Preparation of PSF/FEP mixed matrix membrane with super hydrophobic surface for efficient water-in-oil emulsion separation

Polysulfone (PSF)/fluorinated ethylene propylene (FEP) mixed matrix membranes (MMMs) with super hydrophobic surface were successfully fabricated via non-solvent induced phase separation (NIPS) method. The effects of FEP content on the morphology, roughness, wettability, pore size, and mechanical property of PSF/FEP MMMs were characterized by scanning electron microscope, confocal microscopy, contact angle goniometer, mercury porosimetry, and tensile testing instrument, respectively. When the FEP content was 9 wt%, the average roughness of M-4 reached 0.712 μm. Meanwhile, the water contact angle (CA) and the water sliding angle (SA) was 153.3° and 6.1°, respectively. M-4 showed super hydrophobicity with a micro- and nanoscale structure surface. Then, M-4 was used for separating of water-in-oil emulsion, showing high separation efficiency for water-in-kerosene and water-in-diesel emulsions of 99.79% and 99.47%, respectively. The flux and separation efficiency changed slightly after 10 cycles. Therefore, this study indicated that the obtained PSF/FEP MMM with super hydrophobic surface could be used for efficient water-in-oil emulsion separation.


Introduction
Environmental pollution has got increasingly serious with the rapid expansion of industrialization.Emulsied oil/water mixtures are generated in diverse industries, such as petrochemical, food, textile, leather, steel, aluminum, and metal nishing, the direct discharge of which will threaten the environment and human health. 1,2Separating water from emulsied oil/water mixtures is extremely important for the treatment of water-in-oil emulsion and the purication of oil, such as fuel oil, automotive oil, and transformer oil.The separation of emulsied oil/water mixtures is always difficult and challenging because the droplets are usually stable and nanoscale. 3[9] Generally, the membranes are classied as the hydrophobicoleophilic membrane and hydrophilic-oleophobic membrane for "oil-removing" and "water-removing" process, respectively. 10 series of "oil-removing" membranes have been fabricated for highly efficient oil/water separation by designing superhydrophobic and superoleophilic surfaces.Li et al. 11 immobilized Ag nanocluster on nano-brous membrane for oil/water separation.Cao et al. 12 modied stainless steel mesh using chemistry and Michael addition reaction by n-dodecyl mercaptan for efficient oil/water separation.Zhang et al. 13 fabricated superhydrophobic and superoleophilic polyester materials by one-step growth of silicone nanolaments onto the textile via chemical vapor deposition of trichloromethylsilane for oil/water separation.These materials usually show ultrahigh permeation ux for the separation of immiscible oil/water mixtures.Nevertheless, these materials could not effectively separate emulsied oil/water mixtures because their pore sizes (about tens of micrometers) are much larger than the droplet sizes of the emulsion (typically less than 20 mm). 14uperhydrophobic surface is one of the most important parameters for the separation of water-in-oil emulsion.When emulsion droplets touch the superhydrophobic surface, a de-emulsication process could proceed immediately on the membrane surface due to the different wettability for oil and water. 2 Meanwhile, the oil quickly penetrates through the membrane and water is retained above.Generally, the emulsion separation efficiency increases with the improvement of hydrophobicity. 15he preparation of the superhydrophobic membranes for the separation of water-in-oil emulsion usually requires expensive materials, strict conditions (such as harsh chemical treatment), and complex processing methods including plasma etching, chemical vapor deposition, electrodeposition, calcination and the use of templates, 11,13,[16][17][18][19][20] which can be challenging for the large-scale membrane fabrication.
PSF is a classical membrane material for the preparation of ultraltration, [21][22][23][24] nanoltration, 25,26 and matrix membranes [27][28][29] due to its outstanding properties of thermal stability, chemical resistance, high mechanical strength, and wide aperture adjustment range. 30][37] Herein, we report the fabrication of PSF/FEP mixed matrix membranes (MMMs) for water-in-oil emulsion separation by using environmentally friendly and low cost chemicals as well as under simple and easy conditions to meet the need on an industrial scale.SiO 2 nanoparticles and micro-nanometer scale FEP particles were introduced into PSF casting solution to fabricate micro-and nanoscale hierarchical structures on the membrane surface.Meanwhile, the surface energy of membrane decreased due to the existing of FEP on the surface, which was benecial to fabricating of superhydrophobic surface, and there were obvious improvements on the comprehensive performance of the as-prepared MMMs.The effects of FEP content on MMMs' performances in terms of hydrophobicity, mechanical strength, permeability, and separation performance of water-in-oil emulsion were investigated respectively.

