[1] Brown G H. Photochromism[M]. New York: Wiley-Interscience. 1971.
[2] Irie M. Diarylethenes for memories and switches[J]. Chemi-cal Reviews, 2000, 100: 1685-1716.
[3] Tian H, Yang S J. Recent progresses on diarylethene based photochromic switches[J]. Chemical Society Reviews, 2004, 33: 85-97.
[4] Yokoyama Y. Fulgides for memories and switches[J]. Chemical Reviews, 2000, 100: 1717-1739.
[5] Berkovic G, Krongauz V, Wiess V. Spiropyrans and spirooxazines for memories and switches[J]. Chemical Reviews, 2000, 100: 1741-1753.
[6] Luigi A, Tmiana B, Loris G. Synthesis, chiroptical properties and photoinduced linear birefringence of the homopolymer of (R)-3-methacryloyloxy-1-(4'-cyano-4-azobenzene)pyrrolidine and of the copolymers with the enantiomeric monomer[J]. European Polymer Journal, 2005, 41: 2045-2048.
[7] Raymo F M, Tomasulo M. Electron and energy transfer modulation with photochromic switches[J]. Chemical Society Reviews, 2005, 34: 327-336.
[8] Wang S, Shen W, Feng Y L, Tian H. A multiple switching bisthienylethene and its photochromic fluorescent organogelator[J]. Chemical Communications, 2006, 14: 1497-1499.
[9] Satoshi K, Yoshimasa K. Three-dimensional optical data storage using photochromic materials[J]. Chemical Reviews, 2000, 100: 1777-1788.
[10] Pu S Z, Liu G, Shen L, Shen L, Xu J. Efficient synthesis and properties of isomeric photochromic diarylethenes having a pyrrole unit[J]. Organic Letters, 2007, 9: 2139-2142.
[11] Tan W J, Li X, Zhang J J, Tian H. A photochromic diarylethene dyad based on perylene diimide[J]. Dyes and Pigments, 2011, 89: 260-265.
[12] Zhang J J, Zou Q, Tian H. Photochromic materials: more than meets the eye[J]. Advanced Materials, 2013, 25: 378-399.
[13] Yildiz I, Deniz E, Raymo F M. Fluorescence modulation with photochromic switches in nanostructured constructs[J]. Chemical Society Reviews, 2009, 38: 1859-1867.
[14] De Silva A P, Gunaratne H Q N, Gunnlaugsson T, Huxley A J, McCoy C P, Rademacher J T, Rice T E. Signaling recognition events with fluorescent sensors and switches[J]. Chemical Reviews, 1997, 97: 1515-1566.
[15] Wang S S, Li X, Zhao W D, Chen X, Zhang J, Agren H, Chen W. Cu2+-Selectivity gated photochromism in Schiff-modified diarylethenes with a star-shaped structure[J]. Journal of Materials Chemistry C, 2017, 5: 282-289.
[16] Ai Q, Ahn K H. A photoswitchable diarylethene heterodimer for use as a multifunctional logic gate[J]. RSC Advances, 2016, 6: 43000-43006.
[17] Cui S Q, Liu G, Pu S Z, Chen B. A highly selective fluorescent probe for Zn2+ based on a new photochromic diarylethene with a di-2-picolylamine unit [J]. Dyes and Pigments, 2013, 99: 950-956.
[18] Ding H C, Liu G, Pu S Z, Zheng C H. Multi-addressable fluorescent switch based on a photochromic diarylethene with triazole-bridged methylquinoline group [J]. Dyes and Pigments, 2014, 103: 82-88.
[19] Xia S J, Liu G, Pu S Z. A highly selective fluorescence sensor for Zn2+ and Cu2+ based on diarylethene with a piperazine-linked amidoquinoline unit[J]. Journal of Materials Chemistry C, 2015, 3: 4023-4029.
[20] Pu S Z, Sun Q, Fan C B, Wang R J, Liu G. Recent advances in diarylethene-based multi-responsive molecular switches [J]. Journal of Materials Chemistry C, 2016, 4: 3075-3093.
[21] Liu H, Zhang X, Gao Z, Chen Y. Photoconversion of a protonated diarylethene derivative[J]. The Journal of Physical Chemistry A, 2012, 116: 9900-9903.
[22] Irie M, Sakemura K, Okinaka M, Uchida K. Photochromism of dithienylethenes with electron-donating substi-tuents[J]. The Journal of Organic Chemistry, 1995, 60: 8305-8309.
[23] Uchida K, Mastsuoka T, Kobatake S, Yamaguchi T, Irie M. Substituent effect on the photochromic reactivity of bis(2-thienyl)perfluorocyclopentenes[J]. Tetrahedron, 2001, 57: 4559-4565.
[24] Liu X, Chen Z, Fan G, Zhang F S. Lewis acid modulation in a amido-functional diarylethene and its hypsochromism effect[J]. Chinese Journal of Chemistry, 2006, 24: 1462-1464.
[25] Liu G, Liu M, Pu S Z, Fan C B, Cui S Q. Synthesis and photochromic properties of novel pyridine-containing diarylethenes[J]. Dyes and Pigments, 2012, 95: 553-562.
