Emergence of Hexagonally Close-Packed Spheres in Linear Block Copolymer Melts

Zhang, Cheng; Vigil, Daniel L.; Sun, Dan; Bates, Morgan W.; Loman, Tessa; Murphy, Elizabeth A.; Barbon, Stephanie M.; Song, Jung-Ah; Yu, Beihang; Fredrickson, Glenn H.; Whittaker, Andrew K.; Hawker, Craig J.; Bates, Christopher M.

doi:10.1021/jacs.1c03647

Cited by 43 publications

(44 citation statements)

References 44 publications

(87 reference statements)

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“…

d \propto N^{2 / 3} χ^{1 / 6}

), where N is the overall degree of polymerization of the BCP and χ is the Flory–Huggins interaction parameter between the blocks, then d can be readily tailored by controlling N and χ . For instance, a hexagonally close‐packed sphere phase can be achieved from linear block copolymer with high χ across a wide range of compositions, which is supported by the experimental and simulation results 6 . Beyond χ , complex inaccessible morphologies from linear BCPs can be obtained by manipulating the combination parameters (e.g.…”

Section: Figuresupporting

confidence: 56%

Self‐assembly of block copolymers for biological applications

Lin

2021

Polymer International

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Self‐assembly of block copolymers (BCPs) has garnered much attention over the past several decades owing to an array of intriguing properties. In this perspective, recent advances in self‐assembly and applications of BCPs with different architectures are presented. First, the self‐assembly mechanism of BCPs and the general criteria to evaluate the assembled morphologies are introduced. Subsequently, the self‐assembly of linear, star‐like and bottlebrush‐like BCPs is discussed. In particular, polymerization‐induced self‐assembly for large‐scale preparation is highlighted. Afterwards, a rich diversity of applications of self‐assembled BCPs in drug delivery, bioimaging, molecular recognition and photothermal therapy are outlined. Finally, an outlook on larger‐scale production and implementation of self‐assembled BCPs for biological applications is noted. © 2021 Society of Industrial Chemistry.

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“…

d \propto N^{2 / 3} χ^{1 / 6}

Section: Figuresupporting

confidence: 56%

Self‐assembly of block copolymers for biological applications

Lin

2021

Polymer International

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“…The selection of the ordered state can be posed as identifying the least expensive distortion of the otherwise spherical particle to fill space . For decades, there was a general consensus that the optimal particle packing for diblock copolymers is the body-centered cubic (bcc) lattice in Figure , , with self-consistent field theory (SCFT) predicting a very narrow region of close-packed spheres (face-centered cubic, fcc, or hexagonally close-packed, hcp) near the order–disorder transition. , Theory predicts that the close-packed structure predicted in the mean field limit is destroyed by fluctuations at finite molecular weights, although close packing has been observed experimentally. − The consensus surrounding the formation of a bcc lattice, achieved in the 1980s, , was upended by the theoretical prediction of a Frank–Kasper A15 phase in a multiply branched block polymer by Grason and co-workers in 2003 and the subsequent discovery of a Frank–Kasper σ phase in both a diblock copolymer and a tetrablock terpolymer by Bates and co-workers in 2010 …”

Section: Introductionmentioning

confidence: 99%

Frank–Kasper Phases in Block Polymers

Dorfman

2021

Macromolecules

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The discovery of the Frank−Kasper σ phase in diblock copolymer and tetrablock terpolymer melts catalyzed a renewed interest over the past decade in understanding particle-forming phases in block polymer systems. This Perspective provides a concise overview of the Frank−Kasper phases seen to date in block polymers (A15, σ, and the C14 and C15 Laves phases) and mechanisms known to produce them: conformational asymmetry in neat diblock copolymer melts, interfacial segregation effects in diblock copolymer blends, particle swelling in diblock copolymer/homopolymer blends, and matrix segregation effects in neat tetrablock terpolymer melts. While a qualitative understanding of the emergence of Frank−Kasper phases in block polymer systems has been achieved, a number of outstanding questions remain, in particular those arising from the low degree of polymerization used in experiments, nonequilibrium effects during thermal processing, and the large design space available in blends and multiblock systems. This Perspective discusses potential avenues for future research related to these areas as well as overarching issues underlying the connections between Frank−Kasper phase formation in block polymers to other soft matter and metals.

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“…A synthetic polymer is virtually a mixture of chains with the same repeating unit but varied chain lengths (known as dispersity , Đ ). It has been recently recognized that the formation and transition of ordered structures are surprisingly susceptible to molecular weight distribution, and even batch-to-batch variation would be sufficient to result in disparate assemblies. ,− Quantitatively unraveling the role of molecular geometry/architecture demands independent and precise control of molecular parameters to decouple undesired interferences (such as compositional variation). Recent progress in polymer syntheses (e.g., solid-phase synthesis and iterative growth) has allowed the preparation of discrete oligomers/polymers with uniform chain lengths (i.e., Đ = 1). − The precision feature offers unparalleled control over chain arrangements, revealing intriguing phase behaviors that have long been compromised by inherent molecular weight distribution and bridging the existing gaps between experiments and theories. ,,− In this study, we (i) elaborately designed a library of monomers based on glutamic acid derivatives with similar constitution but varied alkyl side chains and (ii) modularly prepared discrete linear polymers with programmable molecular geometries (Scheme ).…”

Section: Introductionmentioning

confidence: 99%

Precisely Encoding Geometric Features into Discrete Linear Polymer Chains for Robust Structural Engineering

Zhou

et al. 2021

J. Am. Chem. Soc.

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Molecular shape is an essential parameter that regulates the self-organization and recognition process, which has not yet been well appreciated and exploited in block polymers due to the lack of precise and efficient modulation methods. This work (i) develops a robust approach to break the intrinsic symmetry of linear polymers by introducing geometric features into otherwise homogeneous chains and (ii) quantitatively highlights the critical contribution of molecular geometry/architecture to the self-assembly behaviors. Iteratively connecting homologous monomers of different side chains according to pre-designed sequences generates discrete polymers with exact chemical structure, uniform chain length, and programmable side-chain gradient along the backbone, which transcribes into diverse shapes. The precise chemistry eliminates all the defects and heterogeneities, providing a delicate platform for fundamental inquiries into the role of molecular geometry. A rich collection of unconventional complex phases, including Frank–Kasper A15 and σ phases, as well as a dodecagonal quasicrystal phase, were captured in these rigorous single-component systems. The self-assembly behaviors are strikingly sensitive to subtle variations of geometry, such that simply migrating a few methylene units among the side chains would generate substantial differences in lattice size or phase stability, or even trigger a phase transition toward distinct structures. The phenomena can be rationalized with a geometric argument that nonuniform side chain distribution leads to conformational mismatch between two immiscible blocks, resulting in varied interfacial curvatures and distinct lattice symmetries. The profound contribution demonstrates that molecular geometry is an effective and robust parameter for structural engineering.

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Emergence of Hexagonally Close-Packed Spheres in Linear Block Copolymer Melts

Cited by 43 publications

References 44 publications

Self‐assembly of block copolymers for biological applications

Self‐assembly of block copolymers for biological applications

Frank–Kasper Phases in Block Polymers

Precisely Encoding Geometric Features into Discrete Linear Polymer Chains for Robust Structural Engineering

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