LibCat » Книги » Приключения » unrecognised » Handbook of Aggregation-Induced Emission, Volume 3

Handbook of Aggregation-Induced Emission, Volume 3

Здесь есть возможность читать онлайн «Handbook of Aggregation-Induced Emission, Volume 3» — ознакомительный отрывок электронной книги совершенно бесплатно, а после прочтения отрывка купить полную версию. В некоторых случаях можно слушать аудио, скачать через торрент в формате fb2 и присутствует краткое содержание. Жанр: unrecognised, на английском языке. Описание произведения, (предисловие) а так же отзывы посетителей доступны на портале библиотеки ЛибКат.

Читать книгу

Название:
Handbook of Aggregation-Induced Emission, Volume 3
Автор:
Неизвестный Автор
Жанр:
unrecognised / на английском языке
Год:
неизвестен
ISBN:
нет данных
Рейтинг книги:
4 / 5. Голосов: 1
Избранное:

Добавить в избранное
Отзывы:
Написать комментарий
Ваша оценка:
- 80
- 1
- 2
- 3
- 4
- 5

Handbook of Aggregation-Induced Emission, Volume 3: краткое содержание, описание и аннотация

Предлагаем к чтению аннотацию, описание, краткое содержание или предисловие (зависит от того, что написал сам автор книги «Handbook of Aggregation-Induced Emission, Volume 3»). Если вы не нашли необходимую информацию о книге — напишите в комментариях, мы постараемся отыскать её.

The third volume of the ultimate reference on the science and applications of aggregation-induced emission The Handbook of Aggregation-Induced Emission In
the editors address the applications of AIEgens in several fields, including bio-imaging, fluorescent molecular switches, electrochromic materials, regenerative medicine, detection of organic volatile contaminants, hydrogels, and organogels. Topics covered include:
AIE-active emitters and their applications in OLEDs, and circularly polarized luminescence of aggregation-induced emission materials AIE polymer films for optical sensing and energy harvesting, aggregation-induced electrochemiluminescence, and mechanoluminescence materials with aggregation-induced emission Dynamic super-resolution fluorescence imaging based on photoswitchable fluorescent spiropyran Visualization of polymer microstructures Self-assembly of micelle and vesicles New strategies for biosensing and cell imaging Perfect for academic researchers working on aggregation-induced emission, this set of volumes is also ideal for professionals and students in the fields of photophysics, photochemistry, materials science, optoelectronic materials, synthetic organic chemistry, macromolecular chemistry, polymer science, and biological sciences.

Handbook of Aggregation-Induced Emission, Volume 3 — читать онлайн ознакомительный отрывок

Ниже представлен текст книги, разбитый по страницам. Система сохранения места последней прочитанной страницы, позволяет с удобством читать онлайн бесплатно книгу «Handbook of Aggregation-Induced Emission, Volume 3», без необходимости каждый раз заново искать на чём Вы остановились. Поставьте закладку, и сможете в любой момент перейти на страницу, на которой закончили чтение.

Тёмная тема

Шрифт:

↓

↑

Сбросить

Интервал:

↓

↑

Закладка:

Сделать

72 72 Jenkin ME, Saunders SM, Pilling MJ (1997). The tropospheric degradation of volatile organic compounds: a protocol for mechanism development. Atm. Env. 31(1): 81–104.

73 73 Kim YM, Harrad S, Harrison RM (2001). Concentrations and sources of VOCs in urban domestic and public microenvironments. Environ. Sci. Technol. 35(6): 997–1004.

74 74 Germain ME, Knapp MJ (2009). Optical explosives detection: from color changes to fluorescence turn‐on. Chem. Soc. Rev. 38(9): 2543–55.

75 75 Salinas Y, Martinez‐Manez R, Marcos MD, Sancenon F, Costero AM, Parra M, et al. (2012). Optical chemosensors and reagents to detect explosives. Chem. Soc. Rev. 41(3): 1261–96.

76 76 Sun X, Wang Y, Lei Y (2015). Fluorescence based explosive detection: from mechanisms to sensory materials. Chem. Soc. Rev. 44(22): 8019–61.

