Dynamic surface patterns(DSPs)have attracted significant interest in anti-counterfeiting,enabling information to be stored,encrypted and decrypted in response to external stimuli.However,creating dynamic surface patte...Dynamic surface patterns(DSPs)have attracted significant interest in anti-counterfeiting,enabling information to be stored,encrypted and decrypted in response to external stimuli.However,creating dynamic surface patterns,capable of controlling wrinkling time and independently modulating different information in both wrinkled and fluorescent states,remains a tremendous challenge.These limit DSPs to further enhance tamper-proofing capacity and extend the information storage density.Here,a rationally designed patterning strategy based on controllable elastic modulus was demonstrated to fabricate self-erasable dynamic surface patterns(S-DSPs)that increase information storage density.These novel S-DSPs strategically integrated amino co-oligomers(ACOs)with the 9-anthracenemethanol(9-AM)as skin layers,designing a bilayer multi-encoding system which could carry several different types of information with wrinkled and fluorescent patterns.The ACOs with relatively low molecular weight can endow the elastic modulus of skin layers with a wide range of regulation.As a result,the difference between the compressive strain and the critical wrinkle strain in the bilayer system would be precisely modulated by photo-dimerization to form quick-response(minimum<1 min)and self-erasable(3 min–8 days)wrinkled patterns for S-DSPs.Meanwhile,the fluorescence pattern could be independently erased and reprogrammed without affecting the change in the wrinkle pattern under modulus-controlled conditions.Moreover,controllable self-erasure in S-DSPs significantly develops tamper-proof capabilities in a supply chain.This original strategy could provide a new approach to the tamper-proof,high-density,and multi-encoded information storage in the product security or inkless printing.展开更多
In this study, we developed an approach to fabricate novel 1D Ag NWs-Ag NPs hybrid substrate for enhanced fluorescene detection of protoporphyrin 1X (PplX) based on surface plasmon-enhanced fluorescence. The Ag NWs-...In this study, we developed an approach to fabricate novel 1D Ag NWs-Ag NPs hybrid substrate for enhanced fluorescene detection of protoporphyrin 1X (PplX) based on surface plasmon-enhanced fluorescence. The Ag NWs-Ag NPs hybrid was synthesized by combining the hydrothermal method and self-assembly method with the asisstance of polyvinylpyrrolidone (PVP). When the Ag NWs-Ag NPs hybrid was deposited on the glass substrate and employed as active substrate to detect PplX, the fluorescence intensity of PplX was enhanced greatly due to the coupling effect of localized surface plasmon-localized surface plasmon (LSP-LSP) and localized surface plasmon- surface plasmon propagation (LSP-SPP) which induced great enhancement of the electromagnetic field. Furthermore, the enhancement effect was approximately linear when the concentration of PpIX was ranged from 1×10^-7 mol/L to 2×10^-5 mol/L, and the photobleaching phenomenon of PplX was reduced greatly, indicating that the fab- ricated Ag NWs-Ag NPs hybrid substrate had well performance for PplX imaging. This work provides an effective approach to prepare highly sensitive and stable fluorescence enhancement substrate, and has great potential application in fluorescence imaging.展开更多
基金This work was supported by the National Natural Science Foundations of China(Nos.51903058,51873042,and 51833011)Key Laboratory for Polymeric Composite and Functional Materials of Ministry of Education(No.PCFM-2922A02)Guangzhou Basic and Applied Basic Research Foundation(No.202201010382).
文摘Dynamic surface patterns(DSPs)have attracted significant interest in anti-counterfeiting,enabling information to be stored,encrypted and decrypted in response to external stimuli.However,creating dynamic surface patterns,capable of controlling wrinkling time and independently modulating different information in both wrinkled and fluorescent states,remains a tremendous challenge.These limit DSPs to further enhance tamper-proofing capacity and extend the information storage density.Here,a rationally designed patterning strategy based on controllable elastic modulus was demonstrated to fabricate self-erasable dynamic surface patterns(S-DSPs)that increase information storage density.These novel S-DSPs strategically integrated amino co-oligomers(ACOs)with the 9-anthracenemethanol(9-AM)as skin layers,designing a bilayer multi-encoding system which could carry several different types of information with wrinkled and fluorescent patterns.The ACOs with relatively low molecular weight can endow the elastic modulus of skin layers with a wide range of regulation.As a result,the difference between the compressive strain and the critical wrinkle strain in the bilayer system would be precisely modulated by photo-dimerization to form quick-response(minimum<1 min)and self-erasable(3 min–8 days)wrinkled patterns for S-DSPs.Meanwhile,the fluorescence pattern could be independently erased and reprogrammed without affecting the change in the wrinkle pattern under modulus-controlled conditions.Moreover,controllable self-erasure in S-DSPs significantly develops tamper-proof capabilities in a supply chain.This original strategy could provide a new approach to the tamper-proof,high-density,and multi-encoded information storage in the product security or inkless printing.
文摘In this study, we developed an approach to fabricate novel 1D Ag NWs-Ag NPs hybrid substrate for enhanced fluorescene detection of protoporphyrin 1X (PplX) based on surface plasmon-enhanced fluorescence. The Ag NWs-Ag NPs hybrid was synthesized by combining the hydrothermal method and self-assembly method with the asisstance of polyvinylpyrrolidone (PVP). When the Ag NWs-Ag NPs hybrid was deposited on the glass substrate and employed as active substrate to detect PplX, the fluorescence intensity of PplX was enhanced greatly due to the coupling effect of localized surface plasmon-localized surface plasmon (LSP-LSP) and localized surface plasmon- surface plasmon propagation (LSP-SPP) which induced great enhancement of the electromagnetic field. Furthermore, the enhancement effect was approximately linear when the concentration of PpIX was ranged from 1×10^-7 mol/L to 2×10^-5 mol/L, and the photobleaching phenomenon of PplX was reduced greatly, indicating that the fab- ricated Ag NWs-Ag NPs hybrid substrate had well performance for PplX imaging. This work provides an effective approach to prepare highly sensitive and stable fluorescence enhancement substrate, and has great potential application in fluorescence imaging.
