Conductive Ink with Circular Life Cycle for Printed Electronics

Kwon, Junpyo; DelRe, Christopher; Kang, Philjun; Hall, Aaron; Arnold, Daniel; Jayapurna, Ivan; Ma, Le; Michalek, Matthew; Ritchie, Robert O.; Xu, Ting

doi:10.1002/adma.202202177

Cited by 37 publications

(26 citation statements)

References 27 publications

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“…Utilizing and mimicking protein function is a key approach to unlocking advanced, robust, cheap, and scalable functional materials. Heteropolymers are routinely used for surfactants, − hydrogels, , polyelectrolytes, − gene delivery, − and more. − Chemistry diversification through monomer increments, side-chain modifications, or block copolymerization have been unsystematically explored as the primary design criteria for material functionalization. However, a more general chemical heterogeneity framework for rational design of protein-like heteropolymers is still lacking.…”

Section: Introductionmentioning

confidence: 99%

Sequence Design of Random Heteropolymers as Protein Mimics

et al. 2023

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Random heteropolymers (RHPs) have been computationally designed and experimentally shown to recapitulate protein-like phase behavior and function. However, unlike proteins, RHP sequences are only statistically defined and cannot be sequenced. Recent developments in reversible-deactivation radical polymerization allowed simulated polymer sequences based on the well-established Mayo−Lewis equation to more accurately reflect ground-truth sequences that are experimentally synthesized. This led to opportunities to perform bioinformatics-inspired analysis on simulated sequences to guide the design, synthesis, and interpretation of RHPs. We compared batches on the order of 10000 simulated RHP sequences that vary by synthetically controllable and measurable RHP characteristics such as chemical heterogeneity and average degree of polymerization. Our analysis spans across 3 levels: segments along a single chain, sequences within a batch, and batch-averaged statistics. We discuss simulator fidelity and highlight the importance of robust segment definition. Examples are presented that demonstrate the use of simulated sequence analysis for in-silico iterative design to mimic protein hydrophobic/hydrophilic segment distributions in RHPs and compare RHP and protein sequence segments to explain experimental results of RHPs that mimic protein function. To facilitate the community use of this workflow, the simulator and analysis modules have been made available through an open source toolkit, the RHPapp.

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Section: Introductionmentioning

confidence: 99%

Sequence Design of Random Heteropolymers as Protein Mimics

et al. 2023

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“…The full degradation times of E0Et80 and E0.3Et80 are calculated to be 115 and 121 d for E0Et80 and E0.3Et80 (see Figure S13b), respectively, indicating that chemical cross-linking slightly prolongs the degradation time of E0.3Et80, without hindering the process of degradation. Additionally, chitin materials exhibited rapid and almost complete degradation in Chitinase solutions, facilitating the separation and recovery of electronic substances, such as the precious metal silver. , Figure e shows photographs of various stages of gradual degradation and separation of the E0.3Et80-Ag flexible electrodes in Chitinase solution. Light microscopy images (Figure f) indicate the gradual increase and expansion of cracks, and degradation of floc at the surface and edges, followed by the gradual degradation into tiny fragments and nonforming slime.…”

Section: Resultsmentioning

confidence: 99%

Stretchable, Biodegradable Dual Cross-Linked Chitin Hydrogels with High Strength and Toughness and their Potential Applications in Flexible Electronics

Wang

et al. 2023

ACS Sustainable Chem. Eng.

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Sensors, displays, and energy storage devices utilized in electronics are undergoing a rapid transition from rigid to flexible and stretchable materials. Traditional electronics-material substrates (metals and semiconductors) have several flaws, including insufficient softness and flexibility and high fragility, resulting in breakage upon stretching and folding. In addition, these materials have limited biodegradability for recycling. Thus, natural polymer hydrogels, with intrinsic biodegradability and biocompatibility, have been recently used to fabricate eco-friendly sensors and flexible energy storage devices. These hydrogels exhibit a vast range of tunable mechanical properties, making them suitable for the fabrication of flexible electronics. Here, dual cross-linked chitin hydrogels with high strength, flexibility, and biodegradability were synthesized using a sequential chemical and physical cross-linking strategy. The dual cross-linked chitin hydrogels exhibited a more comprehensive energy dissipation mechanism than hydrogels that were only physically or chemically cross-linked. Additionally, they could be used as flexible substrates for screen printing, with immense potential applications in the fields of wearable sensors and flexible supercapacitors. Furthermore, the hydrogel-based flexible electronics can be biodegraded in soil or easily recycled in Chitinase solution. This strategy provides a promising route for creating high strength, toughness, and biodegradable chitin hydrogels, which may contribute to the sustainable development of flexible electronics.

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“…Another example using organic solvent systems involves the synthesis of random heteropolymers (RHP) with co-monomer distribution matching the protein surface pattern of the enzyme for stabilization and solubilization in organic solvents [ 86 ]. Xu and co-workers dissolved RHP-stabilized lipase together with PCL and a conductive filler for DIW of biodegradable electronic circuits [ 87 ]. The printed circuit remained functional and fully degradable, upon immersion in warm water, for at least 7 months at room temperature storage and after 1-month continuous exposure to electrical voltage.…”

Section: Immobilization By Physical Entrapment During 3d Printingmentioning

confidence: 99%

Advances in 3D Gel Printing for Enzyme Immobilization

Shen

Zhang

Fang

et al. 2022

Gels

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Incorporating enzymes with three-dimensional (3D) printing is an exciting new field of convergence research that holds infinite potential for creating highly customizable components with diverse and efficient biocatalytic properties. Enzymes, nature’s nanoscale protein-based catalysts, perform crucial functions in biological systems and play increasingly important roles in modern chemical processing methods, cascade reactions, and sensor technologies. Immobilizing enzymes on solid carriers facilitates their recovery and reuse, improves stability and longevity, broadens applicability, and reduces overall processing and chemical conversion costs. Three-dimensional printing offers extraordinary flexibility for creating high-resolution complex structures that enable completely new reactor designs with versatile sub-micron functional features in macroscale objects. Immobilizing enzymes on or in 3D printed structures makes it possible to precisely control their spatial location for the optimal catalytic reaction. Combining the rapid advances in these two technologies is leading to completely new levels of control and precision in fabricating immobilized enzyme catalysts. The goal of this review is to promote further research by providing a critical discussion of 3D printed enzyme immobilization methods encompassing both post-printing immobilization and immobilization by physical entrapment during 3D printing. Especially, 3D printed gel matrix techniques offer mild single-step entrapment mechanisms that produce ideal environments for enzymes with high retention of catalytic function and unparalleled fabrication control. Examples from the literature, comparisons of the benefits and challenges of different combinations of the two technologies, novel approaches employed to enhance printed hydrogel physical properties, and an outlook on future directions are included to provide inspiration and insights for pursuing work in this promising field.

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Conductive Ink with Circular Life Cycle for Printed Electronics

Cited by 37 publications

References 27 publications

Sequence Design of Random Heteropolymers as Protein Mimics

Sequence Design of Random Heteropolymers as Protein Mimics

Stretchable, Biodegradable Dual Cross-Linked Chitin Hydrogels with High Strength and Toughness and their Potential Applications in Flexible Electronics

Advances in 3D Gel Printing for Enzyme Immobilization

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