Membrane preparation
Before using, PSF, FEP resin and SiO 2 particles were dried in an oven at 80 C for 12 h to wipe out the residual moisture.In the process of preparing casting solution, DOP and DMAc were mixed homogeneously at 80 C for 30 min; then, SiO 2 particles were introduced into the mixed stirring for 1 h and ultrasound 30 min to guarantee SiO 2 particles homogeneous dispersion.
PSF was dissolved in the mixed for 3 h at 80 C. Finally, FEP was introduced into the previous solution stirring for 3 h.Aer degassing for 30 min with atmospheric pressure, the casting solution was casted into at sheet membranes on the clean and smooth glass substrate.Then, the membranes were immersed into the deionized water for 5 min and soaked in the ethyl alcohol for 24 h to remove solvent and additive.Finally, membranes with different FEP content were obtained and dried in the air for the analytical test.The as-prepared membranes with different FEP content were labeled as M-1, M-2, M-3, M-4, and M-5, respectively.The composition of PSF/FEP MMMs were listed in Table 1.

Characterization of PSF/FEP MMMs
PSF/FEP MMMs had large roughness, which was not suitable for quantifying by Atomic Force Microscope (AFM).So, surface roughness of the membrane was measured by Confocal Scanning Microscope (CSM700, Zeiss, Germany).The samples were cut into 5 mm (width) Â 5 mm (length) test strips and then were stick on the smooth glass.The morphologies of membrane surface and cross-section were observed using eld emission scanning electron microscopy (FESEM, S4800, HITACHI Japan).The samples were coated in gold before testing.The mechanical properties of PSF/FEP MMMs were measured by YG-061-1500 tensile tester at room temperature.The samples were cut into 5 mm (width) Â 50 mm (length) test strips.Each sample was measured 5 times at the tensile rate of 2 mm min À1 .The wettability of PSF/FEP MMMs were measured via Optical contact angle meter (JYSP-180, Jinshengxin Inspection instrument Co., Ltd.) by measuring the contact angle of water and oil.The water droplet and oil droplet about 2 ml were dropped on the membrane surface, respectively.The porosity of PSF/FEP MMMs were measured by the gravimetric method.The porosity (3) was used to calculate by the following eqn (1): where, W 1 is the weight of the wet membrane, W 2 is the weight of the dry membrane, D 1 is the n-butyl alcohol density, and D 2 is the density of PSF/FEP MMMs.
The pore size and pore size distribution of membranes were measured by mercury porosimetry (Autopore IV9500, Tektronix, USA).The oil ux of PSF/FEP MMMs were measured by a laboratory device (Fig. 11(a)).The samples were located between the feed liquid bottle and the lter tip sealed by PTFE tape carefully.The oil ux was measured at À0.09 MPa and the ux was calculated by the following eqn (2): where, J is the oil ux (L m À2 h À1 ), V is the oil total volume (L), A is the membrane area (m 2 ), t is the operating time (h).

Emulsion separation experiment
Surfactant-stabilized water-in-oil emulsion is stable and difficult to separate.In this work, we selected surfactant-stabilized water-in-oil emulsion to test the separating performance of PSF/FEP MMMs.Surfactant-stabilized water-in-oil emulsions were prepared by adding 0.5 g Span80 into 100 g oil (kerosene and diesel), stirring 30 min, then adding 5 g water dropwise slowly, and vigorously stirring for more than 3 h.The water-inoil emulsions of kerosene and diesel were stable for separation experiment.The separation experiment was conducted by the laboratory device as shown in Fig. 11(a).The fresh water-in-oil emulsions were separated through PSF/FEP MMMs under a negative pressure (À0.09MPa).The water content of fresh water-in-oil emulsions and collected ltrate were analyzed This journal is © The Royal Society of Chemistry 2018 using a Karl Fischer titrator.For each PSF/FEP MMM, ve measurements were tested to obtain an average value.The separation efficiency was calculated by the following eqn (3): where, W is the separation efficiency (%), C 0 is the water content of fresh water-in-oil emulsions (ppm), C 1 is the water content of collected ltrate (ppm).

Surface roughness
Conventionally, super hydrophobic surface has been produced mainly by two ways. 12One is to create a rough structure on the hydrophobic surface, 38 and the other is to modify a rough surface by low surface free energy materials. 39However, it has demonstrated that the -CF 3terminated surface possessed the Fig. 2 FESEM images of PSF/FEP MMMs with different FEP contents.
lowest free energy, while the maximum water contact angle could only reach about 120 on at surface. 40As described in Wenzel equation, 41 it could be known that the surface roughness was also a key factor for super hydrophobic surface.The membrane surface roughness was showed in Fig. 1.The image colors represented different surface roughness size, red and blue were on behalf of large and small surface roughness, respectively.When the content of FEP was 9 wt%, the surface roughness was the largest of 0.712 mm because of forming micro-and nanoscale hierarchical structures on the membrane surface.Furthermore, micro-and nanoscale structures of the membrane surface were destroyed due to redundant FEP (12 wt%), so the surface roughness decreased.