77 77 Janzen MC, Ponder JB, Bailey DP, Ingison CK, Suslick KS (2006). Colorimetric sensor arrays for volatile organic compounds. Anal. Chem. 78(11): 3591–600.

78 78 Rakow NA, Suslick KS (2000). A colorimetric sensor array for odour visualization. Nature 406(6797): 710–3.

79 79 Thomas SW, Joly GD, Swager TM (2007). Chemical sensors based on amplifying fluorescent conjugated polymers. Chem. Rev. 107(4): 1339–86.

80 80 Hu R, Lam JWY, Yu Y, Sung HHY, Williams ID, Yuen MMF, et al. (2013). Facile synthesis of soluble nonlinear polymers with glycogen‐like structures and functional properties from “simple” acrylic monomers. Polym. Chem. 4(1): 95–105.

81 81 Aldred MP, Li C, Zhang G‐F, Gong W‐L, Li ADQ, Dai Y, et al. (2012). Fluorescence quenching and enhancement of vitrifiable oligofluorenes end‐capped with tetraphenylethene. J. Mater. Chem. 22(15): 7515–28.

82 82 Minei P, Ahmad M, Barone V, Brancato G, Passaglia E, Bottari G, et al. (2016). Vapochromic behavior of polycarbonate films doped with a luminescent molecular rotor. Polym. Adv. Technol. 27(4): 429–35.

83 83 Minei P, Koenig M, Battisti A, Ahmad M, Barone V, Torres T, et al. (2014). Reversible vapochromic response of polymer films doped with a highly emissive molecular rotor. J. Mater. Chem. C 2(43): 9224–32.

84 84 Iasilli G, Martini F, Minei P, Ruggeri G, Pucci A (2017). Vapochromic features of new luminogens based on julolidine‐containing styrene copolymers. Faraday Disc. 196: 113–29.

85 85 Borelli M, Iasilli G, Minei P, Pucci A (2017). Fluorescent polystyrene films for the detection of volatile organic compounds using the twisted intramolecular charge transfer mechanism. Molecules 22(8): 1306.

86 86 Guidugli N, Mori R, Bellina F, Tang BZ, Pucci A (2019). Aggregation‐induced emission: new emerging fluorophores for environmental sensing. In: Tang Y, Tang BZ, editors. Principles and Applications of Aggregation‐Induced Emission. Cham: Springer International Publishing. p. 335–49.

87 87 Cheng Y, Wang J, Qiu Z, Zheng X, Leung NLC, Lam JWY, et al. (2017). Multiscale humidity visualization by environmentally sensitive fluorescent molecular rotors. Adv. Mater. 29(46): 1703900.

88 88 Iasilli G, Francischello R, Lova P, Silvano S, Surace A, Pesce G, et al. (2019). Luminescent solar concentrators: boosted optical efficiency by polymer dielectric mirrors. Mater. Chem. Front. 3(3): 429–36.

89 89 Geervliet TA, Gavrila I, Iasilli G, Picchioni F, Pucci A (2019). Luminescent solar concentrators based on renewable polyester matrices. Chem‐Asian J. 14(6): 877–83.

90 90 Papucci C, Geervliet TA, Franchi D, Bettucci O, Mordini A, Reginato G, et al. (2018). Green/yellow‐emitting conjugated heterocyclic fluorophores for luminescent solar concentrators. Eur. J. Org. Chem. 2018(20): 2657–66.

91 91 Gianfaldoni F, De Nisi F, Iasilli G, Panniello A, Fanizza E, Striccoli M, et al. (2017). A push–pull silafluorene fluorophore for highly efficient luminescent solar concentrators. RSC Adv. 7(59): 37302–9.

92 92 Lucarelli J, Lessi M, Manzini C, Minei P, Bellina F, Pucci A (2016). N‐Alkyl diketopyrrolopyrrole‐based fluorophores for luminescent solar concentrators: effect of the alkyl chain on dye efficiency. Dye. Pigm. 135: 154–62.

93 93 Carlotti M, Fanizza E, Panniello A, Pucci A (2015). A fast and effective procedure for the optical efficiency determination of luminescent solar concentrators. Sol. Ener. 119: 452–60.

94 94 Swanson RM (2000). The promise of concentrators. Progr. Photovolt. Res. Appl. 8(1): 93–111.

