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Journal of Polymer Research

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01-09-2015 | Original Paper

Preparation of biodegradable poly(butylene succinate)/halloysite nanotube nanocomposite foams using supercritical CO₂ as blowing agent

Authors: Wei Wu, Xianwu Cao, Hong Lin, Guangjian He, Mengmeng Wang

Published in: Journal of Polymer Research | Issue 9/2015

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Abstract

Biodegradable poly(butylene succinate) (PBS) was melt compounded with halloysite nanotube (HNT) to prepare PBS/HNT nanocomposites, and both pure PBS and PBS/HNT nanocomposites were foamed successfully using supercritical carbon dioxide as a physical blowing agent. The cell morphologiesshowed that the cell size decreased, and both cell density and volume expansion ratio increased with the addition of HNT. Within the HNT content used in this work (1, 3, 5, and 7 wt.%), the content of 5 wt.% was found to be the one that lead to the smallest cell size and highest cell density and volume expansion ratio. In addition to the HNT content, both saturation temperature and saturation pressure were found to significantly influence the cell morphology. Higher saturation pressure led to smaller cell size and higher volume expansion ratio. Interestingly, a close-celled to interconnect open-celled morphology transition occurred for PBS/HNT nanocomposites at a saturation temperature of 120 °C. The formation of interconnect open-celled morphology was mainly attributed to the stress induced by the HNT in the cell solidification process. With the increase of HNT content, saturation temperature and saturation pressure, the enthalpy of fusion of the foamed samples increased.

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Gross RA, Kalra B (2002) Science 297:803–807CrossRef

Cooper AI (2003) Adv Mater 15:1049–1059CrossRef

Lee LJ, Zeng CC, Cao X, Han XM, Shen J, Xu GJ (2005) Compos Sci Technol 65:2344–2363CrossRef

Wang J, Zhu WL, Zhang HT, Park CB (2012) Chem Eng Sci 75:390–399CrossRef

Salerno A, Zeppetelli S, Di Maio E, Iannace S, Netti PA (2011) Macromol Rapid Commun 32:1150–1156CrossRef

Salerno A, Di Maio E, Iannace S, Netti PA (2011) J Supercrit Fluids 58:158–167CrossRef

Liao X, Nawaby AV (2012) J Polym Res 19:9827–9835CrossRef

Bao DF, Liao X, He T, Yang Q, Li GX (2013) J Polym Res 20:290–299CrossRef

Orava E, Korventausta J, Rosenberg M, Jokinen M, Rosling A (2007) Polym Degrad Stab 92:14–23CrossRef

10.

Boccaccini AR, Blaker JJ, Maquet V, Day RM, Jerome R (2005) Mater Sci Eng C-Biomim 25:23–31CrossRef

11.

Richards E, Rizvi R, Chow A, Naguib H (2008) J Polym Environ 16:258–266CrossRef

12.

Fujimaki T (1998) Polym Degrad Stab 59:209–214CrossRef

13.

Ihn KJ, Yoo ES, Im SS (1995) Macromolecules 28:2460–2464CrossRef

14.

Sutthiphong S, Pavasant P, Supaphol P (2009) Polymer 50:1548–1558CrossRef

15.

Li HY, Chang J, Cao AM, Wang JY (2005) Macromol Biosci 5:433–440CrossRef

16.

da Silva MLA, Crawford A, Mundy JM, Correlo VM, Sol P, Bhattacharya M, Hatton PV, Reis RL, Neves NM (2010) Acta Biomater 6:1149–1157CrossRef

17.

Coutinho DF, Gomes ME, Neves NM, Reis RL (2012) Acta Biomater 8:1490–1497CrossRef

18.

Jaeger A, Gromadzki D, Jaeger E, Giacomelli FC, Kozlowska A, Kobera L, Brus J, Rihova B, El Fray M, Ulbrich K, Stepanek P (2012) Soft Matter 8:4343–4354CrossRef

19.

Brunner CT, Baran ET, Pinho ED, Reis RL, Neves NM (2011) Colloid Surface B 84:498–507CrossRef

20.

Xu L, Ren Z (2008) J Polym Eng 28:27–31CrossRef

21.

Bahari L, Mitomo H, Enjoji T, Yoshii F, Makuuchi K (1998) Polym Degrad Stab 62:551–557CrossRef

22.

Lim SK, Lee SI, Jang SG, Lee KH, Choi HJ, Chin IJ (2011) J Macromol Sci B 50:1171–1184CrossRef

23.

Lim SK, Lee SI, Jang SG, Lee KH, Choi HJ, Chin IJ (2011) J Macromol Sci B 50:100–110CrossRef

24.

Lim SK, Lee JJ, Jang SG, Lee SI, Lee KH, Choi HJ, Chin IJ (2011) Polym Eng Sci 51:1316–1324CrossRef

25.

Li G, Qi RR, Lu JQ, Hu XL, Luo Y, Jiang PK (2013) J Appl Polym Sci 127:3586–3594CrossRef

26.

