Institute of Polymer Materials, School of Materials Science and Engineering, Jiangsu University, Zhenjiang 212013, China
nieyijing@ujs.edu.cn
收稿:2026-02-22,
录用:2026-04-04,
网络首发:2026-07-09,
纸质出版:2026-05
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Dai, Z. X.; Nie, Y. J. Enhanced segment mobility promotes stereocomplex crystallization in polymer blends via elevated segmental miscibility. Chinese J. Polym. Sci. https://doi.org/10.1007/s10118-026-3701-y
Zi-Xiang Dai, Yi-Jing Nie. Enhanced Segment Mobility Promotes Stereocomplex Crystallization in Polymer Blends
Dai, Z. X.; Nie, Y. J. Enhanced segment mobility promotes stereocomplex crystallization in polymer blends via elevated segmental miscibility. Chinese J. Polym. Sci. https://doi.org/10.1007/s10118-026-3701-y DOI:
Zi-Xiang Dai, Yi-Jing Nie. Enhanced Segment Mobility Promotes Stereocomplex Crystallization in Polymer Blends
A fundamental prerequisite to effectively regulate the content of stereocomplex crystals (SCs) in poly(lactic acid) (PLA) is to elucidate the underlying mechanisms governing their formation. In this study
we established polymer blend systems with different chain segment mobility but similar initial segment miscibility based on dynamic Monte Carlo (MC) simulations. The SC fraction was found to be closely related to segment mobility in polymer blend systems during the crystallization process. The simulation results further indicated that polymer blend systems with stronger segment mobility exhibited higher segment miscibility during crystallization
resulting in the formation of more SCs. Therefore
it can be concluded that by increasing the segment mobility
segment miscibility can be enhanced
thereby improving the stereocomplexation ability.
Kumar, R.; Verma, A.; Shome, A.; Sinha, R.; Sinha, S.; Jha, P. K.; Kumar, R.; Kumar, P.; Shubham; Das, S.; Sharma, P.; Prasad, P. V. V. Impacts of plastic pollution on ecosystem services, su stainable development goals, and need to focus on circular economy and policy interventions. Sustainability 2021 , 13 , 9963..
Barra, R.; González, P. Sustainable chemistry challenges from a developing country perspective: education, plastic pollution, and beyond. Curr. Opin. Green Sustainable Chem. 2018 , 9 , 40−44..
Nkwachukwu, O. I.; Chima, C. H.; Ikenna, A. O.; Albert, L. Focus on potential environmental issues on plastic world towards a sustainable plastic recycling in developing countries. Int. J. Ind. Chem. 2013 , 4 , 34..
Walker, T. R.; Fequet, L. Current trends of unsustainable plastic production and micro(nano) plastic pollution. Trac-Trend. Anal. Chem. 2023 , 160 , 116984..
Lakhiar, I. A.; Yan, H. F.; Zhang, J. Y.; Wang, G. Q.; Deng, S. S.; Bao, R. X.; Zhang, C.; Syed, T. N.; Wang, B. Y.; Zhou, R.; Wang, X. X. Plastic pollution in agriculture as a threat to food security, the ecosystem, and the environment: an overview. Agronomy-Basel 2024 , 14 , 548..
Li, K.; Du, L.; Qin, C.; Bolan, N.; Wang, H.; Wang, H. J. C. R. Microplastic pollution as an environmental risk exacerbating the greenhouse effect and climate change: a review. Carbon Res. 2024 , 3 , 9..
Parvez, M. S.; Ullah, H.; Faruk, O.; Simon, E.; Czédli, H. Role of microplastics in global warming and climate change: a review. Water Air Soil Poll. 2024 , 235 , 201..
Moshood, T. D.; Nawanir, G.; Mahmud, F.; Mohamad, F.; Ahmad, M. H.; Ghani, A. A. Expanding policy for biodegradable plastic products and market dynamics of bio-based plastics: challenges and opportunities. Sustainability 2021 , 13 , 6170..
