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Items: 1 to 20 of 165

1.

Dielectric liquid microlens with well-shaped electrode.

Xu S, Lin YJ, Wu ST.

Opt Express. 2009 Jun 22;17(13):10499-505.

PMID:
19550445
2.

Adaptive dielectric liquid lens.

Ren H, Xianyu H, Xu S, Wu ST.

Opt Express. 2008 Sep 15;16(19):14954-60.

PMID:
18795032
3.

Tunable-focus liquid microlens array using dielectrophoretic effect.

Ren H, Wu ST.

Opt Express. 2008 Feb 18;16(4):2646-52.

PMID:
18542348
4.

Tunable liquid microlens arrays in electrode-less configuration and their accurate characterization by interference microscopy.

Miccio L, Finizio A, Grilli S, Vespini V, Paturzo M, De Nicola S, Ferraro P.

Opt Express. 2009 Feb 16;17(4):2487-99.

PMID:
19219152
5.

Tunable microfluidic microlenses.

Werber A, Zappe H.

Appl Opt. 2005 Jun 1;44(16):3238-45.

PMID:
15943257
6.

Characterization of a liquid crystal microlens array using multiwalled carbon nanotube electrodes.

Wang X, Wilkinson TD, Mann M, Teo KB, Milne WI.

Appl Opt. 2010 Jun 10;49(17):3311-5. doi: 10.1364/AO.49.003311.

PMID:
20539349
7.

Polarization independent adaptive microlens with a blue-phase liquid crystal.

Li Y, Wu ST.

Opt Express. 2011 Apr 25;19(9):8045-50. doi: 10.1364/OE.19.008045.

PMID:
21643053
8.

Tunable liquid crystal microlens array using hole patterned electrode structure with ultrathin glass slab.

Zhao X, Liu C, Zhang D, Luo Y.

Appl Opt. 2012 May 20;51(15):3024-30. doi: 10.1364/AO.51.003024.

PMID:
22614606
9.

Liquid-crystal microlens with focus swing and low driving voltage.

Kang S, Zhang X, Xie C, Zhang T.

Appl Opt. 2013 Jan 20;52(3):381-7. doi: 10.1364/AO.52.000381.

PMID:
23338183
10.

Electrowetting on a polymer microlens array.

Im M, Kim DH, Lee JH, Yoon JB, Choi YK.

Langmuir. 2010 Jul 20;26(14):12443-7. doi: 10.1021/la101339t.

PMID:
20465273
11.

Fabrication and Characterization of Flexible Electrowetting on Dielectrics (EWOD) Microlens.

Li C, Jiang H.

Micromachines (Basel). 2014 Jul 4;5(3):432-441.

PMID:
25360324
12.

An electrically tunable-focusing liquid crystal lens with a low voltage and simple electrodes.

Lin HC, Lin YH.

Opt Express. 2012 Jan 30;20(3):2045-52. doi: 10.1364/OE.20.002045.

PMID:
22330445
13.

Achieving high focusing power for a large-aperture liquid crystal lens with novel hole-and-ring electrodes.

Chiu CW, Lin YC, Chao PC, Fuh AY.

Opt Express. 2008 Nov 10;16(23):19277-84.

PMID:
19582020
14.

Adaptive liquid microlenses activated by stimuli-responsive hydrogels.

Dong L, Agarwal AK, Beebe DJ, Jiang H.

Nature. 2006 Aug 3;442(7102):551-4.

PMID:
16885981
15.

Silicon microlens structures fabricated by scanning-probe gray-scale oxidation.

Chen CF, Tzeng SD, Chen HY, Gwo S.

Opt Lett. 2005 Mar 15;30(6):652-4.

PMID:
15792006
16.

Miniaturization of dielectric liquid microlens in package.

Yang CC, Tsai CG, Yeh JA.

Biomicrofluidics. 2010 Dec 30;4(4):43006. doi: 10.1063/1.3494030.

PMID:
21267438
17.

Polymer-stabilized liquid crystal microlens array with large dynamic range and fast response time.

Ren H, Xu S, Wu ST.

Opt Lett. 2013 Aug 15;38(16):3144-7. doi: 10.1364/OL.38.003144.

PMID:
24104671
18.
19.

Ommatidia structure based on double layers of liquid crystal microlens array.

Kang S, Qing T, Sang H, Zhang X, Xie C.

Appl Opt. 2013 Nov 20;52(33):7912-8. doi: 10.1364/AO.52.007912.

PMID:
24513741
20.

Liquid crystal microlens with dual apertures and electrically controlling focus shift.

Kang S, Zhang X.

Appl Opt. 2014 Jan 10;53(2):244-8. doi: 10.1364/AO.53.000244.

PMID:
24514056
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