Mastalski, Isaac2023-09-192023-09-192023-05https://hdl.handle.net/11299/257100University of Minnesota Ph.D. dissertation. May 2023. Major: Chemical Engineering. Advisor: Paul Dauenhauer. 1 computer file (PDF); xiv, 155 pages.Global plastic use has grown exponentially over the past several decades, and this has led to a concomitant increase in plastic waste. Because current plastics, and polyolefins such as polyethylene in particular, have become a necessity for modern life, it is unlikely that more sustainable, alternative plastics can displace them anytime soon, so one of the best ways to mitigate plastic waste is to develop more sustainable, alternative recycling methods. Pyrolysis, or thermal degradation under an inert atmosphere, shows great promise in this regard, since it is capable of chemically recycling plastics back to their constituent monomers or to value-added chemicals. However, knowledge of the mechanisms and reaction kinetics underlying polyethylene pyrolysis remains extremely lacking, hindering development of large-scale plastic recycling capabilities. Therefore, the primary objective of this thesis was to investigate those kinetics and shed new light on the reasons behind the vast discrepancies reported in the literature. Fundamental understanding of polyethylene pyrolysis has previously been limited due to an inability to obtain intrinsic reaction kinetics; instead, the literature presently reports only apparent kinetics, which are a combination of intrinsic kinetics and a variety of other transport and system design limitations. In this thesis, an extensive summary of these limitations in other works is presented, and a new system, known as the Pulse-Heated Analysis of Solid Reactions, or PHASR, system was developed to overcome these limitations. The PHASR system is uniquely capable of operating under “isothermal, reaction-controlled” conditions, at which intrinsic kinetics can reliably be measured. The PHASR system was validated extensively to ensure operation in this desired regime, and detailed descriptions of the reactor setup and experimental methodologies are presented. Alongside this system, a second, Visual PHASR system was developed as well, to enable visualization of polyethylene pyrolysis reaction phenomena for the first time, via integrated high-speed photographic equipment. The method of PHASR was then used to study the intrinsic kinetics of polyethylene pyrolysis. Conversion of low-density polyethylene to pyrolysis products was measured over a range of reaction temperatures (550 to 650 °C) and reaction durations (20 ms to 2.0 s), and three distinct product lumps were characterized via integrated gas chromatography and a microgram-resolution balance. Lumped intrinsic reaction kinetics were calculated using these product fractions. The results were further validated by applying a generalized Rice-Herzfeld radical reaction model to the polyethylene pyrolysis system; good agreement was found between this first principles approach and the PHASR experimental data. Additionally, extensive characterization was performed on the residues left behind in PHASR post-pyrolysis, and this helped elucidate new insights into the different reaction timescale regimes that are present during polyethylene pyrolysis.enkineticsplasticpolyethylenepyrolysisrecyclingThesis or Dissertation