Okolie, O.; Kumar, A.; Edwards, C.; Lawton, L. A.; Oke, A.; McDonald, S.; Thakur, V. K.; Njuguna, J. Bio-based sustainable polymers and materials: from processing to biodegradation. J. Compos. Sci. 2023 , 7 , 213..
Ding, F. Y.; Long, S. M.; Huang, X. W.; Shi, J. Y.; Povey, M.; Zou, X. B. Emerging Pickering emulsion films for bio-based food packaging applications. Food Packag. Shelf Life 2024 , 42 , 101242..
Atta, O. M.; Manan, S.; Shahzad, A.; Ul-Islam, M.; Ullah, M. W.; Yang, G. Biobased materials for active food packaging: a review. Food Hydrocoll. 2022 , 125 , 107419..
Jayasekara, T.; Surendra, Y. W.; Rathnayake, M. Polylactic acid pellets production from corn and sugarcane molasses: process simulation for scaled-up processing and comparative life cycle analysis. J. Polym. Environ. 2022 , 30 , 4590−4604..
Rueda-Duran, C. A.; Ortiz-Sanchez, M.; Cardona-Alzate, C. A. Detailed economic assessment of polylactic acid production by using glucose platform: sugarcane bagasse, coffee cut stems, and plantain peels as possible raw materials. Biomass Convers. and Biorefin. 2022 , 12 , 4419−4434..
Zhao, X. H.; Wang, Y.; Chen, X. W.; Yu, X. B.; Li, W.; Zhang, S. Y.; Meng, X. Z.; Zhao, Z. M.; Dong, T.; Anderson, A.; Aiyedun, A.; Li, Y. F.; Webb, E.; Wu, Z. L.; Kunc, V.; Ragauskas, A.; Ozcan, S.; Zhu, H.L. Sustainable bioplastics derived from renewable natural resources for food packaging. Matter 2023 , 6 , 97−127..
Hossam, Y.; Fahim, I. S. Towards a circular economy: fabrication and characterization of biodegradable plates from sugarcane waste. Front. Sustain. Food Syst. 2023 , 7 , 1220324..
Marzo-Gago, C.; Díaz, A. B.; Blandino, A. Sugar beet pulp as raw material for the production of bioplastics. Fermentation-Basel 2023 , 9 , 655..
Lyshtva, P.; Kuusik, A.; Voronova, V. Degradation and disintegration behavior of PHBV- and PLA-based films under composting conditions. Sustainability 2025 , 17 , 8657..
Lyshtva, P.; Voronova, V.; Kuusik, A.; Kobets, Y. Assessing the biodegradation characteristics of poly(butylene succinate) and poly(lactic acid) formulations under controlled composting conditions. Appliedchem 2025 , 5 , 17..
[Joseph, T. M.; Kallingal, A.; Suresh, A. M.; Mahapatra, D. K.; Hasanin, M. S.; Haponiuk, J.; Thomas, S. 3D printing of polylactic acid: recent advances and opportunities. Int. J. Adv. Manuf. Technol . 2023 , 125 , 1015−1035..
Ekonomou, S. I.; Soe, S.; Stratakos, A. C. An explorative study on the antimicrobial effects and mechanical properties of 3D printed PLA and TPU surfaces loaded with Ag and Cu against no socomial and foodborne pathogens. J. Mech. Behav. Biomed. Mater. 2023 , 137 , 105536..
Swetha, T. A.; Bora, A.; Mohanrasu, K.; Balaji, P.; Raja, R.; Ponnuchamy, K.; Muthusamy, G.; Arun, A. A comprehensive review on polylactic acid (PLA)-Synthesis, processing and application in food packaging. Int. J. Biol. Macromol. 2023 , 234 , 123715..
Moldovan, A.; Sarosi, I.; Cuc, S.; Prodan, D.; Taut, A. C.; Petean, I.; Bombos, D.; Doukeh, R.; Nemes, O.; Man, S. C. Development and characterization of PLA food packaging composite. J. Therm. Anal. Calorim. 2025 , 150 , 2469−2481..
