Hasala N. Lokupitiya scite author profile

Porous and nanoscale architectures of inorganic materials have become crucial for a range of energy and catalysis applications, where the ability to control the morphology largely determines the transport characteristics and device performance. Despite the availability of a range of block copolymer self-assembly methods, the conditions for tuning the key architectural features such as the inorganic wall-thickness have remained elusive. Towards this end we have developed solution processing guidelines that enable isomorphic nanostructures with tunable wall-thickness. A new poly(ethylene oxide-b-hexyl acrylate) (PEOb-PHA) structure directing agent (SDA) was used to demonstrate the key solution design criteria. Specifically, the use of a polymer with a high Flory-Huggins effective interaction parameter, χ, and appropriate solution conditions leads to the kinetic entrapment of persistent micelle templates (PMT) for tunable isomorphic architectures. Solubility parameters are used to predict conditions for maintaining persistent micelle sizes despite changing equilibrium conditions. Here the use of different inorganic loadings controls the inorganic wall-thickness with constant pore size. This versatile method enabled a record 55 nm oxide wall-thickness from micelle coassembly as well as the seamless transition from mesoporous materials to macroporous materials by varying the polymer molar mass and solution conditions. The processing guidelines are generalizable and were elaborated with three inorganic systems, including Nb 2 O 5 , WO 3 , and SiO 2 that were thermally stable to 600 o C for access to crystalline materials. access to extensive pore size regimes that seamlessly span from mesopores to macropores. This concept is demonstrated with a new PEO-b-PHA SDA. The use of a polymer with sufficiently high Flory-Huggins interaction parameter is needed to inhibit micelle re-equilibration that would otherwise change the final pore size with different inorganic loadings. Both micelle fusion-fission and unimer expulsion-insertion reactions may be slowed with appropriate solution conditions that inhibit micelle changes. 68-72 The demonstrated broad range of tunable pore sizes fills the gap typically found between block copolymer approaches and colloidal approaches. The resulting materials were stable to high temperatures and enabled the formation of multiple crystalline oxide frameworks. Experimental Methods Reagents: Anhydrous, inhibitor free THF (>99.9%, Aldrich), Niobium (V) ethoxide (99.9%, Fisher) and Tungsten (VI) chloride (99.9%, Acros) were stored inside a glove box and used as received. Concentrated hydrochloric acid (37 wt% ACS grade, VWR) and Tetraethoxysilane (98%, Alfa Aesar) were used as received. Poly(ethylene glycol) methyl ether (M n 20, 000 g mol-1 , Aldrich) was dried by azeotropic distillation with toluene before use.

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Lignin Biopolymers in the Age of Controlled Polymerization

Ganewatta

2019

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Polymers made from natural biomass are gaining interest due to the rising environmental concerns and depletion of petrochemical resources. Lignin isolated from lignocellulosic biomass is the second most abundant natural polymer next to cellulose. The paper pulp process produces industrial lignin as a byproduct that is mostly used for energy and has less significant utility in materials applications. High abundance, rich chemical functionalities, CO2 neutrality, reinforcing properties, antioxidant and UV blocking abilities, as well as environmental friendliness, make lignin an interesting substrate for materials and chemical development. However, poor processability, low reactivity, and intrinsic structural heterogeneity limit lignins′ polymeric applications in high-performance advanced materials. With the advent of controlled polymerization methods such as ATRP, RAFT, and ADMET, there has been a great interest in academia and industry to make value-added polymeric materials from lignin. This review focuses on recent investigations that utilize controlled polymerization methods to generate novel lignin-based polymeric materials. Polymers developed from lignin-based monomers, various polymer grafting technologies, copolymer properties, and their applications are discussed.

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Designing Block Copolymer Architectures toward Tough Bioplastics from Natural Rosin

et al. 2017

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Resin acids (or natural rosin) are a class of abundant, renewable natural biomass. Most low molecular weight resin acid-containing polymers are very brittle due to their low chain entanglement associated with the pendant, intrinsically bulky hydrophenanthrene group. The use of block copolymer architectures can enhance chain entanglement and thus improve toughness. A–B–A type triblock and A–B–A–B–A type pentablock copolymers were synthesized by ring-opening metathesis polymerization (ROMP) with one-pot sequential monomer addition of a rosin-based monomer and norbornene. We investigated the effect of chain architecture and microphase separation on mechanical properties of both types of block copolymers. Pentablock copolymers exhibited higher strength and toughness as compared to both the triblock copolymers and the corresponding homopolymers. The greater toughness of pentablock copolymers is due to the presence of the rosin-based midblock chains that act as bridging chains between two polynorbornene domains. SAXS and AFM data were consistent with short-range phase separation of microdomains in all tri- and pentablock copolymers.

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Pseudocapacitance: Nanostructure Dependence of T‐Nb₂O₅ Intercalation Pseudocapacitance Probed Using Tunable Isomorphic Architectures (Adv. Funct. Mater. 1/2021)

Bergh

Lokupitiya

Vest

et al. 2021

Adv Funct Materials

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In article number 2007826, Morgan Stefik and co‐workers determine unambiguous nanostructure‐property relationships using a series of nanoscale T‐Nb2O5 architectures that vary by a single spatial variable at a time by using persistent micelle templates. The departure of lithiation behavior from intercalation pseudocapacitance with surface‐limited kinetics depend sensitively upon the architecture's intercalation length scale. Identifying such nanostructure–performance relationships enables tailored architecture designs that are “nano‐optimized” to specific needs.

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