Preparation, with graphene, of novel biomimetic self-healing microcapsules with high thermal stability and conductivity

Ying-Yuan WANG; Yi-Qiu TAN

doi:10.1007/s11709-023-0027-5

Front. Struct. Civ. Eng. ›› 2023, Vol. 17 ›› Issue (8) : 1188 -1198. DOI: 10.1007/s11709-023-0027-5

RESEARCH ARTICLE

Preparation, with graphene, of novel biomimetic self-healing microcapsules with high thermal stability and conductivity

Ying-Yuan WANG ¹
, Yi-Qiu TAN ¹^,²^,^†

Author information +

History +

PDF (5342KB)

Abstract

This paper reports a comparative study of microcapsules with enhanced thermal stability and electrical conductivity inspired by the bionic thermal insulation of birds’ feathers for self-healing aged asphalt. The work is based on an in situ polymerization with composite shell components of graphene and hexamethoxymethylmelamine resin. By using graphene, microcapsules with rough surfaces are achieved, improving the interface between microcapsules and asphalt. In addition, the microcapsules’ initial thermal decomposition temperature is appropriately high, so that the stability of the microcapsule in the asphalt highway system is protected. The proportion of graphene in the microcapsule shell can regulate the microcapsule’s heat resistance because graphene modifies the shell’s structural makeup. Additionally, the microcapsules’ electrical conductivity is relatively high. The self-healing capability of bitumen sharply increases, providing benefit to the effect of microcapsules on the properties of aged asphalt.

Graphical abstract

Keywords

graphene / microcapsule / bitumen / heat insulation / conductivity

Cite this article

Download citation ▾

Ying-Yuan WANG, Yi-Qiu TAN. Preparation, with graphene, of novel biomimetic self-healing microcapsules with high thermal stability and conductivity. Front. Struct. Civ. Eng., 2023, 17(8): 1188-1198 DOI:10.1007/s11709-023-0027-5

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Nie F H, Jian W, Lau D. Advanced self-healing asphalt reinforced by graphene structures: An atomistic insight. Journal of Visualized Experiments, 2022, 183(183): e63303

[2]	Li Z L, Yu X, Liang Y S, Wu S P. Carbon nanomaterials for enhancing the thermal, physical and rheological properties of asphalt binders. Materials, 2021, 14(10): 2585

[3]	Tabaković A, Schlangen E. Self-healing technology for asphalt pavements. Advances in Polymer Science, 2016, 273: 285–306

[4]	Xu S, Garcia A, Su J F, Liu Q T, Tabakovic A, Schlangen E. Self-healing asphalt review: From idea to practice. Advanced Materials Interfaces, 2018, 5(17): 1800536

[5]	Su J F, Schlangen E. Synthesis and physicochemical properties of high compact microcapsules containing rejuvenator applied in asphalt. Chemical Engineering Journal, 2012, 198: 289–300

[6]	Su J F, Schlangen E, Qiu J. Design and construction of microcapsules containing rejuvenator for asphalt. Powder Technology, 2013, 235: 563–571

[7]	Su J F, Qiu J, Schlangen E. Stability investigation of self-healing microcapsules containing rejuvenator for bitumen. Polymer Degradation & Stability, 2013, 98(6): 1205–1215

[8]	Su J F, Qiu J, Schlangen E, Wang Y Y. Experimental investigation of self-healing behavior of bitumen/microcapsule composites by a modified beam on elastic foundation method. Materials and Structures, 2015, 48(12): 4067–4076

[9]	Su J F, Han S, Wang Y Y, Schlangen E, Han N X, Liu B, Zhang X L, Yang P, Li W. Experimental observation of the self-healing microcapsules containing rejuvenator states in asphalt binder. Construction & Building Materials, 2017, 147: 533–542

[10]	Garcia A, Jelfs J, Austin C J. Internal asphalt mixture rejuvenation using capsules. Construction & Building Materials, 2015, 101: 309–316

[11]	Garcia A, Austin C J, Jelfs J. Mechanical properties of asphalt mixture containing sunflower oil capsules. Journal of Cleaner Production, 2016, 118: 124–132

[12]	Shu B A, Wu S P, Dong L J, Wang Q, Liu Q T. Microfluidic synthesis of Ca-alginate microcapsules for self-healing of bituminous binder. Materials, 2018, 11(4): 630

