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Journal of Materials Science

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12-10-2022 | Chemical routes to materials

An intelligent superhydrophobic absorbent with electrothermal conversion performance for effective high-viscosity oil removal and oil–water separation

Authors: Xuedan Zhu, Yajie Pang, Jinmei He, Yaxin Wu, Jianwei Ge, Lei Shen, Jie Yang, Mengnan Qu

Published in: Journal of Materials Science | Issue 40/2022

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Abstract

Functionalized superwetting materials that are able to deal with the contamination problems of industrial and domestic oily wastewater are urgently demanded in the field of oil–water separation. In this work, we fabricated superhydrophobic absorbent with excellent electrothermal conversion performance through the liquid-phase reduction and hierarchically assemble methods. The adhesive layer of poly-dopamine (PDA), Cu/carbon microspheres composites (Cu/CMSs) and the fluoride-free hydrophobic reagents were successively assembled on the absorbent cotton to obtain the intelligent absorbent with excellent superhydrophobicity (WCA = 154°), satisfactory oil–water separation efficiency (> 98.3%) and high oil absorption capacity (12–20 g/g). Surprisingly, this intelligent absorbent displayed an excellent electrothermal conversion capacity, which provided the basis for the collection of high-viscosity oil and the low-melting solid oil. On the basis of the excellent electrothermal conversion performance, it also could be utilized as a filter to effectively realize the continuous separation process of high-viscosity crude oil/water mixture under low-voltage conditions. Therefore, this intelligent absorbent possesses broad application prospects in high-viscosity oil–water separation, oily wastewater treatment, oil spill cleaning, crude oil extraction, petrochemicals and other fields.

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Feng XH, Stewart S, Sartori L, Hodges K (2020) Understanding the effect of skim oil recycle on the water/oil separation in steam assisted gravity drainage operations. J Pet Sci Eng 192:107233CrossRef

Silva UG, Melo MA, Silva AF, Farias RF (2003) Adsorption of crude oil on anhydrous and hydrophobized vermiculite. J Colloid Interface Sci 260:302–304CrossRef

He BY, Zhang YY, Li BJ, Chen YH, Zhu L (2021) Preparation and hydrophobic modification of carboxymethyl chitosan aerogels and their application as an oil adsorption material. J Environ Chem Eng 9:106333CrossRef

Yang K, Ren JQ, Cui YH, Shah T, Zhang QY, Zhang BL (2021) Length controllable tubular carbon nanofibers: Surface adjustment and oil adsorption performance. Colloids Surf A 615:126272CrossRef

Li ZK, Kepkay P, Lee K, King T, Michel BC, Albert DV (2007) Effects of chemical dispersants and mineral fines on crude oil dispersion in a wave tank under breaking waves. Mar Pollut Bull 54:983–993CrossRef

Nyankson E, Muslum D, Gonen M, Gupta R (2016) Interfacially active hydroxylated soybean lecithin dispersant for crude oil spill remediation. ACS Sustain Chem Eng 4:2056–2067CrossRef

Wang AQ, Li YM, Yang XL, Bao MT, Cheng H (2017) The enhanced stability and biodegradation of dispersed crude oil droplets by Xanthan Gum as an additive of chemical dispersant. Mar Pollut Bull 118:275–280CrossRef

Kuo T, Chen Y, Lin C, Chen J (2016) Oil recovery from a fluctuating water table. Pet Sci Technol 34:1562–1567CrossRef

Patrick O, Princewill O, Boniface O, Ugochukwu D (2017) In situ combustion methods: applicability to heavy oil reservoirs in the niger delta. Pet Sci Technol 35:51–58CrossRef

10.

Varfolomeev MA, Yuan CD, Alexander VB, Minkhanov IF, Seyedsaeed MK, Emil RS, Marrat MM, Emil RB et al (2021) Effect of copper stearate as catalysts on the performance of in-situ combustion process for heavy oil recovery and upgrading. J Pet Sci Eng 207:109125CrossRef

11.

