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Facile synthesis of highly dispersed Ag doped Graphene Oxide/Titanate nanotubes as visible light photocatalytic membrane for water treatment Gonggang Liu, Kai Han, Yonghua Zhou, Hongqi Ye, Xiang Zhang, Jinbo Hu, and Xianjun Li ACS Sustainable Chem. Eng., Just Accepted Manuscript • DOI: 10.1021/ acssuschemeng.8b00029 • Publication Date (Web): 29 Mar 2018 Downloaded from http://pubs.acs.org on March 30, 2018

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Facile synthesis of highly dispersed Ag doped Graphene

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Oxide/Titanate nanotubes as visible light photocatalytic

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membrane for water treatment

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Gonggang Liua#, Kai Hanb#, Yonghua Zhoub, Hongqi Yeb, Xiang Zhanga, Jinbo Hua,c*, Xianjun Lia,c*

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a

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. College of Materials Science and Engineering, Central South University of Forestry and Technology, Changsha 410004, China

b

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. College of Chemistry and Chemical Engineering, Central South University, Changsha 410083, China

c

. Hunan Provincial Collaborative Innovation Center for High-efficiency Utilization of Wood and Bamboo Resources, Central South

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University of Forestry and Technology, Changsha 410004, China

#

Thesis two authors contributed equally.

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*Corresponding authors. Email: [email protected], [email protected].

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ABSTRACT

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Graphene oxide (GO) membranes have attracted extensive interest due to their

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ultrathin, high-flux, pore size tunable, superior flexibility and energy-efficient

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properties for transporting ions and molecules through the unique 2D channels.

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Nevertheless, membrane fouling leading to membrane blocking and poor water flux

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of GO membranes during long-term use resulting from the membrane fouling is one

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of the major obstacles for water treatment or desalination application. In this work, Ag

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doped GO/Titanate nanotubes (Ag/GO/TNTs) membranes with enhanced visible light

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degradation ability were fabricated by a single-step procedure to resolve the fouling

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problem via integration of photocatalysis with membrane filtration. The results show

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that the Ag nanoparticles could be highly dispersed on the surface of GO and TNTs.

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And the as-prepared Ag/GO/TNTs membranes exhibited reasonable ability on

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photocatalytic degradation of Methylene Blue under visible light. 90% of MB could

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be effectively degraded after 120 min irradiation with 8 mg of photocatalyst. More

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importantly, the membrane fouling could be effectively alleviated with visible light

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irradiation. In coupling photocatalysis and membrane separation process, the flux of

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Ag/GO/TNTs membranes with GO and TNT ratio at 1: 3 and Ag content of 6% could

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keep at 34.7 L/m2h which doubles that of membrane filtration without visible light

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irradiation. In addition, Ag/GO/TNTs membranes possess high acid-alkali resistance

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stability and good compressive strength. These results have provided a simple

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preparation strategy to obtain highly dispersed nanoparticles and valuable insight of

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endowing membranes with visible-light degradation ability for solving GO based

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membrane fouling.

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Keywords: Graphene oxide membranes; membrane fouling; visible light;

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photocatalytic degradation; Ag; Titanate nanotubes

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INTRODUCTION

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Due to a rising water pollution problem, affordable and safe drinking water is an

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on-going global challenge. Especially, contamination of dyes and other organism is

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one of the main problems in water treatment [1-3]. Membrane separation technology

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has been a promising approach due to high efficiency, low energy consuming and easy

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operation [4, 5]. Recently, graphene oxide (GO) and GO based membranes as a

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perfect molecular level separating unit have exhibited extraordinary separation

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performance in respect of water flux and pollutant molecular/ions rejection [6-14].

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And it has been an emerging field of research which has drawn extensive attentions

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[15-18]. However, when treating organic pollutants, GO based membranes is easy to

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suffer from membrane fouling resulting in flux decline due to strong adsorption

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ability for organic dye molecules [19-21], and it is intractable to remove attached

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pollutants which restricts their large scale application. Aiming at decreasing

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membrane pollution, endowing GO membranes with UV photocatalysis function have

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been proposed in our previous work [19, 21]. But to the best of our knowledge, few

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reports were found to synthesize and study GO based membrane with visible light

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photocatalytic ability for water decontamination and resolving membrane fouling

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under visible light irradiation.

