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  1. Mechanism of O 2 /NO-Promoted Oxidative C–C Bond Cleavage in Linear Alkanes

    elective oxidation of alkanes to oxygenated products remains a fundamental challenge, particularly if the goal is to promote C-C bond cleavage while minimizing formation of CO(2). Oxidation conditions that use O(2) and nitrogen oxides (NO(x)) have been shown to be very effective in promoting radical-mediated functionalization and oxidative carbon-carbon cleavage in saturated hydrocarbon polymers, such as polyethylene. Here, we investigate the mechanism of O(2)/NO-mediated oxidation of n-decane as a prototypical linear alkane substrate. These reactions enable identification and quantification of reactive intermediates, including nitrites, nitrates, alcohols, and ketones. Under the reaction conditions, these species convert into common ketone intermediates thatmore » evolve into alpha-diketones and other alpha-functionalized ketones, which undergo further conversion into carboxylic acids. Infrared (IR) spectroscopy indicates that HDPE oxidation proceeds through similar key intermediates. Together, these findings establish a mechanistic framework for NO(x)-mediated alkane oxidation and provide a foundation for the development of broadly applicable oxidative transformations.« less
  2. Conversion of Polystyrene to Terephthalic Acid via Sequential Acetylation and Mn/Br-Catalyzed Autoxidation

    Most methods for the oxidative deconstruction of polystyrene produce benzoic acid, which has a low market size relative to the production of waste polystyrene. Here, the present study demonstrates a method for conversion of polystyrene into terephthalic acid, a high-volume chemical, by introducing a carbon-containing fragment into the para position of the phenyl groups in polystyrene, followed by Mn/Br-catalyzed autoxidation. Acetylated polystyrene is shown to be the most effective substrate for oxidation, affording an 81% yield of terephthalic acid. Mechanistic studies highlight the effectiveness of bromide as a cocatalyst and offer insight into the underlying reasons the acetyl group undergoesmore » efficient oxidation.« less
  3. Can the Hock Process Be Used to Produce Phenol from Polystyrene?

    Polystyrene (PS) is a widely used thermoplastic polymer, but its very low recycling rate has motivated consideration of chemical conversion strategies to convert waste PS into value-added products. Oxidation methods have been widely studied, but they typically generate benzoic acid, a product with a relatively low market demand. Phenol is a higher volume chemical that would be an appealing target, but no methods currently exist for the conversion of PS into phenol. The repeat unit in PS closely resembles cumene, the primary feedstock used to produce phenol through the Hock process. Here, we investigate prospects for adapting the Hock processmore » to PS, generating hydroperoxides through the autoxidation of benzylic C–H bonds followed by the acid-promoted rearrangement of the hydroperoxides to afford phenol and a partially oxygenated polymer. Experimental and computational studies of dimeric and trimeric PS model compounds show that neighboring phenyl rings impose conformational constraints that raise the barrier to hydrogen-atom transfer from the tertiary benzylic C–H bond. These effects are also evident with PS and contribute to lower yields of phenol when PS is subjected to Hock process conditions. Furthermore, these results provide valuable insights that have important implications for other efforts that seek to adapt small-molecule reactivity to polymeric feedstocks.« less
  4. Networks and interfaces as catalysts for polymer materials innovation

    Autonomous experimental systems offer a compelling glimpse into a future where closed-loop, iterative cycles—performed by machines and guided by artificial intelligence (AI) and machine learning (ML)—play a foundational role in materials research and development. This perspective draws attention to the roles of networks and interfaces—of and between humans and machines—for the purpose of generating knowledge and accelerating innovation. Polymers, a class of materials with massive global impact, present a unique opportunity for the application of informatics and automation to pressing societal challenges. To develop these networks and interfaces in polymer science, the Community Resource for Innovation in Polymer Technology (CRIPT)—amore » polymer data ecosystem based on novel polymer data model, representation, search, and visualization technologies—is introduced. The ongoing co-design efforts engage stakeholders in industry, academia, and government to uncover rapidly actionable, high-impact opportunities to build networks, bridge interfaces, and catalyze innovation in polymer technology.« less
  5. Tunable structural color of bottlebrush block copolymers through direct-write 3D printing from solution

    Additive manufacturing of functional materials is limited by control of microstructure and assembly at the nanoscale. In this work, we integrate nonequilibrium self-assembly with direct-write three-dimensional (3D) printing to prepare bottlebrush block copolymer (BBCP) photonic crystals (PCs) with tunable structure color. After varying deposition conditions during printing of a single ink solution, peak reflected wavelength for BBCP PCs span a range of 403 to 626 nm (blue to red), corresponding to an estimated change in d-spacing of >70 nm (Bragg- Snell equation). Physical characterization confirms that these vivid optical effects are underpinned by tuning of lamellar domain spacing, which wemore » attribute to modulation of polymer conformation. Using in situ optical microscopy and solvent-vapor annealing, we identify kinetic trapping of metastable microstructures during printing as the mechanism for domain size control. More generally, we present a robust processing scheme with potential for on-the-fly property tuning of a variety of functional materials.« less

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