Zhang X, Liu QW, Fan ZZ, Liu YJ (2019) Enhanced heavy oil recovery and performance by application of catalytic in-situ combustion. Pet Sci Technol 37:493–499CrossRef

12.

Mirshahghassemi S, Cai B, Lead JR (2019) A comparison between the oil removal capacity of polymer-coated magnetic nanoparticles in natural and synthetic environmental samples. Environ Sci Technol 53:4426–4432CrossRef

13.

Song QQ, Zhu JY, Niu XP, Wang J, Dong GY, Shan MX, Zhang B, Matsuyama H et al (2022) Interfacial assembly of micro/nanoscale nanotube/silica achieves superhydrophobic melamine sponge for water/oil separation. Sep Purif Technol 280:119920CrossRef

14.

Lu YQ, Yuan WZ (2017) Superhydrophobic/superoleophilic and reinforced ethyl cellulose sponges for oil/water separation: synergistic strategies of cross-linking, carbon nanotube composite, and nanosilica modification. ACS Appl Mater Interfaces 9:29167–29176CrossRef

15.

Zhou ZP, Wu XF (2015) Electrospinning superhydrophobic-superoleophilic fibrous PVDF membranes for high-efficiency water-oil separation. Mater Lett 160:423–427CrossRef

16.

Mehranbod N, Khorram M, Azizi S, Khakinezhad N (2021) Modification and superhydrophilization of electrospun polyvinylidene fluoride membrane using graphene oxide-chitosan nanostructure and performance evaluation in oil/water separation. J Environ Chem Eng 9:106245CrossRef

17.

Yang J, Cui JY, Xie AT, Dai JD, Li CX, Yan YS (2021) Facile preparation of superhydrophilic/underwater superoleophobic cellulose membrane with CaCO₃ particles for oil/water separation. Colloids Surf A 608:125583CrossRef

18.

Duan FZ, Zhu YF, Lu YS, Wang XW, Wang AQ (2022) Preparation of pre-wetted underwater superoleophobic porous material from green water-based foam for oil-water separation. J Mater Sci 57:9172–9186. https://doi.org/10.1007/s10853-022-07232-6CrossRef

19.

Liu MM, Hou YY, Li J, Tie L, Guo ZG (2018) pH-responsive superwetting fabric for on-demand oil-water separation. Chem Lett 47:923–926CrossRef

20.

Xiang YH, Shen JH, Wang YZ, Liu F, Xue LX (2015) A pH-responsive PVDF membrane with superwetting properties for the separation of oil and water. RSC Adv 5:23530–23539CrossRef

21.

Wu C, Zhang Y, Zhao Q, Li Y, Zhang BQ (2021) Ultrahigh throughput and efficient separation of oil/water mixtures using superhydrophilic multi-scale CuBTC-coated meshes. Sep Purif Technol 279:119802CrossRef

22.

Qu RX, Zhang WF, Li XY, Liu YA, Wei Y, Lin F, Jiang L (2020) Peanut leaf-inspired hybrid metal-organic framework with humidity-responsive wettability: toward controllable separation of diverse emulsions. ACS Appl Mater Interfaces 12:6309–6318CrossRef

23.

Du JC, Zhang CY, Pu H, Li YF, Jin SM, Tan LX, Zhou CL, Dong LC (2019) HKUST-1 MOFs decorated 3D copper foam with superhydrophobicity/superoleophilicity for durable oil/water separation. Colloids Surf A 573:222–229CrossRef

24.

Sun S, Xiao QR, Zhou X, Wei YY, Shi L, Jiang Y (2018) A bio-based environment-friendly membrane with facile preparation process for oil-water separation. Colloids Surf A 559:18–22CrossRef

25.

Xu Z, Jiang DY, Wei ZB, Chen J, Jing JF (2018) Fabrication of superhydrophobic nano-aluminum films on stainless steel meshes by electrophoretic deposition for oil-water separation. Appl Surf Sci 427:253–261CrossRef

26.