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On the other hand, the fabrication of GO-based hybrid photocatalysts with a

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remarkable photocatalytic performance is currently a hot topic attracting global

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attentions [22-25]. GO could effectively reduce the electron-hole recombination rate

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and red-shift the response edge of TiO2 from UV to visible region [26]. And compared

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with

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photocatalytic activity as nanowires structure have larger specific surface and more

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contact area between TiO2 and graphene [27, 28]. Besides, nanoparticles of noble

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metals (i.e. Ag, Au, Pt) strongly absorb visible light due to their surface plasmon

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resonance (SPR) which could further significantly enhance visible light photocatalytic

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performance of GO-based hybrid photocatalysts [29, 30]. Sun [31] synthesized

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multifunctional nanocomposites (Ag/GO/TiO2) integrating 2D GO sheets, 1D TiO2

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nanorods and 0D Ag nanoparticles via a facile two-phase method. The Ag/GO/TiO2

GO/TiO2

nanoparticle

composites,

GO/TiO2

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nanowires

show

higher

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nanocomposites demonstrate remarkably enhanced photocatalytic activities in

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degrading organic dye (AO7) and phenol under solar irradiation compared with

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GO/TiO2 and Ag/GO.

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In the present work, single-step solvothermal synthesis of Ag/GO/TNTs was used. In

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a single-step synthetic procedure, the reduction of AgNO3 and graphene oxide and Ag

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loading on GO/TNTs were spontaneously performed by TEOA which act as reductant.

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Highly dispersed Ag nanoparticles on GO and TNTs were obtained. Meanwhile, the

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Ag/GO/TNTs membranes were fabricated by vacuum filtration of the Ag/GO/TNTs

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suspension, which could be directly used for water filtration treatment. In addition,

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crossflow filtration which is more approximated to real industrial process was applied

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to evaluate the separation performance. The results show that the as-prepared

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Ag/GO/TNTs membranes exhibited reasonable photocatalytic degradation of

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methylene blue (MB) dyes under visible light, which is superior to GO/TNTs and

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Ag/GO/P25 membranes. Moreover, the membrane fouling of Ag/GO/TNTs

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membranes could be effectively alleviated via a synergistic visible-light illumination

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compared with single membrane separation process. Besides, the Ag/GO/TNTs

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membranes possess high acid-alkali resistance stability and good compressive

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strength due to carbon-based material and support of embedded TNTs between GO

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layers respectively.

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EXPERIMENTAL SECTION

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Chemicals and materials. GO was prepared by the modified Hummers method, as

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shown in our previous work [32]. Titanate nanotubes (average diameters size of 10

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nm) were purchased from Klamar Chemical Reagent Co. Ltd. (Shanghai, China) and

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used as received.

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Synthesis of Ag doped GO/TNTs composites. Ag doped GO/TNTs composites were

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obtained via a simple solvothermal process. Typically, 0.18 g of TNTs with 40 mL GO

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dispersion (1.5 mg/mL) was under ultrasonic dispersion for 2 h, and the mixture was

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fully dispersed. Subsequently, 20 mL AgNO3 (1.2 mg/mL) were slowly added into the

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uniform suspension following with ultrasonic treatment for 1 h. Next, 10 mL of

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triethanolamine (TEOA) was dripped slowly into the mixture and stirred at a

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temperature of 80℃ for 3h. After several cycles of centrifugation and washing, Ag

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doped GO/TNTs composites was obtained. And it was finally diluted to a 0.15% w/w

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(1.5 mg/mL) aqueous suspension for storage and use, denoted Ag/GO/TNTs. The

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preparation of Ag/GO, GO/TNTs and Ag/GO/P25 composites adopted similar method.

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Fabrication of Ag/GO/TNTs composite membranes. Ag/GO/TNTs composite

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membranes were fabricated by vacuum filtration of the as-prepared Ag/GO/TNTs

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suspension through a porous cellulose filter membrane (200 mm in diameter, 0.45 µm

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pore size). Typically, about 8.3 mL Ag/GO/TNTs composites were dispersed in 50 mL

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distilled water under ultrasonic treatment for 10min. Then Ag/GO/TNTs membranes

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were prepared by vacuum filtration of the aforesaid dispersion through a porous

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cellulose filter membrane (200 mm in diameter, 0.45 µm pore size), and it was

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stabilized for 30 min under a pressure of 0.3 MPa by nitrogen filling. The preparation

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of other GO composite membranes adopted similar method.