Morphology
Morphologies of PSF/FEP MMMs with different FEP contents were observed by FESEM.As shown in Fig. 2, there were many papillae on the membrane surface with the addition of SiO 2 nanoparticles and micro-nanometer scale FEP particles.When the FEP content was 9 wt%, many papillae were clearly found on the M-4 surface with average diameter about 145 nm.These micro-and nanoscale structures improved the membrane surface roughness and hydrophobicity.However, when the content of FEP was up to 12 wt%, FEP particles were inclined to aggregate, which destroyed the structures of membrane surface.Morphologies of the membrane cross-sections were shown in Fig. 2, the cross-sections presented sponge-like pore structure, and there were some heterogeneous macro pores in the crosssections.With increasing FEP concentration, the cross-section pore structure got bigger.When the FEP concentration continued to increase to 12 wt%, an excess of FEP particles blocked the phase separation of matrix PSF and dispersion phase FEP, leading to destroying the pore structures.
The thickness of PSF/FEP MMMs was shown in Table 2.It could be found that the thickness improved obviously due to the improvement of the solid content with increasing FEP concentration.

Mechanical strength
The mechanical properties of PSF/FEP MMMs were discussed and shown in Fig. 3.For M-1, the elongation at break was the biggest of 22.06%, while tensile strength was low.With increasing FEP concentration, FEP particles changed the intrinsic structure of PSF matrix, the elongation at break decreased obviously.When the content of FEP was 9 wt%, the   PSF/FEP membrane had good elongation at break of 11.1% and the biggest tensile strength.The main reason was that M-4 had homogeneous cross-section pore structure, as shown in Fig. 2, which improved the tensile strength and the elongation at break.When FEP concentration was up to 12 wt%, the membrane structure was destroyed resulting in the tensile strength and elongation at break decreasing obviously.

Wettability of the membrane surface
Super hydrophobic and super oleophilic membrane surface is one of the most important properties for the efficient separation of water-in-oil emulsion.Generally, surfaces with a water contact angle (CA) larger than 150 and a water sliding angle (SA) lower than 10 are considered to be super hydrophobic surfaces.Fig. 4 showed the CA changing from 110.8 to 153.3 , as the content of FEP increased from 0 wt% to 12 wt% with constant 3 wt% SiO 2 .When FEP concentration was 9 wt%, the micro-and nanoscale hierarchical structures were fabricated on the M-4 surface.The CA of M-4 was about 153.3 .And the SA of M-4 was about 6.1 lower than 10 (calculated by the equation of SA ¼ arctan (h L À1 )) determined by placing a water droplet on its surface, which was inclined to tilt gradually until water droplet started to roll, as shown in Fig. 5.The result indicated that M-4 exhibited super hydrophobicity.When FEP concentration was 12 wt%, the hierarchical structures of the membrane surface were destroyed and the surface roughness decreased obviously, ultimately resulting in the decrease of hydrophobicity.
As shown in Fig. 6, the water droplets (dyed with methylene blue) kept sphere without inltrating the membrane surface, which demonstrated the super hydrophobicity of M-4.
The oil contact angle of PSF/FEP MMM was tested using kerosene on the M-4 surface.As shown in Fig. 7(a), the oil (kerosene) droplet was squeezed onto M-4 surface, then the oil droplet stuck to the membrane surface fast within 100 ms; aerwards, the needle was withdrew, the kerosene droplet rapidly spread out on the membrane surface and disappeared within 500 ms.The membrane exhibited good oleophilicity.
Furthermore, the water-adhesion property of M-4 surface was also characterized.Fig. 7(b) showed the process of water droplet on the membrane surface.When the needle approaching M-4 surface, the water droplet was squeezed onto the surface, then the water droplet was forced to sufficiently contact the membrane surface with an obvious deformation; aerwards, the needle was withdrew, the water droplet stuck completely to the needle and no trace of water was detected on   the membrane surface.That was because the M-4 surface was rough and hydrophobic, which trapped water molecules in a Wenzel state.Meanwhile, the contact area decreased between water droplet and the membrane surface.The result further indicated that M-4 exhibited super hydrophobicity and super oleophilicity.

