Laser Induced Forward Transfer (LIFT) is an additive direct-writing technique, in which a piece of material (ink) is transferred from a donor to a receiver surface, utilizing a laser impulse. In practice, the process of jet formation can suffer from irreproducibility. We identify two possible destructive mechanisms due to multiple optical breakdowns (originating from imperfections of the optical system) and rarefaction waves (originating from impurities), both with harmful consequences caused by cavitation. Based on experiments in a model system that allows for visualization and numerical simulations employing the boundary integral method, we reveal the underlying fluid dynamics of both mechanisms. Finally, to overcome the irreproducibility, we provide recommendations for the industrial use of LIFT.
References
1.
C. W.
Visser
, R.
Pohl
, C.
Sun
, G.-W.
Römer
, B.
Huis in't Veld
, and D.
Lohse
, Adv. Mater.
27
, 4087
(2015
).2.
L.
Koch
, A.
Deiwick
, S.
Schlie
, S.
Michael
, M.
Gruene
, V.
Coger
, D.
Zychlinski
, A.
Schambach
, K.
Reimers
, P. M.
Vogt
et al., Biotechnol. Bioeng.
109
, 1855
(2012
).3.
P.
Serra
and A.
Piqué
, Adv. Mater. Technol.
4
, 1800099
(2019
).4.
A.
Piqué
and P.
Serra
, Laser Printing of Functional Materials: 3D Microfabrication, Electronics and Biomedicine
(John Wiley & Sons
, 2018
).5.
Z.
Zhang
, R.
Xiong
, R.
Mei
, Y.
Huang
, and D. B.
Chrisey
, Langmuir
31
, 6447
(2015
).6.
J.
Yan
, Y.
Huang
, C.
Xu
, and D. B.
Chrisey
, J. Appl. Phys.
112
, 083105
(2012
).7.
A.
Vogel
, K.
Nahen
, D.
Theisen
, and J.
Noack
, IEEE J. Sel. Top. Quantum Electron.
2
, 847
–860
(1996
).8.
P. K.
Kennedy
, D. X.
Hammer
, and B. A.
Rockwell
, Prog. Quantum Electron.
21
, 155
–248
(1997
).9.
M.
Duocastella
, A.
Patrascioiu
, J. M.
Fernández-Pradas
, J.
Morenza
, and P.
Serra
, Opt. Express
18
, 21815
(2010
).10.
A.
Vogel
and V.
Venugopalan
, Chem. Rev.
103
, 577
(2003
).11.
S. T.
Thoroddsen
, K.
Takehara
, T.
Etoh
, and C.-D.
Ohl
, Phys. Fluids
21
, 112101
(2009
).12.
H. N.
Oguz
and A.
Prosperetti
, J. Fluid Mech.
219
, 143
(1990
).13.
S.
Li
, Y.-B.
Li
, and A.
Zhang
, Appl. Ocean Res.
50
, 227
(2015
).14.
S.
Li
, R.
Han
, A.
Zhang
, and Q.
Wang
, Ocean Eng.
117
, 22
(2016
).15.
E. A.
Brujan
, G. S.
Keen
, A.
Vogel
, and J. R.
Blake
, Phys. Fluids
14
, 85
(2002
).16.
L.
Fu
, S.
Wang
, J.
Xin
, S.
Wang
, C.
Yao
, Z.
Zhang
, and J.
Wang
, Opt. Express
26
, 28560
(2018
).17.
W.
Lauterborn
and K.
Ebeling
, Appl. Phys. Lett.
31
, 663
(1977
).18.
M.
Capon
, F.
Docchio
, and J.
Mellerio
, Graefe's Arch. Clin. Exp. Ophthalmol.
226
, 362
(1988
).19.
T.
Kovalchuk
, G.
Toker
, V.
Bulatov
, and I.
Schechter
, Chem. Phys. Lett.
500
, 242
(2010
).20.
F.
Docchio
, P.
Regondi
, M. R.
Capon
, and J.
Mellerio
, Appl. Opt.
27
, 3661
(1988
).21.
A.
Vogel
, K.
Nahen
, D.
Theisen
, R.
Birngruber
, R. J.
Thomas
, and B. A.
Rockwell
, Appl. Opt.
38
, 3636
(1999
).22.
Y.
Tagawa
, S.
Yamamoto
, K.
Hayasaka
, and M.
Kameda
, J. Fluid Mech.
808
, 5
(2016
).23.
Y.
Tian
, B.
Xue
, J.
Song
, Y.
Lu
, and R.
Zheng
, Appl. Phys. Lett.
109
, 061104
(2016
).24.
F.
Potemkin
, E.
Mareev
, A.
Podshivalov
, and V.
Gordienko
, New J. Phys.
17
, 053010
(2015
).25.
L.
Duchemin
, S.
Popinet
, C.
Josserand
, and S.
Zaleski
, Phys. Fluids
14
, 3000
(2002
).26.
L.
Deike
, E.
Ghabache
, G.
Liger-Belair
, A. K.
Das
, S.
Zaleski
, S.
Popinet
, and T.
Séon
, Phys. Rev. Fluids
3
, 013603
(2018
).27.
S.
Wang
, W.
Duan
, and Q.
Wang
, Ocean Eng.
109
, 611
(2015
).28.
J. W.
Grove
and R.
Menikoff
, J. Fluid Mech.
219
, 313
(1990
).29.
A.
Vogel
, S.
Busch
, and U.
Parlitz
, J. Acoust. Soc. Am.
100
, 148
(1996
).30.
M. H.
Rice
and J. M.
Walsh
, J. Chem. Phys.
26
, 824
(1957
).31.
P. G.
Debenedetti
, Metastable Liquids: Concepts and Principles
(Princeton University Press
, 1996
).32.
E.
Herbert
, S.
Balibar
, and F.
Caupin
, Phys. Rev. E
74
, 041603
(2006
).33.
34.
K.
Ando
, A.-Q.
Liu
, and C.-D.
Ohl
, Phys. Rev. Lett.
109
, 044501
(2012
).35.
36.
P.
Quinto-Su
, V.
Venugopalan
, and C.-D.
Ohl
, Opt. Express
16
, 18964
(2008
).37.
E.
Turkoz
, A.
Perazzo
, H.
Kim
, H. A.
Stone
, and C. B.
Arnold
, Phys. Rev. Lett.
120
, 074501
(2018
).38.
N. T.
Kattamis
, N. D.
McDaniel
, S.
Bernhard
, and C. B.
Arnold
, Appl. Phys. Lett.
94
, 103306
(2009
).39.
N. J.
Balmforth
, I. A.
Frigaard
, and G.
Ovarlez
, Annu. Rev. Fluid Mech.
46
, 121
(2014
).© 2019 Author(s).
2019
Author(s)
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