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Test of membrane flux, rejection and photocatalytic properties. Water flux and

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rejection performance of Ag/GO/TNTs composite membranes were investigated using

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a flat sheet crossflow membrane filtration system as shown in the Fig. S1 similar with

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our previous [21]. It consists of a feed tank, peristaltic pump, flat sheet filter and a

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xenon lamp (with a UV-cutoff filter, λ>400 nm) just above the filter. When studying

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membrane separation performance separately, the xenon lamp was turned off. And

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photocatalysis-membrane filtration integrated process was investigated keeping the

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xenon lamp on. Methylene Blue (MB) solution (10 mg/L) was used to simulated

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dye-containing wastewater, and the dye concentration of the feed was determined by a

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UV-vis spectrometer (752N) at a wavelength of 662 nm. Permeate flux was calculated

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on the basis of permeate volume divided by effective surface area and filtration time,

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unit is L/(m2h).

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When the separate photodegradation activity of as-prepared membranes was studied,

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the membranes were stripped from porous cellulose filter membranes. The

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membranes (8 mg) were put in 100 mL MB solution (10 mg/L), and before UV-light

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irradiation, the suspensions were kept in the dark for 30min to establish an

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adsorption-desorption equilibrium. The 752N UV-vis spectrometer was used to

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analyze the sampled suspension. The changes in maximum absorption versus

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irradiation time (C/C0 versus t) were obtained which reflected the decrease in the MB

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concentration.

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Characterization. X-ray diffraction (XRD) was analyzed using a Japan Rigaku

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D/MAX-2500 instrument with a Cu Ka radiation and a scanning rate of 5℃/min.

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Morphology of the membranes was observed by a scanning electronic microscope

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(Nova, Nano SEM230, USA) and Transmission electron microscopy (JEM-2100F).

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The light absorption abilities of the as-prepared membranes were tested using UV-Vis

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spectrometer (UV-2550, Shimadzu, Japan). The pore structure and specific surface

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area were measured at 77 K with a Quantachrome NOVA 2200e instrument

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(America).

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RESULTS AND DISCUSSION

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Morphologies of the as-prepared membranes were characterized by SEM as shown in

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Fig. 1. As shown in Fig. 1a, GO membranes have a typical corrugated surface

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structure which offers filtering channels for molecule or ions [19]. Compared with the

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surface of pure GO and Ag/GO membranes (Fig. 1b), the surface of Ag/GO/TNTs

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membranes (Fig. 1c) are more rough and have much more corrugations. These

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corrugations could provide more transportation corridors for small molecules. As

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shown in Fig. 1d, the structure of TNTs and lots of highly dispersed nanoparticles are

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observed on the surface of GO sheets. The cross section SEM images of Ag/GO/TNTs

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membranes (12.5 mg) are shown in Fig. 1e and f. It shows a typical thickness of about

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10 µm. Moreover, TNTs are not well dispersed on the surface of GO. Instead, they

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aggregates into porous particles and are clearly encapsulated by GO sheets forming

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layer structure of Ag/GO/TNTs membranes. The pores from porous particles are in

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favour of molecular sieving. The clearer SEM image of porous particles in the

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membrane is shown in Fig. S2. Meanwhile, in order to further study the Ag/GO/TNTs

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membrane structure, the nitrogen adsorption-desorption isotherms and the pore size

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distribution (calculated by BJH model) was provided, and the results are as shown in

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Fig S3. The isotherm of Ag/GO/TNTs membrane is a typical IV-type curve with a

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clear H3-type hysteretic loop, which was characteristic of mesoporous materials

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suggesting that slit-shaped pores in agreement with graphene layers structure and

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non-rigid aggregates of one-dimensional TNTs [33]. The BET specific surface area is

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106.35 m2/g, and pore volume was 0.49 cm3/g. The pore size distribution was

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centered at 4-15 nm.

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In order to study the observed dispersed nanoparticles, the morphologies of GO/TNTs

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and Ag/GO/TNTs membranes were further characterized by TEM. As shown in Fig.

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2a and b, TNTs are chaotically stacked on GO sheets in both the GO/TNTs and

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Ag/GO/TNTs membranes. For Ag/GO/TNTs membranes (as shown in Fig. 2b, c, d),

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Ag nanoparticles (with a uniform size of about 3 nm) are highly dispersed on the

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surface of both GO and TNTs.