Stoisavljević, Z.; Galović, S.; Đorđević, K. L. J. T. Medical application of polylactide (PLA). Tehnika 2024 , 79 , 14−19..
Zhao, X. P.; Liu, J. C.; Li, J. C.; Liang, X. Y.; Zhou, W. Y.; Peng, S. X. Strategies and techniques for improving heat resistance and mechanical performances of poly(lactic acid) (PLA) biodegradable materials. Int. J. Biol. Macromol. 2022 , 218 , 115−134..
Sun, Y. F.; Zheng, Z. P.; Wang, Y. P. ; Yang, B.; Wang, J. W.; Mu, W. L. PLA composites reinforced with rice residues or glass fiber-a review of mechanical properties, thermal properties, and biodegradation properties. J. Polym. Res. 2022 , 29 , 422..
Andrzejewski, J.; Das, S.; Lipik, V.; Mohanty, A. K.; Misra, M.; You, X. Y.; Tan, L. P.; Chang, B. P. The Development of poly(lactic acid) (PLA)-based blends and modification strategies: methods of improving key properties towards technical applications-review. Materials 2024 , 17 , 4556..
Zhu, Y.; Zhang, X. Y.; Jia, S. K.; Yan, Z. Y.; Liang, W. J.; Zhang, Y. Y.; Coates, P.; Liu, W. Recent reviews for isothermal crystallization kinetics and its regulation strategies of PLA. J. Polym. Res. 2024 , 31 , 253..
Ikada, Y.; Jamshidi, K.; Tsuji, H.; Hyon, S. H. J. M. Stereocomplex formation between enantiomeric poly (lactides). Macromolecules 1987 , 20 , 904−906..
Wei, D. Y.; Chen, N.; Yin, Z. W.; Li, Y. B.; Zheng, G. F.; Bian, J. J.; Pan, H. W.; Wang, G. Q.; He, L. T.; Zhao, Y.; Zhang, H. L. Crystallization properties, heat resistance, and hydrolytic resistance of poly(L-lactide)/poly(D-lactide) blend enhanced by in situ formation of stereocomplex polylactide. Chinese J. Polym. Sci. 2025 , 43 , 1549−1564..
Li, Z. L.; Zhang, M.; Fan, X.; Ye, X. X.; Zeng, Y.; Zhou, H. J.; Guo, W. J.; Ma, Y.; Shao, J.; Yan, C. Hydrogen bonding assists stereocomplexation in poly(L-lactic acid)/poly(D-lactic acid) racemic blends. J. Polym. Sci., Part B: Polym. Phys. 2019 , 57 , 83−88..
[Huang, Y. Y.; Geng, D. X.; Ye, X. X.; Nie, Y. J.; Li, Z. L. Cooling rate guiding contradictory effect of thermal treated temperature on the crystallization of PLA racemic blends upon cooling. Mater. Lett . 2023 , 335 ..
Zhang, M.; Fan, X.; Guo, W. J.; Zhou, H. J.; Li, Z. L.; Ma, Y.; Yan, C.; Dufresne, A. Insights into stereocomplexation of poly(lactic acid) materials: evolution of interaction between enantiomeric chains and its role in conformational transformation in racemic blends. ACS Appl. Polym. Mater. 2022 , 4 , 5891−5900..
Bao, R. Y.; Yang, W.; Wei, X. F.; Xie, B. H.; Yang, M. B. Enhanced formation of stereocomplex crystallites of high molecular weight poly(L-lactide)/poly(D-lactide) blends from melt by using poly(ethylene glycol). ACS Sustainable Chem. Eng. 2014 , 2 , 2301−2309..
Guan, X. C.; Wang, J. P.; Hu, W. B. Monte Carlo simulation of strain-enhanced stereocomplex polymer crystallization. J. Phys. Chem. B 2018 , 122 , 10928−10933..
He, Y. C.; Liu, D.; Wang, J. P.; Pan, P. J.; Hu, W. B. Tammann analysis of the molecular weight selection of polymorphic crystal nucleation in symmetric racemic poly(lactic acid) blends. Macromolecules 2022 , 55 , 3661−3670..
