Biodegradable polycarbonates from lignocellulose based 4-pentenoic acid and carbon dioxide

被引:5
|
作者
Wang, Weiliang [1 ]
Qu, Rui [1 ]
Suo, Hongyi [1 ]
Gu, Yanan [1 ]
Qin, Yusheng [1 ]
机构
[1] Yantai Univ, Coll Chem & Chem Engn, Yantai, Peoples R China
来源
FRONTIERS IN CHEMISTRY | 2023年 / 11卷
基金
中国国家自然科学基金;
关键词
biobased polymer; CO2-based polycarbonate; lignocellulose based; 4-pentenoic acid; biodegradable (co)polymers; BINARY CATALYST SYSTEMS; ALTERNATING COPOLYMERIZATION; ALUMINUM PORPHYRIN; PROPYLENE-OXIDE; LIMONENE OXIDE; EPOXIDES; CO2; BIOMASS; TRANSFORMATION; OPTIMIZATION;
D O I
10.3389/fchem.2023.1202735
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
The production of biodegradable polycarbonate by copolymerizing CO2 with epoxides has emerged as an effective method to utilize CO2 in response to growing concerns about CO2 emissions and plastic pollution. Previous studies have mainly focused on the preparation of CO2-based polycarbonates from petrochemical-derived propylene oxide (PO) or cyclohexene oxide (CHO). However, to reduce dependence on fossil fuels, the development of 100% bio-based polymers has gained attention in polymer synthesis. Herein, we reported the synthesis of glycidyl 4-pentenoate (GPA) from lignocellulose based 4-pentenoic acid (4-PA), which was further copolymerized with CO2 using a binary catalyst SalenCoCl/PPNCl to produce bio-based polycarbonates with vinyl side chains and molecular weights up to 17.1 kg/mol. Introducing a third monomer, PO, allows for the synthesis of the GPA/PO/CO2 terpolymer, and the glass transition temperature (T ( g )) of the terpolymer can be adjusted from 2? to 19? by controlling the molar feeding ratio of GPA to PO from 7:3 to 3:7. Additionally, post-modification of the vinyl side chains enables the production of functional polycarbonates, providing a novel approach to the preparation of bio-based materials with diverse side chains and functions.
引用
收藏
页数:9
相关论文
共 50 条
  • [1] Iodolactonization of 4-pentenoic acid
    Crouch, RD
    Tucker-Schwartz, A
    Barker, K
    JOURNAL OF CHEMICAL EDUCATION, 2006, 83 (06) : 921 - 922
  • [2] The thermodynamic properties of 4-pentenoic acid
    V. N. Emel’yanenko
    S. P. Verevkin
    E. N. Burakova
    G. N. Roganov
    M. K. Georgieva
    Russian Journal of Physical Chemistry A, Focus on Chemistry, 2008, 82 : 1521 - 1526
  • [3] EFFECT OF 4-PENTENOIC ACID ON AMMONIOGENESIS
    LEVIN, ML
    QUINTANILLA, AP
    ROXE, D
    SAID, R
    SCHOTT, J
    GREENBERG, G
    KIDNEY INTERNATIONAL, 1978, 14 (06) : 742 - 742
  • [4] The thermodynamic properties of 4-pentenoic acid
    Emel'yanenko, V. N.
    Verevkin, S. P.
    Burakova, E. N.
    Roganov, G. N.
    Georgieva, M. K.
    RUSSIAN JOURNAL OF PHYSICAL CHEMISTRY A, 2008, 82 (09) : 1521 - 1526
  • [5] ACTION OF 4-PENTENOIC ACID ON GLUCONEOGENESIS
    BRENDEL, K
    CORREDOR, C
    BRESSLER, R
    PHARMACOLOGIST, 1968, 10 (02): : 213 - &
  • [6] INHIBITION OF GLUCONEOGENESIS BY 4-PENTENOIC ACID
    WILLIAMS.JR
    PETERSON, M
    ROSTAND, S
    SCHOLZ, R
    FEDERATION PROCEEDINGS, 1969, 28 (02) : 411 - &
  • [7] EFFECT OF 4-PENTENOIC ACID ON FATTY ACID OXIDATION
    BRENDEL, K
    CORREDOR, CF
    BRESSLER, R
    BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS, 1969, 34 (03) : 340 - &
  • [8] ACTION OF 4-PENTENOIC ACID IN ISOLATED MITOCHONDRIA
    FUKAMI, MH
    WILLIAMSON, JR
    DIABETES, 1969, S 18 : 330 - +
  • [9] EFFECTS OF 4-PENTENOIC ACID ON HEPATIC GLUCONEOGENESIS
    PETERSON, MJ
    ROSTAND, SG
    SCHOLZ, R
    WILLIAMSON, JR
    DIABETES, 1969, S 18 : 369 - +
  • [10] MECHANISM OF ACTION OF 4-PENTENOIC ACID IN MITOCHONDRIA
    FUKAMI, MH
    FEDERATION PROCEEDINGS, 1969, 28 (02) : 852 - &
12345