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Fig. 1 SEM images of (a) pure GO, (b) Ag/GO and (c~f) Ag/GO/TNTs membranes

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Fig. 2 TEM images of (a) GO/TNTs and (b, c, d) Ag/GO/TNTs membranes

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The XRD patterns of TNTs, Ag/GO and Ag/GO/TNTs composite membranes with

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different mass ratio of GO and TNTs (1:0.5, 1:1, 1:2, 1:3 and 1:4) were shown in Fig.

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3. For TNTs, the characteristic peaks of H2Ti2O5·H2O (47-0124 JCPDS file) are

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observed at 9.78°, 24.06°, 27.82° and 48.02°, respectively. For the Ag/GO composite

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membranes, there are strong characteristic peaks of metallic Ag at 38.11°, 44.30°,

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32.23°, 38.70° and 40.78°. However, there are no observable peaks of graphene oxide,

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which is probably due to the partial reduction of GO by TEOA [34]. As for

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Ag/GO/TNTs composite membranes, the characteristic peaks of both metallic Ag and

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H2Ti2O5·H2O can be observed. This demonstrates the highly dispersed nanoparticles

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on GO and TNTs are metallic Ag. Moreover, with the increased content of TNTs, the

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peak intensity of TNTs becomes stronger, while the peak intensity of Ag is weakened.

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Therefore, combined with the results of SEM and TEM, highly dispersed Ag

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nanoparticles could be obtained by a simple procedure which Ag+ first was adsorbed

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on the active sites of GO/TNTs and then grew up in situ.

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Fig.3 XRD patterns of TNTs, Ag/GO and Ag/GO/TNTs composite membranes with different mass

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ratio of GO and TNTs (1:0.5, 1:1, 1:2, 1:3 and 1:4)

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The optical absorbance spectra obtained by the diffuse reflections of TNTs, GO/TNTs

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and Ag/GO/TNTs are shown in Fig. 4. The absorption edge and bandgap of TNTs are

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375 nm and 3.1 eV, which are close to TiO2 [31]. However, an obvious red shift of the

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absorption edge and decreased bandgap are observed for GO/TNTs. This is mainly

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caused by graphene which could reduce the bandgap of TNTs due to the direct

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interaction between C and Ti atoms on TNTs surface during solvothermal treatment

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[35]. And after Ag doping, a red shift of the absorption edge and decreased bandgap

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are also observed for Ag/GO/TNTs. The improved visible light absorption abilities are

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potent to explain for the enhanced visible light photocatalytic properties of the

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Ag/GO/TNTs composite, which will be discussed later.

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Fig.4 (a) The UV-Vis DRS spectra of TNTs, GO/TNTs and Ag/GO/TNTs membranes, (b)

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corresponding bandgaps

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The photocatalytic activities of TNTs, GO/TNTs, Ag/GO/P25 and Ag/GO/TNTs were

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studied via MB degradation under visible light. The results are shown in Fig. 5. In

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30min dark condition, MB molecules were adsorbed onto all samples. Obviously, GO

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shows strong adsorption ability for MB, but almost has no catalytic activity. However,

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the strong adsorption ability easily leads to membrane fouling resulting in a

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significant decline in membrane flux, and the contaminant is difficult to be eliminated

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via regular cleaning method due to strong interactions. On the other hand, TNTs also

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has impressive adsorption ability for MB due to its high specific surface area and

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abundant hydroxyl group. In addition, it has good photocatalytic degradation ability

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for MB. It reveals that membrane fouling could be alleviated by photocatalysis. As a

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consequence, Ag/GO/TNTs membranes exhibit a better adsorption and photocatalytic

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ability than Ag/GO/P25. 90% of MB could be degraded after 120 min irradiation. In

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order to distinguish the catalytic effects of different materials, the kinetic degradation

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curves simulated by first-order degradation equation were obtained as shown in Fig.

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S4. The rate constants of Ag/GO/TNTs, GO/TNTs and Ag/GO/P25 membranes are

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calculated to be 0.74 h 1, 0.23 h 1 and 0.31 h 1, respectively. Obviously, Ag loading and

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TNTs benefit the enhancement of photocatalytic dye degradation.

