Redox-Responsive, Reconfigurable All-Liquid Constructs

Sun, Huilou; Li, Mingwei; Li, Lianshun; Liu, Tan; Luo, Yuzheng; Russell, Thomas P.; Shi, Shaowei

doi:10.1021/jacs.1c00429

Cited by 64 publications

(52 citation statements)

References 28 publications

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“…Regulated by external stimuli, the JNS emulsifiers were convertible between surface-active and surface-inactive, enabling emulsification and demulsification in a controllable manner. Many external stimuli, such as CO 2 /N 2 , pH, redox state, temperature, and light irradiation, have been reported to regulate the surface activity of JNP materials. − However, the stimuli of CO 2 /N 2 , pH, and redox state are invasive, which often bring about some undesirable side effects in catalytic reactions. − Triggers such as temperature and light are noninvasive, but they are limited to small-scale operation (temperature changes are energy-intensive and time-consuming, and light has a limited penetration depth in reaction solution due to the opaqueness of emulsions). − In addition, such external stimuli modes required additional steps to regulate the stability of Pickering emulsions, which was unfavorable for energy-saving and sustainable industrial applications. If the emulsion characteristics can be controlled by the catalytic reaction process without any additives and additional energy input, that is, the emulsion is stable during the reaction, and quickly demulsified when the reaction is completed, these problems can be solved.…”

Section: Introductionmentioning

confidence: 99%

Phosphotungstate-Functionalized Mesoporous Janus Silica Nanosheets for Reaction-Controlled Pickering Interfacial Catalysis

Liu

et al. 2021

ACS Sustainable Chem. Eng.

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Pickering interfacial catalysis enables oil/water biphasic reactions to efficiently proceed by the formation of stable Pickering emulsions. However, a convenient approach to control the emulsion properties, so as to combine the reactivity and recovery of catalytic emulsifiers, remains challenging to date. Herein, we have reported the switchable transition between emulsification/demulsification controlled by the catalytic reaction process, to realize reaction-controlled Pickering interfacial catalysis. A novel series of phosphotungstate (PW)-functionalized mesoporous Janus silica nanosheets were thus prepared by selectively decorating ammonium PW on one side of mesosilica nanosheets. Characterization results suggested their H2O2-switched reversible emulsification/demulsification behavior in an oil/water biphasic system due to H2O2-induced wettability change in the ammonium PW moiety. The resultant H2O2-switchable Pickering emulsions induced an efficient Pickering interfacial catalysis approach for selective oxidation of alcohols by aqueous H2O2 in water, thus leading to remarkable high conversion and selectivity over a wide range of alcohols. When H2O2 was used up, they could be demulsified spontaneously, resulting in the complete separation of catalytic emulsifiers for steady reuse. The reaction-controlled emulsification/demulsification approach provided a sustainable way to combine reactivity and recovery of catalytic emulsifiers in Pickering interfacial catalysis, which was a benefit for energy-saving in industrial applications.

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Section: Introductionmentioning

confidence: 99%

Phosphotungstate-Functionalized Mesoporous Janus Silica Nanosheets for Reaction-Controlled Pickering Interfacial Catalysis

Liu

et al. 2021

ACS Sustainable Chem. Eng.

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“…With surfactants assembled at the interface, one liquid can be dispersed in another immiscible liquid to form emulsion droplets, which typically take spherical shapes to decrease the interfacial area and, therefore, to reduce the interfacial energy [5–8] . Recently, by using the electrostatic interactions or host–guest interactions between nanoparticles (NPs) dispersed in aqueous phase and polymeric/oligomeric ligands dissolved in oil phase to form nanoparticle surfactants (NPSs) at the oil–water interface, an alternate strategy is put forward to stabilize the oil–water interface [9–12] . Due to the self‐regulated number of ligands anchored to the NPs, the binding energy of the NPs can be significantly enhanced to withstand the compressive force exerted on the particles when the interfacial area decreases, allowing the stabilization of liquids in nonequilibrium shapes, i.e., structuring liquids [13–15] .…”

Section: Methodsmentioning

confidence: 99%

“…The reversible, dynamic noncovalent interactions between NPs and ligands play a crucial role in the formation of NPSs at the interface, not only endowing NPSs with self‐regulating properties to maximize the reduction in the interfacial energy, [26] but also giving the resultant liquid constructs reconfigurable properties in response to environmental stimuli, like pH, light, and redox [11–12, 27] . Among the various noncovalent interactions used to construct supramolecular systems, charge transfer (CT) interactions between electron‐rich donors and electron‐deficient acceptors have attracted extensive attention with regard to their optical and electronic properties [28–31] .…”

Section: Methodsmentioning

confidence: 99%

Responsive Interfacial Assemblies Based on Charge‐Transfer Interactions

et al. 2021

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Charge transfer (CT) interactions have been widely used to construct supramolecular systems, such as functional nanostructures and gels. However, to date, there is no report on the generation of CT complexes at the liquid–liquid interface. Here, by using an electron‐deficient acceptor dissolved in water and an electron‐rich donor dissolved in oil, we present the in situ formation and assembly of CT complex surfactants (CTCSs) at the oil–water interface. With time, CTCSs can assemble into higher‐order nanofilms with exceptional mechanical properties, allowing the stabilization of liquids and offering the possibility to structure liquids into nonequilibrium shapes. Moreover, due to the redox‐responsiveness of the electron‐deficient acceptor, the association and dissociation of CTCSs can be reversibly manipulated in a redox process, leading to the switchable assembly and disassembly of the resultant constructs.

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“…Recently, a cooperative assembly strategy was put forward by using the noncovalent interactions between functionalized NPs dispersed in one liquid and polymeric ligands with complementary functionality dissolved in the second liquid [12–14] . “Janus‐like” nanoparticle surfactants (NPSs) form in situ at the interface, maximizing the reduction in the interfacial energy per particle and of the assembly, and generating an elastic NPS monolayer at the interface.…”

Section: Introductionmentioning

confidence: 99%

The Assembly and Jamming of Nanoparticle Surfactants at Liquid–Liquid Interfaces

et al. 2022

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Using the interactions between nanoparticles (NPs) and polymeric ligands to generate nanoparticle surfactants (NPSs) at the liquid–liquid interface, the binding energy of the NP to the interface can be significantly increased, irreversibly binding the NPSs to the interface. By designing a simplified NPS model, where the NP size can be precisely controlled and the characteristic fluorescence of the NPs be used as a direct probe of their spatial distribution, we provide new insights into the attachment mechanism of NPSs at the liquid–liquid interface. We find that the binding energy of NPSs to the interface can be reduced by competitive ligands, resulting in the dissociation and disassembly of NPSs at the interface, and allowing the construction of responsive, reconfigurable all‐liquid systems. Smaller NPSs that are loosely packed (unjammed) and irreversibly bound to the interface can be displaced by larger NPSs, giving rise to a size‐dependent assembly of NPSs at the interface. However, when the smaller size NPSs are densely packed and jam at the interface, the size‐dependent assembly of NPSs at the interface can be completely suppressed.

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Redox-Responsive, Reconfigurable All-Liquid Constructs

Cited by 64 publications

References 28 publications

Phosphotungstate-Functionalized Mesoporous Janus Silica Nanosheets for Reaction-Controlled Pickering Interfacial Catalysis

Phosphotungstate-Functionalized Mesoporous Janus Silica Nanosheets for Reaction-Controlled Pickering Interfacial Catalysis

Responsive Interfacial Assemblies Based on Charge‐Transfer Interactions

The Assembly and Jamming of Nanoparticle Surfactants at Liquid–Liquid Interfaces

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