Zhang YH, Lu B, Lv FZ, Guo WM, Ji JH, Chu PK, Zhang CG (2012) J Appl Polym Sci 126:756–761CrossRef

27.

Xu Q, Peng Q, Ni W, Hou ZZ, Li JG, Yu L (2006) J Appl Polym Sci 100:2901–2906CrossRef

28.

Son JM, Song KB, Kang BW, Lee KH (2012) Polym (Korea) 36:34–40CrossRef

29.

Lee YH, Wang KH, Park CB, Sain M (2007) J Appl Polym Sci 103:2129–2134CrossRef

30.

Wu W, Cao XW, Zhang YJ, He GJ (2013) J Appl Polym Sci 130:443–452CrossRef

31.

Joussein E, Petit S, Churchman J, Theng B, Righi D, Delvaux B (2005) Clay Miner 40:383–426CrossRef

32.

Du ML, Guo BC, Jia DM (2010) Polym Int 59:574–582

33.

Lecouvet B, Gutierrez JG, Sclavons M, Bailly C (2011) Polym Degrad Stab 96:226–235CrossRef

34.

Sharif NFA, Mohamad Z, Hassan A, Wahit MU (2012) J Polym Res 19:9749–9758CrossRef

35.

Marney DCO, Yang W, Russell LJ, Shen SZ, Nguyen T, Yuan Q, Varley R, Li S (2012) Polym Adv Technol 23:1564–1571CrossRef

36.

Marney DCO, Russell LJ, Wu DY, Nguyen T, Cramm D, Rigopoulos N, Wright N, Greaves M (2008) Polym Degrad Stab 93:1971–1978CrossRef

37.

Ye YP, Chen HB, Wu JS, Chan CM (2011) Compos Sci Technol 71:717–723CrossRef

38.

Jia ZX, Luo YF, Guo BC, Yang BT, Du ML, Jia DM (2009) Polym-Plast Technol 48:607–613CrossRef

39.

Wu W, Cao XW, Luo J, He GJ, Zhang YJ (2014) Polym Compos 35:847–855CrossRef

40.

Geol SK, Beckman EJ (1994) Polym Eng Sci 34:1137–1147CrossRef

41.

Corre YM, Maazouz A, Duchet J, Reignier J (2011) J Supercrit Fluids 58:177–188CrossRef

42.

Marini J, Suman Bretas RE (2013) Polym Eng Sci 53:1512–1528CrossRef

43.

Mishra JK, Hwang KJ, Ha CS (2005) Polymer 46:1995–2002CrossRef

44.

Lee KS, Chang YW (2013) J Appl Polym Sci 128:2807–2816CrossRef

45.

Tang XG, Hou M, Zou J, Truss R (2013) J Appl Polym Sci 128:869–878CrossRef

46.

Nam JY, Ray SS, Okamoto M (2003) Macromolecules 36:7126–7131CrossRef

47.

Colton JS, Suh NP (1987) Polym Eng Sci 27:485–492CrossRef

48.

Colton JS, Suh NP (1987) Polym Eng Sci 27:493–499CrossRef

49.

Huang HX, Wang JK (2007) J Appl Polym Sci 106:505–513CrossRef

50.

Tsuchiya A, Tateyama H, Kikuchi T, Takahashi T, Koyama K (2007) Polym J 39:514–523CrossRef

51.

Yang JT, Huang LQ, Li LL, Zhang YF, Chen F, Zhong MQ (2013) J Polym Res 20:173–180CrossRef

52.

Vogel H (1921) Phys Z 23:645–646

53.

Fulcher GS (1925) J Am Ceram Soc 8:339–355CrossRef

54.

Tammann G, Hesse W (1926) Anorg Allg Chem 156:245–257CrossRef

55.

Reverchon E, Cardea S (2007) J Supercrit Fluids 40:144–152CrossRef

56.

Lee ST, Park CB, Ramesh NS (2006) CRC Press 64–72

57.

Kiran E, Liu K, Ramsdell K (2008) Polymer 49:1853–1859CrossRef

58.

Markocic E, Skerget M, Knez Z (2013) Ind Eng Chem Res 52:15594–15601CrossRef

59.

Zhang P, Zhou NQ, Li B (2007) Polym-Plast Technol 46:885–891CrossRef

60.

Liao X, Nawaby AV, Naguib HE (2012) J Appl Polym Sci 124:585–594CrossRef

61.

Nofar M, Zhu W, Park CB (2012) Polymer 53:3341–3353CrossRef

62.

Li DC, Liu T, Zhao L, Yuan WK (2011) J Supercrit Fluids 60:89–97CrossRef

Title: Preparation of biodegradable poly(butylene succinate)/halloysite nanotube nanocomposite foams using supercritical CO2 as blowing agent
Authors: Wei Wu
Xianwu Cao
Hong Lin
Guangjian He
Mengmeng Wang
Publication date: 01-09-2015
Publisher: Springer Netherlands
Published in: Journal of Polymer Research / Issue 9/2015
Print ISSN: 1022-9760
Electronic ISSN: 1572-8935
DOI: https://doi.org/10.1007/s10965-015-0811-6

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