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Beyond that, the photocatalytic activities of Ag/GO/TNTs membranes with different

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ratio of GO: TNTs (1: 0, 1: 0.5, 1: 1, 1: 2, 1: 3, 1: 4) and Ag content (0%, 1.5%, 3%,

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6%, 7%) were also investigated to optimize preparation parameters for obtaining the

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Ag/GO/TNTs membrane with improved photocatalytic ability. As shown in Fig. 6a,

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with increase of TNTs content in the composite membranes, the removal ability of

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MB increased at first and then decreased. And the Ag/GO/TNTs membranes show

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higher removal ability when the ratio of GO: TNTs reaches to 1: 3 via

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adsorption-photocatalysis synergistic effect. It could be interpreted by the variation of

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adsorption abilities of Ag/GO/TNTs membranes. With the rising TNTs content,

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plentiful corrugations and bulges on the surface of Ag/GO/TNTs membranes as shown

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in Fig. S5 and they are formed by the intercalation of TNTs as shown in Fig. S6, and

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the pores from porous TNTs particles benefit to adsorption of MB. However, because

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of GO with a stronger adsorption ability than TNTs (Fig. 5), excessive content of

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TNTs is unfavorable to increase the adsorption ability of Ag/GO/TNTs membranes.

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On the other hand, excessive amounts of Ag are also not in favor of MB removal as

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shown in Fig. 6b. And the Ag/GO/TNTs membranes with Ag content of 6% show

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higher removal ability. It is mainly because the excessive metal loading leads to the

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limitation of the amount of light reaching to the surface of the catalyst, and therefore







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results in decreasing photogenerated charge carriers [36].

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Fig. 5 Photocatalytic activities of GO, TNTs, GO/TNTs and Ag/GO/TNTs for degradation of MB

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under visible light illumination

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Fig. 6 The photocatalytic activities of Ag/GO/TNTs membranes with different ratio of (a) GO:

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TNTs (1: 0, 1: 0.5, 1: 1, 1: 2, 1: 3, 1: 4) and (b) Ag content (0%, 1.5%, 3%, 6%, 7%) for

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degradation of MB under visible light.

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In order to investigate the photocatalytic mechanism of Ag/GO/TNTs for degradation

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of MB, 1mL tert-butyl alcohol (TBA) and TEOA which act as radical and hole

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scavenger were added into photocatalytic reaction system, respectively. The

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photocatalytic activities are as shown in Fig. S7. In presence of TBA, the

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photocatalytic activity of Ag/GO/TNTs significantly decreases, while it almost

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remains invariable with addition of TEOA. It indicates radical plays an important role

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on photodegraded MB molecule for Ag/GO/TNTs catalyst. Here, a possible

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photocatalytic mechanism is proposed on the basis of the literature [30, 31], as shown

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in Fig. 7. Due to Ag doping and GO composite, Ag/GO/TNTs could adsorb visible

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light and produce photoinduced electrons. On account of high electronic mobility of

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graphene, these photoinduced electrons could easily transfer from TNTs and Ag to

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GO sheets. It could effectively suppress the recombination of photoinduced electrons

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and holes, thus enhance the photocatalytic activity of Ag/GO/TNTs. Then, these

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electrons could react with adsorbed oxidants to produce reactive oxygen radicals (•O2

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molecule could be photodegraded by these active radicals eventually.

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), while the holes react with H2O/OH to generate hydroxyl radicals (•OH). MB

Fig. 7 Schematic of photocatalytic mechanism of Ag/GO/TNTs membranes under visible light

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The compressive strength of Ag/GO/TNTs membranes was further evaluated via

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water fluxes variation with 10 cycles changed pressure (0.01-0.07 MPa). The results

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are as shown in Fig. 8. The water fluxes of Ag/GO/TNTs membranes were improved

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with the increasing pressure from 0.01-0.07 MPa, and it presented a fine linear

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relationship and even after 10 cycles. It indicates the pore of Ag/GO/TNTs

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membranes was without severe compressive deformation due to the influence of

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higher pressure according to Hagen-Poiseuille equation [37]. The results reveal

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Ag/GO/TNTs membranes have a good compressive strength at a range of 0.01-0.07

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MPa.