95 95 Debije M (2015). Renewable energy better luminescent solar panels in prospect. Nature (Lond. UK) 519(7543): 298–9.

96 96 Debije MG, Verbunt PPC (2012). Thirty years of luminescent solar concentrator research: solar energy for the built environment. Adv. Ener. Mater. 2(1): 12–35.

97 97 Garwin RL (1960). The collection of light from scintillation counters. Rev. Sci. Instrum. 31(9): 1010–1.

98 98 Weber WH, Lambe J (1976). Luminescent greenhouse collector for solar radiation. Appl. Opt. 15(10): 2299–300.

99 99 Goetzberger A, Greube W (1977). Solar energy conversion with fluorescent collectors. Appl. Phys. 14(2): 123–39.

100 100 Krumer Z, van Sark WGJHM, Schropp REI, Donega CdM (2017). Compensation of self‐absorption losses in luminescent solar concentrators by increasing luminophore concentration. Sol. Ener. Mater. Sol. Cell. 167: 133–9.

101 101 Mei J, Leung NLC, Kwok RTK, Lam JWY, Tang BZ (2015). Aggregation‐induced emission: together we shine, united we soar! Chem. Rev. (Wash. USA) 115(21): 11718–940.

102 102 De Nisi F, Francischello R, Battisti A, Panniello A, Fanizza E, Striccoli M, et al. (2017). Red‐emitting AIEgen for luminescent solar concentrators. Mater. Chem. Front. 1(7): 1406–12.

103 103 Liu B, Pucci A, Baumgartner T (2017). Aggregation induced emission: a land of opportunities. Mater. Chem. Front. 1(9): 1689–90.

104 104 Kang M, Gu X, Kwok RTK, Leung CWT, Lam JWY, Li F, et al. (2016). A near‐infrared AIEgen for specific imaging of lipid droplets. Chem. Commun. 52(35): 5957–60.

105 105 Banal JL, White JM, Ghiggino KP, Wong WWH (2014). Concentrating aggregation‐induced fluorescence in planar waveguides: a proof‐of‐principle. Sci. Rep. 4: 4635/1–/5.

106 106 Banal JL, Ghiggino KP, Wong WWH (2014). Efficient light harvesting of a luminescent solar concentrator using excitation energy transfer from an aggregation‐induced emitter. Phys. Chem. Chem. Phys. 16(46): 25358–63.

107 107 Banal JL, Zhang B, Jones DJ, Ghiggino KP, Wong WWH (2017). Emissive molecular aggregates and energy migration in luminescent solar concentrators. Acc. Chem. Res. 50(1): 49–57.

108 108 Zhang B, Banal JL, Jones DJ, Tang BZ, Ghiggino KP, Wong WWH (2018). Aggregation‐induced emission‐mediated spectral downconversion in luminescent solar concentrators. Mater. Chem. Front. 2(3): 615–9.

109 109 Flores Daorta S, Proto A, Fusco R, Claudio Andreani L, Liscidini M (2014). Cascade luminescent solar concentrators. Appl. Phys. Lett. 104(15): 153901.

110 110 Altan Bozdemir O, Erbas‐Cakmak S, Ekiz OO, Dana A, Akkaya EU (2011). Towards unimolecular luminescent solar concentrators: BODIPY‐based dendritic energy‐transfer cascade with panchromatic absorption and monochromatized emission. Angew. Chem. Int. Ed. 50(46): 10907–12.

111 111 Currie MJ, Mapel JK, Heidel TD, Goffri S, Baldo MA (2008). High‐efficiency organic solar concentrators for photovoltaics. Science 321(5886): 226–8.

112 112 Carlotti M, Ruggeri G, Bellina F, Pucci A (2016). Enhancing optical efficiency of thin‐film luminescent solar concentrators by combining energy transfer and stacked design. J. Lumin. 171: 215–20.

113 113 Mori R, Iasilli G, Lessi M, Munoz‐Garcia AB, Pavone M, Bellina F, et al. (2018). Luminescent solar concentrators based on PMMA films obtained from a red‐emitting ATRP initiator. Polym. Chem. 9(10): 1168–77.