[26] Liu G, Liu M, Pu S Z, Fan C B, Cui S Q. Photochromism of new unsymmetrical isomeric diarylethenes bearing a pyridine group[J]. Tetrahedron, 2012, 68: 2267-2275.
[27] Pu S Z, Zheng C H, Sun Q, Liu G, Fan C B. Enhancement of cyclization quantum yields of perfluorodiarylethenes via weak intramolecular interactions[J]. Chemical Communications, 2013, 49: 8036-8038.
[28] Coudret C, Nakagawa T, Kawai T, Micheau J C. Weak acid triggers the ring opening of an otherwise long-lived triangle terthiazole closed isomer[J]. New Journal of Chemistry, 2009, 33: 1386-1392.
[29] Kutsunugi Y, Coudret C, Micheau J, Kawai T. Photomodulation of the proton affinity and acid gated photochromism of a novel dimethylaminophenyl thiazole diarylethene[J]. Dyes and Pigments, 2012, 92: 838-846.
[30] Suzuki K, Ubukata T, Yokoyama Y. Dual-mode fluorescence switching of photochromic bisthiazolylcoumarin[J]. Chemical Communications, 2012, 48: 765-767.
[31] Zhang J Q, Jin J Y, Zhang J J. An optic/proton dual-controlled fluorescence switch based on novel photochromic bithienylethene derivatives[J]. Chinese Journal of Chemistry, 2012, 30: 1741-1747.
[32] Lan H C, Lv G L, Wen Y, Mao Y, Huang C, Yi T. The synergic control of photocyclization and fluorescence in a pH-gated photochromic system[J]. Dyes and Pigments, 2016, 131: 18-23.
[33] Mahvidi S, Takeuchi S, Kusumoto S, Sato H. Gated photochromic system of diarylethene with a photon-working key[J]. Organic Letters, 2016, 18: 5042-5045.
[34] Zhang X X, Wang R J, Liu G, Fan C B, Pu S Z. A highly selective fluorescence probe for Al3+ based on a new diarylethene with a 6-(hydroxymethyl) picolinohydrazide unit[J]. Tetrahedron, 2016, 72: 8449-8455.
[35] Cui S Q, Tang Y J, Lu R M, Pu S Z. A multi-addressable diarylethene for selective detection of Al3+ and construction of logic circuit[J]. RSC Advances, 2016, 6: 107475-107482.
[36] Zhang X X, Wang R J, Liu G, Pu S Z. A highly selective fluorescent sensor for Cd2+ based on a new diarylethene with a 1,8-naphthyridine unit[J]. Dyes and Pigments, 2017, 139: 208-217.
[37] Dong X R, Wang R J, Liu G, Liu P, Pu S Z. A novel sensitive sensor for Cu2+ and multi-switch based on a diarylethene with a 2-(2-hydroxyphenyl)benzothiazole unit[J]. Tetrahedron, 2016, 72: 2935-2942.
[38] Xue Y M, Wang R J, Zheng C H, Liu P, Pu S Z. A new multi-addressable molecular switch based on a photochromic diarylethene with a thieno-imidazole unit[J]. Tetrahedron Letters, 2016, 57: 1877-1881.
[39] Wang R J, Dong X R, Liu G, Ren P, Pu S Z. Multi-functional ion-sensor based on a photochromic diarylethene with a 1H-imidazo [4, 5-f][1, 10] phenanthroline unit[J]. Luminescence, 2015, 30: 1290-1296.
[40] Zhou Z G, Xiao S Z, Xu J, Liu Z, Shi M, Li F, Huang C H. Modulation of the photochromic property in an organoboron-based diarylethene by a fluoride ion[J]. Organic Letters, 2006, 8: 3911-3914.
[41] Li Z, Zhang C, Ren Y, Yin J, Liu S H. Amide-and urea-functionalized dithienylethene: synthesis, photochromism, and binding with halide anions[J]. Organic Letters, 2011, 13: 6022-6025.
[42] Liu W, Hu F, Chen Z, Li Z, Yin J, Yu G A, Liu S H. Dithienylethenes containing aromatic carbons: synthesis, photochromism and anion recognition[J]. Dyes and Pigments, 2015, 115: 190-196.
[43] Hu F, Cao M J, Ma X, Liu S H, Yin J. Visible-light-dependent photocyclization: design, synthesis, and properties of a cyanine-based dithienylethene[J]. The Journal of Organic Chemistry, 2015, 80: 7830-7835.
[44] Fu Y L, Fan C B, Liu G, Pu S Z. A colorimetric and fluorescent sensor for Cu2+ and F- based on adiarylethene with a 1,8-naphthalimide Schiff base unit[J]. Sensors and Actuators B: Chemical, 2017, 239: 295-303.
[45] Jin J Y, Zhang J J, Zou L, Tian H. Near-infrared photochromic behavior in a donor-acceptor type diarylethene modulated by the cyanide anion[J]. Analyst, 2013, 138: 1641-1644.