Shen BS, Du CX, Wang W, Yu D (2022) Hydrophilic SPE/MPTES-PAN electrospun membrane prepared via click chemistry for high efficiency oil-water separation. J Mater Sci 57:1474–1488. https://doi.org/10.1007/s10853-021-06688-2CrossRef

27.

Yuan J, Liao FF, Guo YN, Liang LY (2019) Preparation and performance of superhydrophilic and superoleophobic membrane for oil/water separation. Prog Chem 31:144–155

28.

Zhu XT, Zhang ZZ, Ge B, Men XH, Zhou XY, Xue QJ (2014) A versatile approach to produce superhydrophobic materials used for oil-water separation. J Colloid Interface Sci 432:105–108CrossRef

29.

Aljuboury DA, Palaniandy P, Abdul HB, Feroz S (2017) Treatment of petroleum wastewater by conventional and new technologies-A review. Global Nest J 19:439–452CrossRef

30.

Jing B, Feng QH, Qu ZQ (2021) Study on the treatment of petroleum wastewater with advanced oxidation process. Fresenius Environ Bull 30:949–953

31.

Gao LL, Lu YC, Zhang JL, Li J, Zhang JD (2019) Biotreatment of restaurant wastewater with an oily high concentration by newly isolated bacteria from oily sludge. World J Microbiol Biotechnol 35:179CrossRef

32.

Mirshafiee A, Rezaee A, Mamoory RS (2018) A clean production process for edible oil removal from wastewater using an electroflotation with horizontal arrangement of mesh electrodes. J Clean Prod 198:71–79CrossRef

33.

Sanghamitra P, Mazumder D, Mukherjee S (2021) Treatment of wastewater containing oil and grease by biological method-a review. J Environ Sci Health Part A Eng 56:394–412CrossRef

34.

Yu J, Cao C, Pan Y (2021) Advances of adsorption and filtration techniques in separating highly viscous crude oil/water mixtures. Adv Mater Interfaces 8:2100061CrossRef

35.

Bai B, Sun YK, Yang CX, He YH, Li S, Hu N, Wang HL (2020) Photothermal polymethylsilsesquioxane-vinyltrimethoxysilane-polypyrrole xerogel for efficient solar-driven viscous oil/water separation through one-pot synthesis route. J Photonics Energy 10:023508CrossRef

36.

Zhong Q, Shi GG, Sun Q, Mu P, Li J (2021) Robust PVA-GO-TiO₂ composite membrane for efficient separation oil-in-water emulsions with stable high flux. J Membr Sci 640:119836CrossRef

37.

Wu MM, Xiang B, Mu P, Li J (2022) Janus nanofibrous membrane with special micro-nanostructure for highly efficient separation of oil–water emulsion. Sep Purif Technol 297:121532CrossRef

38.

Shi GG, Wu MM, Zhong Q, Mu P, Li J (2021) Superhydrophobic waste cardboard aerogels as effective and reusable oil absorbents. Langmuir 37:7843–7850CrossRef

39.

Kong Y, Zhang SM, Gao Y, Cheng XH, Kong WJ, Qi YF, Wang SQ, Yin FJ (2022) Low-temperature carbonization synthesis of carbon-based super-hydrophobic foam for efficient multi-state oil/water separation. J Hazard Mater 423:127064CrossRef

40.

Wang P, Zhang JY, Wen H, Zhu ZY, Huang W, Liu CK (2021) Photothermal conversion-assisted oil water separation by superhydrophobic cotton yarn prepared via the silver mirror reaction. Colloids Surf A 610:125684CrossRef

41.

Hou SY, Zhu TL, Shen WC, Kang FY, Inagaki M, Huang ZH (2021) Exfoliated graphite blocks with resilience prepared by room temperature exfoliation and their application for oil-water separation. J Hazard Mater 424:127724CrossRef

42.