Nie, Y. J.; Liu, Y.; Liu, R. J.; Zhou, Z. P.; Hao, T. F. Dynamic Monte Carlo simulations of competition in crystallization of mixed polymers grafted on a substrate. J. Polym. Sci. Part B-Polym. Phys. 2019 , 57 , 89−97..
[Pan, P. J.; Bao, J. N.; Han, L. L.; Xie, Q.; Shan, G. R.; Bao, Y. Z. Stereocomplexation of high-molecular-weight enantiomeric poly(lactic acid)s enhanced by miscible polymer blending with hydrogen bond interactions. Polymer 2016 , 98 , 80−87..
Qiu, X. Y.; Liu, R. J.; Nie, Y. J.; Liu, Y.; Liang, Z. P.; Yang, J.; Zhou, Z. P.; Hao, T. F. Monte Carlo simulations of stereocomplex formation in multiblo ck copolymers. Phys. Chem. Chem. Phys. 2019 , 21 , 13296−13303..
Xie, Q.; Guo, G.; Lu, W. W.; Sun, C. X.; Zhou, J.; Zheng, Y.; Shan, G. R.; Bao, Y. Z.; Pan, P. J. Polymorphic homocrystallization and phase behavior of high-molecular-weight Poly(L-lactic acid)/poly(D-lactic acid) racemic mixture with intentionally enhanced stereocomplexation ability via miscible blending. Polymer 2020 , 201 , 122597..
Xu, J. Z.; Li, Y.; Li, Y. K.; Chen, Y. W.; Wang, R.; Liu, G.; Liu, S. M.; Ni, H. W.; Li, Z. M. Shear-induced stereocomplex cylindrites in polylactic acid racemic blends: morphology control and interfacial performance. Polymer 2018 , 140 , 179−187..
Xu, Y.; Wu, H. T.; Yang, J.; Liu, R. J.; Zhou, Z. P.; Hao, T. F.; Nie, Y. J. Molecular simulations of microscopic mechanism of the effects of chain length on stereocomplex formation in polymer blends. Comput. Mater. Sci. 2020 , 172 , 109297..
Bai, H. W.; Deng, S. H.; Bai, D. Y.; Zhang, Q.; Fu, Q. Recent advances in processing of stereocomplex-type polylactide. Macromol. Rapid Commun. 2017 , 38 , 1700454..
Tsuji, H.; Sobue, T. Stereocomplex crystallization and homo-crystallization of enantiomeric substituted poly(lactic acid)s, poly(2-hydroxy-3-methylbutanoic acid)s. Polymer 2015 , 69 , 186−192..
Wu, H. T.; Wang, X. Y.; Zhu, Q.; Yan, X. J.; Xue, Q. Y.; Zhou, Z. P.; Hao, T. F.; Li, Z. L.; Nie, Y. J. Stereocomplex crystallization in cyclic polymer blends studied using dynamic Monte Carlo simulations. CrystEngComm 2023 , 25 , 1347−1357..
Wen, J. L.; Ming, Y. Q.; Zhang, A. F.; Li, J. L.; Du, X. Y.; Shuai, L.; Nie, Y. J. Interplay between hydrogen bond network and entangled network in polymers during stretching based on molecular simulations. Chinese J. Polym. Sci. 2024 , 42 , 2069−2080..
Zhou, Y. H.; Yang, J.; Zhou, Z. P.; Hao, T. F.; Nie, Y. J. Molecular dynamics simulations of stretch-induced crystal changes in crystallized polyethylene/carbon nanotubes nanocomposites. Chinese J. Polym. Sci. 2023 , 41 , 1425−1438..
Zhu, Q.; Wen, J. L.; Ma, M. Y.; Nie, Y. J. Local segmental miscibility dominating stereocomplex crystallization in polymer blends. CrystEngComm 2023 , 25 , 3885−3895..
Zhang, R.; Zha, L. Y.; Hu, W. B. Intramolecular crystal nucleation favored by polymer crystallization: Monte Carlo simulation evidence. J. Phys. Chem. B 2016 , 120 , 6754−6760..