[46] Jia H J, Pu S Z, Fan C B, Liu G, Zheng C H. A highly selective ratiometric fluorescent Cu2+ and HSO4- probe based on a new photochromic diarylethene with a 6-aryl[1,2-c]quinazoline unit[J]. Dyes and Pigments, 2015, 121: 211-220.
[47] Hu G F, Cheng H B, Niu J L, Zhang Z H, Wu H C. A multi-responsive molecular switch based on a diarylethene derivative containing dinitrobenzenesulfonic amide groups[J]. Dyes and Pigments, 2017, 136: 354-360.
[48] Liu H H, Chen Y. A bifunctional metal probe with independent signal outputs and regulable detection limits[J]. European Journal of Organic Chemistry, 2009, 30: 5261-5265.
[49] Huan S Y, Li Z Y, Li S S, Yin J, Liu S H. Imidazole-based dithienylethenes as a selective chemosensors for iron(Ⅲ) ions[J]. Dyes and Pigments, 2012, 92: 961-966.
[50] Li S S, Li Z Y, Huang S Y, Yin J, Liu S H. Synthesis, photochromism, and effects of metal ions on fluorescence of dithienylethenes containing imidazo[2,1-a]isoquinoline[J]. Synthetic Communications, 2013, 43: 1530-1537.
[51] Zhang J J, Tan W J, Meng X L. Soft mimic gear-shift with a multi-stimulus modified diarylethene[J]. Journal of Materials Chemistry, 2009, 19: 5726-5729.
[52] Pu S Z, Jiang D H, Liu W J, Liu G, Cui S Q. Multi-addressable molecular switches based on photochromic diarylethenes bearing a rhodamine unit[J]. Journal of Materials Chemistry, 2012, 22: 3517-3526.
[53] Pu S Z, Tong Z P, Liu G, Wang R J. Multi-addressable molecular switches based on a new diarylethene salicylal Schiff base derivative[J]. Journal of Materials Chemistry C, 2013, 1: 4726-4739.
[54] Piao X, Zou Y,Wu J, Li C, Yi T. Multiresponsive switchable diarylethene and its application in bioimaging[J]. Organic Letters, 2009, 11: 3818-3821.
[55] Fu Y L,Tu Y Y, Fan C B, Zheng C H, Liu G, P, S Z. A highly sensitive fluorescent sensor for Al3+ and Zn2+ based on a diarylethene salicylhydrazide Schiff base derivative and its bioimaging in live cells[J]. New Journal Chemistry, 2016, 40: 8579-8586.
[56] Lentz S R, Haynes W G. Homocysteine: it is a clinically important cardiovascular risk factor?[J]. Journal of Clinical Medicine, 2004, 71: 729-734.
[57] Gazit V, Ben-Abraham R, Coleman R, Weizman A, Katz Y. Cysteine-induced hypoglycemic brain damage: an alternative mechanism to excitotoxicity[J]. Amino Acids, 2004, 26: 163-168.
[58] Shahrokhian S. Lead phthalocyanine as a selective carrier for preparation of a cysteine-selective electrode[J]. Analytical Chemistry, 2001, 73: 5972-5978.
[59] Tanaka F, Mase N, Barbas Ⅲ C F. Determination of cysteine concentration by fluorescence increase: reaction of cysteine with a fluorogenic aldehyde[J]. Chemical Communications, 2004, 15: 1762-1763.
[60] Zheng C H, Pu S Z, Liu G, Chen B, Liu G, Dai Y. Syntheses and photochromism of new isomeric diarylethenes bearing an indole moiety[J]. Dyes and Pigments, 2013, 98: 280-285.
[61] Wang J C, Ma L L, Liu G, Ding H C, Pu S Z. Cysteine and homocysteine chemosensor based on photochromic diarylethene with fluorine[J]. Tetrahedron, 2016, 72: 8479-8485.
[62] Liao G M, Zheng C H, Xue D D, Fan C B, Liu G, Pu S Z. A diarylethene-based fluorescent chemosensor for the sequential recognition of Fe3+ and cysteine[J]. RSC Advances, 2016, 6: 34748-34753.
[63] Zou Y, Yi T, Xiao S Z, Li F, Li C, Gao X, Huang C. Amphiphilic diarylethene as a photoswitchable probe for imaging living cells[J]. Journal of the American Chemical Society, 2008, 130: 15750-15751.
[64] Hirose T, Matsuda K, Irie M. Self-assembly of photochromic diarylethenes with amphiphilic side chains: Reversible thermal and photochemical control[J]. The Journal of Organic Chemistry, 2006, 71: 7499-7508.
[65] Tong Z P, Pu S Z, Xiao Q, Liu G, Cui S Q. Synthesis and photochromism of a novel water-soluble diarylethene with glucosyltriazolyl groups[J]. Tetrahedron Letters, 2013, 54: 474-477.
[66] Duan F, Liu G, Fan C B, Pu S Z. Synthesis and photochromism of a novel amphiphilic diarylethene bearing two cholic acid groups[J]. Tetrahedron Letters, 2016, 57: 1963-1966. |