. (a) Formation of nanodroplets; (b) cooling of nanodroplets

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Fig. 2. Schematic of the interaction between nanosecond pulsed laser and target^[11]

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Fig. 3. Interaction between femtosecond pulsed laser and silicon wafer^[11]. (a) Reaction on the surface of silicon wafer at different power densities; (b) material absorbs laser energy; (c) electrons stripped from atoms; (d) coulomb explosion on the surface of the material

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Fig. 4. Formation mechanism of carbonized products with different structures in acetone^[23]

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Fig. 5. Formation of nanoparticles in different concentrations of SDS solutions^[24]

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Fig. 6. FE-SEM images of nanoparticles prepared in different concentrations of CTAB solutions^[25]

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Fig. 7. Molecular structure of PVP, PVA, and PEG and protection for Al nanoparticles^[26]

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Fig. 8. Optical microscopy and scanning electron microscopy images and corresponding particle size distribution histograms of NiO particles prepared in different solutions under the same condition^[34]. (a) Distilled water; (b) ethanol solution

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Fig. 9. Schematic of preparation of nanoparticles by laser ablation in dynamic microfluidics^[37]. (a) Experimental setup; (b) confined mode of operation; (c) continuous mode of operation

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Fig. 10. Scanning electron microscopy images of Cu nanoparticles prepared with different pulse widths^[38]. (a)(b) 5 ns; (c)(d) 200 ps; (e)(f) 30 fs

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Fig. 11. Formation of nanoparticle in different solutions^[39]. (a) Deionized water; (b) sodium hydroxide solution; (c) hydrogen peroxide solution; (d) anhydrous ethanol

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Fig. 12. Three methods for laser ablation in liquid^[53]

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Fig. 13. Histogram of particle size distribution of alloy nanoparticles prepared in different solutions and corresponding hydrodynamic diameter, Zeta potential, and Ferret diameter^[56]. (a) Histogram of particle size distribution of alloy nanoparticles prepared in acetone; (b) histogram of particle size distribution of alloy nanoparticles prepared in MMA; (c) histogram of particle size distribution of alloy nanoparticles prepared in deionized water; (d) h

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Fig. 14. TEM images of nanoparticles prepared by ablating alloy targets with different molar ratios of Pb to Zn^[57]. (a)(c)(e) Lowly enlarged TEM; (b)(d)(f) highly enlarged TEM

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Fig. 15. TEM images of the samples prepared in four solutions^[66]

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Fig. 16. Ablated silicon mass as function of the number of laser pulses in different wavelengths^[74]. (a) 1064 nm; (b) 355 nm

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Table 1. Preparation of metal nanoparticles by laser ablation in liquid

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Table 1. Preparation of metal nanoparticles by laser ablation in liquid

The firstauthor	Laser parameter	Target	Solvent	Variable	Product	Averagesize /nm	Ref.
Du	800 nm (30 fs)	--	HAuCl₄·3H₂O	Concentration of PVP,energy and timeof ablation	Au	9--21	[27]
Mafuné	532 nm	Ag	SDS	Concentration of SDSand energy	Ag	7.9--16.2	[17]
Tan	1064/532 nm	Au, Ag	H₂O	Wavelength	Au, Ag	9--32	[18]
Moniri	1064 nm (7 ns)	Pt	C₃H₆O,(CH₂OH)₂,C₂H₅OH, H₂O	Type of solvents	Pt	14--22	[28]
The firstauthor	Laser parameter	Target	Solvent	Variable	Product	Averagesize /nm	Ref.
Zeng	1064 nm (10 ns)	Zn	SDS	Concentration of SDS	Zn, ZnO,Zn(OH)₂	18.1--44.5	[24]
Lee	1064 nm (7 ns)	Al	CTAB	Concentration of CTAB	Al, Al₂O₃,Al(OH)₃	50--300	[25]
Singh	1064/532 nm(5 ns)	Al	PVP, PVA,PEG	Type of solventsand wavelength	Al, Al₂O₃	16--33	[26]

Table 2. Preparation of metal oxide nanoparticles by laser ablation in liquid

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Table 2. Preparation of metal oxide nanoparticles by laser ablation in liquid