Porosity and pore size
Porosity of the hydrophobic membrane was an important property for oil ux in membrane distillation.The porosities of PSF/FEP MMMs were measured using the gravimetric method, and the porosity results were shown in Fig. 8.It could be found that the porosity improved with increasing FEP concentration.The biggest porosity was 74.3% for M-4.That was because the membrane formed abundant and homogeneous sponge-like pore structure as shown in Fig. 2. Phase separation occurred between PSF matrix phase and FEP dispersed phase due to their different hydrophobicity.The phase separation would generate the interfacial micro voids, which improved porosity obviously.When FEP concentration was bigger than PSF concentration, the phase separation got difficult, which leaded to decreasing of porosity obviously.
The average pore size of PSF/FEP MMMs was shown in Table 2.It could be found that the pore size improved obviously with increasing FEP concentration.That was because the phase separation between PSF matrix phase and FEP dispersed phase would generate the interfacial micro voids.As shown in Fig. S1, † the pore size distribution of M-4 was narrow.The result further indicated that M-4 had homogenous porosity.

Flux
The pure oil uxes of PSF/FEP MMMs for kerosene and diesel were tested and shown in Fig. 9, the maximum ux of M-4 reached as high as 352.4 L m À2 h À1 and 668.8 L m À2 h À1 for kerosene and diesel, respectively.The membrane had higher porosity and oleophilic property, when FEP concentration was 9 wt%.The ux of diesel was higher than kerosene because the   viscosity of kerosene was lower.As shown in Fig. 10, with the time increasing, the uxes of M-4 for kerosene and diesel declined.In the beginning, the pore structure was densication and the ux declined quickly.Finally, the uxes of kerosene and diesel were stable about 246.7 L m À2 h À1 and 435.8 L m À2 h À1 , respectively.

Separation performance
We made water-in-kerosene and water-in-diesel stabilized emulsions with surfactant to conduct water-in-oil emulsion separation experiment.Fig. 11(b) showed the schematic diagram of the emulsion separation.Firstly, the water-in-oil emulsion took demulsication on the super hydrophobic membrane surface due to the different wetting performance for oil and water.Then, the oil quickly penetrated through the membrane and water was retained above.We used M-4 to conduct water-in-oil emulsion separation experiment.As shown in Fig. 12, the water content in fresh water-in-kerosene emulsion was about 47 145 ppm, and the ltrate was about 75 ppm.The water rejection rate reached 99.84%.The water content in fresh water-in-diesel emulsion was about 37 850 ppm, and the ltrate was about 195 ppm.The water rejection rate reached 99.48%.M-4 had a high water-in-oil separation precision due to the super hydrophobic surface.The optical microscopy images and droplet distribution for the separation result of water-inkerosene and water-in-diesel emulsions were shown in Fig. 13(a) and (b), respectively.There were dense water droplets in the fresh emulsion, however not a single water droplet was observed aer separation.And by comparison the picture before and aer ltration, we also found that the separation effect of M-4 was very good.3][44][45] To study the separation performance further, the membrane was exposed to the water-in-oil emulsion for a long time, which would cause unavoidable membrane fouling, leading to the reduction of membrane's service life and the separation efficiency.During a separation cycle, the membrane was immersed 20 mL ethanol for 2 h and dried in air.The process was repeated ten times and the oil purity of ltrate was counted each time.As demonstrated in Fig. 14, the separation precision of M-4 was also reected by calculating the purity of the collected ltrate in cycle 10 times.The separation efficiency for water-in-kerosene and water-in-diesel emulsions changed slightly and still maintained a relative high level of 99.79% and 99.47% aer 10 cycles.It indicated that PSF/FEP MMM had an  outstanding separation performance, which was in favor of using for a long time.
The comprehensive properties of PSF/FEP MMMs were shown in Table 2.

Fig. 4
Fig. 4 Water contact angle of PSF/FEP MMMs with different FEP concentration.

Fig. 7 Fig. 8
Fig. 7 Variation of kerosene (a) and water (b) contact angle depended on time for M-4 surface.

Fig. 5
Fig.5The instantaneous sliding behavior of a water droplet (dyed with methylene blue) on the M-4 surface.

Fig. 6
Fig. 6 Photograph of water droplets (dyed with methylene blue) on the M-4 surface.

Fig. 11 (
Fig. 11 (a) The image of laboratory device for continuous water-in-oil emulsions separation.(b) The schematic diagram of emulsion separation process.

Fig. 10
Fig. 10 Change of oil flux with the time increase.

Fig. 9
Fig. 9 Effect of the FEP content on flux.

Fig. 12
Fig.12The water content in fresh water-in-oil emulsion and the filtrate.

Fig. 14
Fig. 14 Change of the separation efficiency for M-4 with increasing cycle numbers.

Table 1
The composition of PSF/FEP MMMs

Table 2
The properties of PSF/FEP MMMs