Gurarslan Alper, Joijode Abhay, Shen Jialong, Narayanan Ganesh, Antony Gerry J, Li Shanshan, Caydamli Yavuz, Tonelli Alan E
Fiber & Polymer Science Program, College of Textiles, North Carolina State University, Raleigh, NC 27606-8301, USA.
Polymers (Basel). 2017 Dec 4;9(12):673. doi: 10.3390/polym9120673.
During the past several years, we have been utilizing cyclodextrins (CDs) to nanostructure polymers into bulk samples whose chain organizations, properties, and behaviors are quite distinct from neat bulk samples obtained from their solutions and melts. We first form non-covalently bonded inclusion complexes (ICs) between CD hosts and guest polymers, where the guest chains are highly extended and separately occupy the narrow channels (~0.5⁻1.0 nm in diameter) formed by the columnar arrangement of CDs in the IC crystals. Careful removal of the host crystalline CD lattice from the polymer-CD-IC crystals leads to coalescence of the guest polymer chains into bulk samples, which we have repeatedly observed to behave distinctly from those produced from their solutions or melts. While amorphous polymers coalesced from their CD-ICs evidence significantly higher glass-transition temperatures, s, polymers that crystallize generally show higher melting and crystallization temperatures (s, s), and some-times different crystalline polymorphs, when they are coalesced from their CD-ICs. Formation of CD-ICs containing two or more guest homopolymers or with block copolymers can result in coalesced samples which exhibit intimate mixing between their common homopolymer chains or between the blocks of the copolymer. On a more practically relevant level, the distinct organizations and behaviors observed for polymer samples coalesced from their CD-ICs are found to be stable to extended annealing at temperatures above their s and s. We believe this is a consequence of the structural organization of the crystalline polymer-CD-ICs, where the guest polymer chains included in host-IC crystals are separated and confined to occupy the narrow channels formed by the host CDs during IC crystallization. Substantial degrees of the extended and un-entangled natures of the IC-included chains are apparently retained upon coalescence, and are resistant to high temperature annealing. Following the careful removal of the host CD lattice from each randomly oriented IC crystal, the guest polymer chains now occupying a much-reduced volume may be somewhat "nematically" oriented, resulting in a collection of randomly oriented "nematic" regions of largely extended and un-entangled coalesced guest chains. The suggested randomly oriented nematic domain organization of guest polymers might explain why even at high temperatures their transformation to randomly-coiling, interpenetrated, and entangled melts might be difficult. In addition, the behaviors and uses of polymers coalesced from their CD-ICs are briefly described and summarized here, and we attempted to draw conclusions from and relationships between their behaviors and the unique chain organizations and conformations achieved upon coalescence.
在过去几年中,我们一直在利用环糊精(CDs)将聚合物纳米结构化,形成块状样品,其链组织、性质和行为与从其溶液和熔体中获得的纯块状样品有很大不同。我们首先在CD主体与客体聚合物之间形成非共价键合的包合物(ICs),其中客体链高度伸展,并分别占据由IC晶体中CD柱状排列形成的狭窄通道(直径约0.5⁻1.0纳米)。从聚合物-CD-IC晶体中小心去除主体晶体CD晶格会导致客体聚合物链聚结成块状样品,我们反复观察到这些块状样品的行为与从其溶液或熔体中产生的样品明显不同。虽然从其CD-ICs聚结的无定形聚合物显示出明显更高的玻璃化转变温度,但结晶的聚合物从其CD-ICs聚结时通常表现出更高的熔点和结晶温度,有时还会出现不同的结晶多晶型。含有两种或更多种客体均聚物或与嵌段共聚物形成的CD-ICs会导致聚结样品,其在共同的均聚物链之间或共聚物的嵌段之间表现出紧密混合。在更具实际相关性的层面上,发现从其CD-ICs聚结的聚合物样品所观察到的独特组织和行为在高于其玻璃化转变温度和熔点的温度下进行长时间退火时是稳定的。我们认为这是结晶聚合物-CD-ICs结构组织的结果,其中主体-IC晶体中包含的客体聚合物链在IC结晶过程中被分离并限制在主体CD形成的狭窄通道中占据。IC包含链的大量伸展和未缠结性质在聚结后显然得以保留,并且耐高温退火。在从每个随机取向的IC晶体中小心去除主体CD晶格之后,现在占据大大减小体积的客体聚合物链可能会有点“向列”取向,从而导致大量伸展和未缠结的聚结合客体链的随机取向“向列”区域的集合。所提出的客体聚合物的随机取向向列域组织可能解释了为什么即使在高温下它们转变为随机卷曲、相互渗透和缠结的熔体也可能很困难。此外,这里简要描述和总结了从其CD-ICs聚结的聚合物的行为和用途,并且我们试图从它们的行为以及聚结时实现的独特链组织和构象之间得出结论和关系。
