Nanostructure design of 3D printed materials through macromolecular architecture

IF 7.6 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Chemical Science Pub Date : 2024-11-01 DOI:10.1039/d4sc05597g

Di Wu, Vaibhav Dev, Valentin A. Bobrin, Kenny Lee, Cyrille Boyer

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Abstract

Polymerization-induced microphase separation (PIMS) has been previously combined with 3D printing to develop customized nanostructured materials with a wide range of functional applications. In traditional PIMS, monofunctional, linear macromolecular chain transfer agents (macroCTAs) are used to develop macroCTA-b-P(monomer-stat-crosslinker) networks that self-assemble into unique disordered nanostructures. In this work, we designed a significantly altered network structure by utilizing linear macroCTAs with pendant CTA groups, which provides a novel network upon polymerization (i.e., branched copolymers, [macroCTA-graft-[P(monomer-stat-crosslinker)]_n]-b-P(monomer-stat-crosslinker)). Intriguingly, this method leads to the development of alternative disordered morphologies where the internal nanostructure can be precisely controlled. By systematically varying the number of pendant CTA groups, we demonstrate controlled transitions in macroCTA domain continuity, nanodomain size, and phase interface sharpness. These tunable properties translate to adjustable mechanical and swelling behaviors in the resulting 3D printed objects, ultimately enabling the fabrication of smart 4D materials (swelling-induced actuators and temperature-responsive shape-morphing objects). This research significantly expands the design toolbox for 3D printed PIMS materials, providing increased flexibility in the development of advanced materials with specific nanostructures and functionalities.

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通过大分子结构设计 3D 打印材料的纳米结构

聚合诱导微相分离（PIMS）曾与三维打印技术相结合，用于开发具有广泛功能应用的定制纳米结构材料。在传统的聚合诱导微相分离技术中，单功能线性大分子链转移剂（macroCTA）被用于开发macroCTA-b-P（单体-静态-交联剂）网络，该网络可自组装成独特的无序纳米结构。在这项工作中，我们利用带有悬垂 CTA 基团的线性大分子链转移剂设计了一种显著改变的网络结构，这种结构在聚合时提供了一种新型网络（即支化共聚物，[macroCTA-graft-[P(monomer-stat-crosslinker)]n]-b-P(monomer-stat-crosslinker)）。有趣的是，这种方法可以开发出内部纳米结构可精确控制的其他无序形态。通过系统地改变悬垂 CTA 基团的数量，我们展示了宏观 CTA 域连续性、纳米域大小和相界面锐度的可控转变。这些可调特性转化为三维打印物体的可调机械和膨胀行为，最终实现了智能四维材料（膨胀致动器和温度响应形状变形物体）的制造。这项研究极大地扩展了三维打印 PIMS 材料的设计工具箱，为开发具有特定纳米结构和功能的先进材料提供了更大的灵活性。

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来源期刊

Chemical Science CHEMISTRY, MULTIDISCIPLINARY-

CiteScore

14.40

自引率

4.80%

发文量

1352

审稿时长

2.1 months

期刊介绍： Chemical Science is a journal that encompasses various disciplines within the chemical sciences. Its scope includes publishing ground-breaking research with significant implications for its respective field, as well as appealing to a wider audience in related areas. To be considered for publication, articles must showcase innovative and original advances in their field of study and be presented in a manner that is understandable to scientists from diverse backgrounds. However, the journal generally does not publish highly specialized research.