The firstauthor	Laserparameter	Target	Solvent	Variable	Product	Averagesize /nm	Ref.
Maneeratanasarn	355 nm (10 ns)	α-Fe₂O₃	C₂H₅OH,H₂O,C₃H₆O	Type of solvents	α-Fe₂O₃,γ-Fe₂O₃	8--13	[31]
Zhang	1064/355 nm(5 ns),800 nm(30 fs/200 ps)	Cu	H₂O	Pulse width,wavelength	Cu₂O,CuO	1--200	[38]
Goncharova	1064 nm (7 ns)	Cu	H₂O,NaOH,H₂O₂,C₂H₅OH	Type of solvents	Cu,Cu₂O,CuO	2--1000	[39]
Singh	532 nm (8 ns),355 nm (5ns)	Zn	SDS	Energy,wavelength	ZnO,ZnOOH	13--28	[44]
Enríquez-Sánchez	1064 nm	Mn	H₂O	Time of ablation	MnO,Mn₃O₄	7--11	[45]
Ghaem	1064 nm (7 ns)	Co	H₂O	Energy	Co₃O₄	100--200	[46]
Semaltianos	800 nm (90 fs)	Cr	H₂O,C₂H₅OH,C₃H₆O,C₇H₈	Type of solvents	Cr₃O₄,Cr₂O₃,CrO₃,Cr₃C_2-_x	5--12	[47]

Table 3. Preparation of alloy nanoparticles by laser ablation in liquid

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Table 3. Preparation of alloy nanoparticles by laser ablation in liquid

The firstauthor	Laserparameter	Target	Solvent	Variable	Product	Averagesize /nm	Ref.
Menéndez-Manjón	515 nm (7 ps)	Au, Ag,Au-Ag alloy	MMA	Type of target	Au, Ag,Au-Ag	8--12	[51]
Li	248 nm (20 ns)	Au+Ag	H₂O	Time ofablation	Au@Ag	20--35	[58]
Compagnini	532 nm	Au+Ag	H₂O	Ratio of gold tosilver, time ofablation	Au@Ag	2--10	[52]
Wagener	800 nm (120 fs),1064 nm (10 ps/8 ns)	Fe-Au	H₂O,C₃H₆O,MMA	Type ofsolvents	Fe@Au,Au@Fe₃O₄	9--21	[56]
Jakobi	800 nm (120 fs)	Pt-Ir	C₃H₆O	--	Pt-Ir	26	[59]
Jakobi	800 nm (120 fs)	Ni-Fe,Sm-Co	C₅H₈O	Time ofablation	Ni-Fe,Sm-Co	6--10	[60]
Patra	532 nm (9 ns)	Al-Cu	H₂O	--	Cu-Al, CuO,Al₂O₃,Al(OH)₃	94	[61]

Table 4. Preparation of non-metallic nanoparticles by laser ablation in liquid

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Table 4. Preparation of non-metallic nanoparticles by laser ablation in liquid

The firstauthor	Laserparameter	Target	Solvent	Variable	Product	Averagesize /nm	Ref.
Sadeghi	1064 nm (7 ns)	Graphite	H₂O,C₂H₅OH,C₃H₆O,CTAB	Type of solvents	C, grapheneflakes	--	[66]
Mahdian	1064 nm (7 ns)	Graphite	H₂O	Temperatureof liquid	C, grapheneflakes	400--650	[67]
Hameed	1064 nm (7 ns)	Graphite	H₂O	Energy	C, Grapheneflakes	25--75	[75]
Lasemi	800 nm (30 fs)	Silicon wafer	C₂H₅OH,C₄H₁₀O,C₆H₁₄	Type of solvents,energy	SiC, SiO₂, Si	9--15	[76]
Serrano-Ruz	1064 nm (6 ns),532 nm	Si	H₂O,C₂H₅OH	Wavelength, typeof solvents,energy, timeof ablation	Si	2--50	[77]
Zabotnov	1250 nm (160 fs)	Porous/crystallinesilicon	H₂O,C₂H₅OH,N₂	Type oftargets/solvents,time of ablation	Si	16--112	[78]

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Yongyi Chen, Lirong Bao, Hui Wang, Zheng Ning, Xiandong Zhong, Jinle Cao, Ruiqi Shen, Wei Zhang. Research Progress in Preparation of Nanoparticles by Laser Ablation in Liquid[J]. Chinese Journal of Lasers, 2021, 48(6): 0600002

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Paper Information

Category: reviews

Received: Jul. 3, 2020

Accepted: Aug. 20, 2020

Published Online: Mar. 15, 2021

The Author Email: Zhang Wei (wzhang@njust.edu.cn)

DOI:10.3788/CJL202148.0600002

Topics

laser devices and laser physics

Lasers and Laser Optics

Laser physics

laser manufacturing

Instrumentation, Measurement and Metrology