Time‐delayed photo‐induced depolymerization of poly(phthalaldehyde) self‐immolative polymer via in situ formation of weak conjugate acid

Jiang, Jisu; Phillips, Oluwadamilola; Engler, Anthony; Vong, Man Hou; Kohl, Paul A.

doi:10.1002/pat.4596

Cited by 7 publications

(2 citation statements)

References 27 publications

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“…10,25 While both linear and cyclic PPAs are intrinsically sensitive to acid, heat, and mechanical forces due to the vulnerable bonds in the hemiacetal units of the polymer backbone, [25][26][27] the reactivity of linear PPAs can be altered by installing an end group that can be selectively cleaved by a predetermined stimulus. [26][27][28] Plenty of studies that demonstrate site-specific depolymerization of linear end-capped PPA exist in the literature, with a library of investigated stimuli including palladium, 29 conjugate acids, 30 UV light, 27 fluorides, 31 and ultrasound. 32 Given the proven capability to functionally customize its end groups, in addition to its ability to depolymerize in the solid-state, 29,33 linear PPA stands out as a strong candidate for adhesive modulation by chemical triggers.…”

Section: Introductionmentioning

confidence: 99%

Functional design of stimuli-responsive poly(phthalaldehyde)-based adhesives: depolymerization kinetics and mechanical strength management through plasticizer addition

Damacet,

Yarbrough,

Blelloch

et al. 2024

Polym. Chem.

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Section: Introductionmentioning

confidence: 99%

Functional design of stimuli-responsive poly(phthalaldehyde)-based adhesives: depolymerization kinetics and mechanical strength management through plasticizer addition

Damacet,

Yarbrough,

Blelloch

et al. 2024

Polym. Chem.

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“…o -Phthalaldehyde (oPHA), T C = −35 °C, , is a versatile monomer that can be ionically polymerized or copolymerized with aldehydes and alkenes to create a variety of functional, depolymerizable materials. − Polyphthalaldehyde (PPHA) and its derivatives have shown to be promising materials for probe-based lithography − and other stimuli-responsive applications − because of their ability to rapidly depolymerize from the solid-state polymer. − The cationic polymerization route to PPHA is often preferred over the anionic route because the polymer has a longer shelf-life and higher molecular weight that improves the mechanical properties of the resulting material. , The anionic route provides lower dispersity and greater synthetic control with the opportunity to utilize functional endcaps.…”

Section: Introductionmentioning

confidence: 99%

Kinetic Investigation on the Cationic Polymerization of o-Phthalaldehyde: Understanding Ring-Expansion Polymerization

Engler

Kohl

2020

Macromolecules

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Depolymerizable polymers are of interest for engineering applications, especially when their decomposition products can be recycled back into high-value monomers. Polyphthalaldehyde and its derivatives form cyclic polymer products which can depolymerize rapidly from the solid state. To facilitate the development of these materials into technologies, the polymerization kinetics of this system was investigated. A microflow reactor was used to examine the cationic polymerization of o-phthalaldehyde with boron trifluoride diethyl etherate as the polymerization catalyst. By utilizing a microflow reactor, mass and heat resistances could be minimized to probe the kinetics of the reaction. High molecular weight polymer, >270 kDa, was formed in 10 s. Kinetic and molecular weight data indicate that two polymerization regimes exist. The first regime is characterized by controlled growth rates to moderate molecular weight polymers. The second regime occurs above a threshold concentration, where intermolecular chain transfer dominates the polymerization kinetics, resulting in an exponential growth of the polymer molecular weight via fusion of adjacent polymer chains. A ring-expansion polymerization model is proposed to explain these polymerization results. These findings enable greater synthetic control to achieve targeted polymer properties for poly(aldehydes) and identifies kinetic methods that can be employed to assess the activity of other polymerization catalysts.

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Sunlight‐Triggerable Transient Energy Harvester and Sensors Based on Triboelectric Nanogenerator Using Acid‐Sensitive Poly(phthalaldehyde)

Jiang

Guo

et al. 2019

Adv Elect Materials

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operation. [5] They have found potential applications as medical diagnostic and therapeutic devices that can resorb into the body, environmental sensors that do not require recovery after data collection, and consumer devices that can be easily disposed without hazards. [6] The potential feature of disappearance with minimal or non-traceable remains also enables transient electronics to find opportunities in privacy or security applications where stealth is required or reverse engineering needs to be avoided. The transience property is largely attributed to the triggerable degradation of device substrates and encapsulation, which are typically made of a group of materials called transient polymers. Depending on constituting material, the transience can be achieved either through material dissolution or depolymerization. Pioneering efforts on transient electronics focused on solution dissolution of polymer matrix. Bioresorbable polymers such as silk, polycaprolactone, poly(glycolic acid), and poly(L-lactide-co-glycolide), were used as substrates, [7][8][9] and biocompatible, implantable devices such as transistor, [1] ring oscillators, [10] and energy harvesters, [11] have been demonstrated. The lifetime of such devices is controlled by the dissolution rate of the materials in the surrounding aqueous solution, making them unsuitable for non-biological applications. Transient electronics that disintegrate via material dissolution or depolymerization under certain stimuli have great potential in biomedical and military applications. The triboelectric nanogenerator (TENG), an emerging mechanical energy harvesting technology with great flexibility in material choices, is promising in offering transient power sources. Previously reported transient energy harvesters using biodegradable polymers require solutionbased degradation and have limited applications in non-biological scenarios. A short time span, sunlight-triggered degradable TENG is developed. The main substrate includes an acid-sensitive poly(phthalaldehyde) (PPHA), a photoacid generator (PAG), and a photosensitizer (PS). Through photoinduced electron transfer, the ultraviolet radiation absorbed by the PS istransferred to the PAG to generate photoacids that trigger the depolymerization of PPHA. Transient TENG-based mechanical energy harvesters and touch/acoustic sensors are successfully demonstrated by embedding silver nanowires onto the PPHA-based films. The fabricated devices degrade rapidly under winter sunlight. The degradation rate can be further tuned via changing the ratio of photosensitive agents. This work not only broadens the applicability of TENG as transient power sources and sensors, but also extends the use of transient functional polymers toward advanced energy and sensing applications.

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Time‐delayed photo‐induced depolymerization of poly(phthalaldehyde) self‐immolative polymer via in situ formation of weak conjugate acid

Cited by 7 publications

References 27 publications

Functional design of stimuli-responsive poly(phthalaldehyde)-based adhesives: depolymerization kinetics and mechanical strength management through plasticizer addition

Functional design of stimuli-responsive poly(phthalaldehyde)-based adhesives: depolymerization kinetics and mechanical strength management through plasticizer addition

Kinetic Investigation on the Cationic Polymerization of o-Phthalaldehyde: Understanding Ring-Expansion Polymerization

Sunlight‐Triggerable Transient Energy Harvester and Sensors Based on Triboelectric Nanogenerator Using Acid‐Sensitive Poly(phthalaldehyde)

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