Zeng QT, Ma PM, Lai DH, Lai XJ, Zeng XR, Li HQ (2021) Superhydrophobic reduced graphene oxide@poly(lactic acid) foam with electrothermal effect for fast separation of viscous crude oil. J Mater Sci 56:11266–11277. https://doi.org/10.1007/s10853-021-06029-3CrossRef

43.

Zhu K, Li ZT, Cheng F, Wu C, Cai D, Zhang QY, Zhang HP (2021) Preparation of durable superhydrophobic composite coatings with photothermal conversion precisely targeted configuration self-healability and great degradability. Compos Sci Technol 213:108926CrossRef

44.

Huang W, Zhang L, Lai XJ, Li HQ, Zeng XR (2020) Highly hydrophobic F-rGO@wood sponge for efficient clean-up of viscous crude oil. Chem Eng J 386:123994CrossRef

45.

Yue XJ, Fu DB, Zhang T, Yang DY (2020) Superhydrophobic stainless-steel mesh with excellent electrothermal properties for efficient separation of highly viscous water-in-crude oil emulsions. Ind Eng Chem Res 59:17918–17926CrossRef

46.

Li HY, Zhong Q, Sun Q, Xiang B, Li J (2022) Upcycling waste pinenut shell membrane for highly efficient separation of crude oil-in-water emulsion. Langmuir 38:3493–3500CrossRef

47.

Ma JW, Fan HQ, Ren XH, Wang C, Tian HL, Dong GZ, Wang WJ (2019) A simple absorbent cotton biotemplate to fabricate SnO₂ porous microtubules and their gas-sensing properties for chlorine. ACS Sustain Chem Eng 7:147–155CrossRef

48.

Li XF, Wu XT (2015) Preparation of multilayer carbon microspheres by using graphitic carbon nitride as precursor. Phys B Condens Matter 477:137–140CrossRef

49.

Yan TN, Xu JL, Chu ZY, Liu EH, Yang L, Wang CH (2017) Hydrothermal synthesis and electrochemical properties of N-doped activated carbon microspheres. Int J Electrochem Sci 12:6118–6128CrossRef

50.

Huang XW, Zhang S, Xiao W, Luo JC, Li B, Wang L, Xue HG, Gao JF (2020) Flexible PDA@ACNTs decorated polymer nanofiber composite with superhydrophilicity and underwater superoleophobicity for efficient separation of oilin-water emulsion. J Membr Sci 614:118500CrossRef

51.

Du J, Xiang K, Zhao LQ, Lan XT, Liu PL, Liu Y (2019) Corrosion inhibition of 13Cr stainless steel in HCl/HAc/HF acid solution. Int J Electrochem Sci 14:8919–8930CrossRef

52.

Liu X, Li HH, Zhao XJ, Chen Y, Wang SW (2021) Comparison of the corrosion behavior of copper tubes in formic acid and acetic acid environment. Werkst Korros 72:1919–1927CrossRef

53.

Lu XH, Zhang FX, Yang XT, Xie JF, Zhao GX, Xue Y (2014) Corrosion performance of high strength 15Cr martensitic stainless steel in severe environments. J Iron Steel Res Int 21:774–780CrossRef

54.

Chukhlanov VY, Selivanov OG (2016) Electrical properties of syntactic foams based on hollow carbon microspheres and polydimethylsiloxane. Russ Phys J 59:944–948CrossRef

Title: An intelligent superhydrophobic absorbent with electrothermal conversion performance for effective high-viscosity oil removal and oil–water separation
Authors: Xuedan Zhu
Yajie Pang
Jinmei He
Yaxin Wu
Jianwei Ge
Lei Shen
Jie Yang
Mengnan Qu
Publication date: 12-10-2022
Publisher: Springer US
Published in: Journal of Materials Science / Issue 40/2022
Print ISSN: 0022-2461
Electronic ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-022-07805-5

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