[Hu, W. B.; Frenkel, D., Polymer crystallization driven by anisotropic interactions. In Interphases and Mesophases in Polymer Crystallization III , Allegra, G., Ed. 2005 ; Vol. 191, pp. 1−35..
Nie, Y. J.; Zhao, Y. F.; Matsuba, G.; Hu, W. B. Shish-kebab crystallites initiated by shear fracture in bulk polymers: 2. Crystallization on shearing. Polymer 2023 , 274 , 125909..
Hu, W. B.; Karssenberg, F. G.; Mathot, V. B. F. How the restriction of sliding diffusion of comonomers affects crystallization and melting of homogeneous copolymers. Polymer 2006 , 47 , 5582−5587..
Ma, J. J.; Chen, Y. P.; Chen, J. Y.; Ming, Y. Q.; Nie, Y. J. Molecular simulations of stereocomplex crystallization in grafted diblock copolymers. Cryst. Res. Technol. 2025 , 60 , 2400187..
Gu, Z. Z.; Xu, Y.; Lu, Q. Q.; Han, C. J.; Liu, R. J.; Zhou, Z. P.; Hao, T. F.; Nie, Y. J. Stereocomplex formation in mixed polymers filled with two-dimensional nanofillers. Phys. Chem. Chem. Phys. 2019 , 21 , 6443−6452..
Zhu, Q.; Zhou, Z. P.; Hao, T. F.; Nie, Y. J. Significantly improved stereocomplexation ability in cyclic block copolymers. Chinese J. Polym. Sci. 2023 , 41 , 432−441..
Xu, Y.; Yang, J.; Liu, Z. F.; Zhou, Z. P.; Liang, Z. P.; Hao, T. F.; Nie, Y. J. Stereocomplex crystallization in asymmetric diblock copolymers studied by dynamic Monte Carlo simulations. Chinese J. Polym. Sci. 2021 , 39 , 632−639..
Tashiro, K.; Kouno, N.; Wang, H.; Tsuji, H. Crystal structure of poly(lactic acid) stereocomplex: Random packing model of PDLA and PLLA chains as studied by X-ray diffraction analysis. Macromolecules 2017 , 50 , 8048−8065..
Chen,Y. J.; Lan, Q. F. Experimental evidence for immiscibility of enantiomeric polymers: Phase separation of high-molecular-weight poly(L-lactide)/poly(o-lactide) blends and its impact on hindering stereocomp lex crystallization. Int. J. Biol. Macromol. 2024 , 260 , 129459..
Nie, Y. J.; Ye, X. B.; Zhou, Z. P.; Yang, W. M.; Tao, L. Intrinsic correlations between dynamic heterogeneity and conformational transition in polymers during glass transition. J. Chem. Phys. 2014 , 141 , 074901..
Shen, X.; Wang, J. P.; Wang, X. D.; Liao, X. L.; Wan, L.; Li, Z. L.; Yan, C.; Dufresne, A. Insight into the acceleration of PLA stereocomplexation within NH 2 -MIL-88: influences of free volume. Polymer 2025 , 338 , 129079..
Bai, D. Y.; Liu, H. L.; Bai, H. W.; Zhang, Q.; Fu, Q. Low-Temperature sintering of Stereocomplex-type polylactide nascent powder: effect of crystallinity. Macromolecules 2017 , 50 , 7611−7619..
Dai, Z. X.; Gao, Z. Y.; Ye, X. K.; Wen, J. L.; Ming, Y. Q.; Nie, Y. J. Segment miscibility variations dominating stereocomplex crystallization in polymer blends with different initial chain conformations. Chinese J. Polym. Sci. 2025 , 43 , 1690−1698..
[Cui, J. M.; Zhang, Q. L.; Liu, F.; Yang, S. G.; Ungar, G. Poisoning by purity: what stops stereocomplex crystallization in polylactide racemate. Macromolecules 2023 , 56 , 989−998..
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