[13]	Xu S, Liu X Y, Tabakovic A, Schlangen E. Investigation of the potential use of calcium alginate capsules for self-healing in porous asphalt concrete. Materials, 2019, 12(1): 168

[14]	Bunch J S, van der Zande A M, Verbridge S S, Frank I W, Tanenbaum D M, Parpia J M, Craighead H G, McEuen P L. Electromechanical resonators from graphene sheets. Science, 2007, 315(5811): 490–493

[15]	Cao K, Feng S Z, Han Y, Gao L B, Ly T H, Xu Z P, Lu Y. Elastic straining of free-standing monolayer graphene. Nature Communications, 2020, 11(1): 284

[16]	Monti M, Rallini M, Puglia D, Peponi L, Torre L, Kenny J M. Morphology and electrical properties of graphene-epoxy nanocomposites obtained by different solvent assisted processing methods. Composites Part A: Applied Science and Manufacturing, 2013, 46: 166–172

[17]	Chen C, Qiu S H, Cui M J, Qin S L, Yan G P, Zhao H C, Wang L, Xue Q. Achieving high performance corrosion and wear resistant epoxy coatings via incorporation of noncovalent functionalized graphene. Carbon, 2017, 114: 356–366

[18]	Wan Y J, Tang L C, Gong L X, Yan D, Li Y B, Wu L B, Jiang J X, Lai G Q. Grafting of epoxy chains onto graphene oxide for epoxy composites with improved mechanical and thermal properties. Carbon, 2014, 69: 467–480

[19]	Huangfu Y, Ruan K, Qiu H, Lu Y, Liang C, Kong J, Gu J. Fabrication and investigation on the PANI/MWCNT/thermally annealed graphene aerogel/epoxy electromagnetic interference shielding nanocomposites. Composites Part A: Applied Science and Manufacturing, 2019, 121: 265–272

[20]	Wang Y Y, Su J F, Schlangen E, Han N X, Han S, Li W. Fabrication and characterization of self-healing microcapsules containing bituminous rejuvenator by a nano-inorganic/organic hybrid method. Construction & Building Materials, 2016, 121: 471–482

[21]	Zhang Q Q, Lin D, Deng B W, Xu X, Nian Q, Jin S Y, Leedy K D, Li H, Cheng G J. Flyweight, superelastic, electrically conductive, and flame-retardant 3D multi-nanolayer graphene/ceramic metamaterial. Advanced Materials, 2017, 29(28): 1605506

[22]	Sogukpinar H. Effect of hairy surface on heat production and thermal insulation on the building. Environmental Progress & Sustainable Energy, 2020, 39(6): e13435

[23]	Fan Z, Marconnet A, Nguyen S T, Lim C Y H, Duong H M. Effects of heat treatment on the thermal properties of highly nanoporous graphene aerogels using the infrared microscopy technique. International Journal of Heat and Mass Transfer, 2014, 76: 122–127

[24]	Long Y, Vincent B, York D, Zhang Z B, Preece J A. Organic-inorganic double shell composite microcapsules. Chemical Communications, 2010, 46(10): 1718–1720

[25]	Long Y, Song K, York D, Zhang Z B, Preece J A. Engineering the mechanical and physical properties of organic-inorganic composite microcapsules. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2013, 433: 30–36

[26]	Zhang Y, Tian J W, Zhong J, Shi X M. Thin nacre-biomimetic coating with super-anticorrosion performance. ACS Nano, 2018, 12(10): 10189–10200

[27]	Sun D Q, Pang Q, Zhu X Y, Tian Y, Lu T, Yang Y. Enhanced self-healing process of sustainable asphalt materials containing microcapsules. ACS Sustainable Chemistry & Engineering, 2017, 5(11): 9881–9893

[28]	Dao T D, Jeong H M. A Pickering emulsion route to a stearic acid/graphene core-shell composite phase change material. Carbon, 2016, 99: 49–57

[29]	Segundo I R, Freitas E, Branco V T F C, Landi S Jr, Costa M F, Carneiro J O. Review and analysis of advances in functionalized, smart, and multifunctional asphalt mixtures. Renewable & Sustainable Energy Reviews, 2021, 151: 111552

[30]	Sun H Z, Liu W Y, Wang Y, Chang X Y, Zhao H, Shi S K, Xing J, Wu D, Zhang J, Zhang W. Evaluation method and influence law of UV-cured polyurethane on the self-healing performance of asphalt and asphalt mixtures. Buildings, 2023, 13(5): 1277