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Encoding Circularity in Polydiketoenamine Thermoplastics via Oxy-Functionalization

25 June 2024, Version 1
Working Paper
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Here, we show that oxy-functionalization at specific sites along polydiketoenamine (PDK) backbones affects depolymerization rates by over three orders of magnitude, due to differences in distortion energies associated with reactive chain conformations in transition states for acidolysis. Site-specific oxy-functionalization, resulting in the fastest rates of acidolysis, opens the door to deconstructing linear PDK chain topologies for the first time, broadening the scope of applications for PDK plastics in a circular manufacturing economy, including chemically recyclable adhesives for a diverse range of surfaces.

Keywords

circularity
PDK
recycling

Supplementary materials

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Supplementary information Methods Supplementary Figs. 1–18 Supplementary Tables 1–6 Supplementary References 1–9
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Version History

Jun 25, 2024 Version 1

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The content is available under CC BY NC ND 4.0 [opens in a new tab]

DOI

10.26434/chemrxiv-2024-p5q4d
D O I: 10.26434/chemrxiv-2024-p5q4d [opens in a new tab]

Funding

Basic Energy Sciences
Unlocking Chemical Circularity in Recycling by Controlling Polymer Reactivity Across Scales program CUP-LBL-Helms
Basic Energy Sciences
DE-AC02- 05-CH11231
National Science Foundation
DGE 1752814

Author’s competing interest statement

B.A.H. is an inventor on the U.S. provisional patent application 62/587,148 and B.A.H., A.E.P., J.D., and K.A.P. are inventors on U.S. provisional patent application 63/390,962, both submitted by Lawrence Berkeley National Laboratory that covers PDKs, as well as aspects of their use and recovery. B.A.H. has a financial interest in Cyklos Materials and Sepion Technologies. The other authors declare that they have no other competing interests.

Ethics

The author(s) have declared ethics committee/IRB approval is not relevant to this content

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