Off‑on/On‑off Dual‑Mode Hydrochromic Materials： Water‑Induced Acidity Changes in the Microenvironment Regulate the Color Switching of Rhodamine Derivatives

doi:10.19894/j.issn.1000-0518.210334

Chinese Journal of Applied Chemistry ›› 2022, Vol. 39 ›› Issue (7): 1119-1128.DOI: 10.19894/j.issn.1000-0518.210334

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Off‑on/On‑off Dual‑Mode Hydrochromic Materials： Water‑Induced Acidity Changes in the Microenvironment Regulate the Color Switching of Rhodamine Derivatives

Xiao-Yan WEI, Jin-Yan ZHANG, Lan SHENG(), Sean Xiao-An ZHANG

State key Laboratong of Supramolecular Strccture and Materiats，Jilin University，Changchun 130012，China

Received:2021-07-09 Accepted:2021-10-22 Published:2022-07-01 Online:2022-07-11
Contact: Lan SHENG
About author:shenglan17@jlu.edu.cn
Supported by:
the National Natural Science Foundation of China(21975099);the Outstanding Youth Talent Fund Project of Jilin Provincial Science and Technology Development Program(20190103126JH)

Abstract

Abstract:

Based on the phenomenon that rhodamine derivatives （4-N-acrylamide-（3'，6'-bis（diethylamino）-spiro［isobenzofuran-1，9'-xanthene］-3-one）（AM-RhB） will open the lactone ring to display color or emit fluorescence under moderate acidic conditions （4.4<pH<6） and will occur excessive protonation， color and fluorescence are “lost” when they are in strongly acidic microenvironment （pH<1）， we propose a new strategy for constructing dual-mode hydrochromic materials. AM-RhB is mixed with solid acid as the imaging layer， and the acidity of the solid acid is adjusted （weakened or strengthened） by introducing and removing water to make the molecule in the ring-open form or excessive protonation state， thereby regulating the reversible change between the color and fluorescence of the material （on/off）. By selecting different solid acids （benzenesulfonic acid and sulfamic acid） respectively， we realize the “off-on” and “on-off” two different color rendering modes of the dual-mode hydrochromic materials， and demonstrate its application in Water-jet printing. The prepared printing paper shows high reflectivity change （optical modulation）（>25%） and fluorescence intensity modulation （>700） before and after stimulating with water， and good reversibility （> 5 times）. This work will provide a promising way for the development of new hydrochromic materials.

Key words: Rhodamine derivatives, Hydrochromic material, Dual-mode, Microenvironment

CLC Number:

O621.2

Xiao-Yan WEI, Jin-Yan ZHANG, Lan SHENG, Sean Xiao-An ZHANG. Off‑on/On‑off Dual‑Mode Hydrochromic Materials： Water‑Induced Acidity Changes in the Microenvironment Regulate the Color Switching of Rhodamine Derivatives[J]. Chinese Journal of Applied Chemistry, 2022, 39(7): 1119-1128.

Figures/Tables 6

Fig.1 （A） UV-Vis absorption spectra and （B） fluorescent emission spectra of AM-RhB in THF with different molar of hydrochloric acid （n（AM-RhB）=0.3 mmoL，V（AM-RhB）=3 mL， λex = 530 nm， slit width： 3 nm， 3 nm）；（C） Structural changes of molecules in solution

Fig.2 Schematic diagram of hydrochromic fluorescent materials based on the principle of “over-protonation”

Fig.3 （A） Schematic diagram of the material structure；（B） The UV-Vis reflective spectra and （C） fluorescence emission spectra of the “off-on” mode material before and after adding water （λex=560 nm， slit width： 5 nm， 3 nm）；（D） Plot of visible reflection（left） and fluorescent emission intensity（right） at λmax of hydrochromic fluorescent materials based on different acid （λex = 560 nm， slit width： 5 nm，3 nm）；（E） Picture of materials in different condition

Fig.4 （A） The UV-Vis reflective spectra and （B） fluorescence emission spectra of the “on-off” mode material before and after adding water （λex = 550 nm， slit width： 5 nm， 3 nm）； The change of （C） color and （D，E） visible reflection of SFA， MO and mixture before and after adding water

Fig.5 （A） Time-dependent reflectivity variations at 568 nm for AM-RhB based WJRP upon adding a droplet of water during 0~500 s， respectively. Blue arrows indicate the moment of adding water. （B） L*， a*， b* measured by spectrodensitometer and photographs of the “off-on” mode paper before （up） and after （down） adding water， respectively. （C） Microscopic images （up） and fluorescence images （down） of the “off-on” mode paper before and after addition of water

Fig.6 （A） Photographs during 5 consecutive print-erase rounds on the dual-mode hydrochromic paper. （B） A plot of the reflectivity at 568 nm and （C） fluorescent intensity at 592 nm versus the number of cycles as the WJRP is cycled through water spraying （Write） and water removal （Erase） by means of wetting/heating at 60 ℃ （λex = 560 nm， slit width： 5 nm， 3 nm）

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Off‑on/On‑off Dual‑Mode Hydrochromic Materials： Water‑Induced Acidity Changes in the Microenvironment Regulate the Color Switching of Rhodamine Derivatives

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