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Meanwhile, the acid and alkali resistance of Ag/GO/TNTs membranes were

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researched by a soaked process in HCl and NaOH solution with a concentration of 0.1

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mol/L respectively as shown in Fig. 9. The results show free standing Ag/GO/TNTs

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membranes have no any disintegration, and they are exhibit high acid-alkali resistance

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stability within even for one month. Besides, Ag/GO/TNTs membranes have good

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transparency which is beneficial to ensure their photocatalysis reaction efficiency. In

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order to further confirm their acid-alkali resistance, the membranes were used to filter

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0.1 mol/L HCl and NaOH solution for 6h respectively, and the fluxes were tested. The

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results are as shown in Fig. S8. It can be seen the fluxes of HCl or NaOH solution

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have no significant change indicating that the membrane structure and pores haven’t

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been destroyed seriously. It is mainly due to acid-alkali resistance of carbon based

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materials.

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Fig. 8 The water fluxes of Ag/GO/TNTs membranes with 10 cycles changed pressure (0.01-0.07

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MPa)

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Fig. 9 Ag/GO/TNTs membranes were soaked at 0.1 mol/L HCl or NaOH solution with different

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time

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Photocatalysis-membrane filtration integrated process of as-prepared Ag/GO/TNTs

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membranes with GO and TNT ratio at 1: 3 and Ag content of 6% was investigated by

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a flat-sheet crossflow filtration unit, and the fluxes and rejection rates for MB solution

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were tested. Meanwhile the antifouling ability of Ag/GO/TNTs membranes was

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evaluated from the flux change with and without visible light irradiation, and the

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results are shown in Fig. 10. As shown in Fig. 10a, the fluxes dramatically decreased

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for the Ag/GO/TNTs membranes with and without visible light due to membrane

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fouling. Without light irradiation, the water fluxes decreased quickly from 70.2 to

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20.0 L/m2h in the first 100 min. And in this period, the adsorption of the membrane

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for MB was main filtration resistance which caused membrane fouling. Then the

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fluxes decreased slowly to equilibrium (17.8 L/m2h) until 6h. As comparison, when

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the membrane separation process was operated under visible light irradiation, the

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fluxes decreased slower and maintained at a higher equilibrium value (34.7 L/m2h).

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The fluxes of GO membrane for MB solution with and without visible light were also

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shown in Fig. S9. It is found that the initial flux of GO membrane is less than

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Ag/GO/TNTs membrane. In addition, visible light has no effect on the flux

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recoverability of GO membrane. On the other hand, the results of rejection rates of

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Ag/GO/TNTs membrane for MB are as shown in Fig. 10b. For membrane separation

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process with visible light, MB removal rate decreased until 64% due to saturation of

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adsorption capacity and the process of membrane separation. However, it’s higher

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than that without light irradiation. This improvement could be attributed to the

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synergetic function of adsorption and photocatalysis in Ag/GO/TNTs membranes. In

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order to intuitively investigate anti-fouling ability of Ag/GO/TNTs membrane under

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visible light, contaminated membranes under 6h cross-flow filtration were cut into a

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piece with diameter of 4 cm and put in a watchglasses with water under visible light

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irradiation. The results are as shown in Fig. S10. Obviously, the color of MB

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contaminated membrane is dark blue. Then the color has bleach out with a period of

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visible light irradiation, and large amounts of bubbles are observed at the same time.

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It indicates MB molecules on surface of membrane are photodegraded under light

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irradiation. In this sense, visible light irradiation could effectively alleviate the

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membrane fouling via photocatalysis during membrane separation process.

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Fig. 10 (a) The fluxes and (b) the rejection rates of Ag/GO/TNTs membranes through cross-flow

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filtration with and without visible light illumination

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CONCLUSIONS

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Ag doped GO/TNT have been successfully synthesized by a single step solvothermal

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reaction, and Ag nanoparticles with a size of about 3 nm were obtained and highly

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dispersed on the surface of GO and TNTs. As-prepared Ag/GO/TNT membranes with

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visible light photocatalytic ability were used in crossflow filtration process. They

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exhibited reasonable ability on photocatalytic degradation of Methylene Blue under

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visible light, and the membrane fouling could be effectively alleviated via integrating

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visible photocatalytic-membrane filtration. In addition, the as-prepared Ag/GO/TNTs

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membranes possess high acid-alkali resistance stability and good compressive

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strength. Our research could provide a valuable reference value for synthesis of highly

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dispersed nanoparticles and using Ag/GO/TNTs membranes to alleviate membrane

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fouling under visible light.

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SUPPORTING INFORMATION

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The Supporting Information is available free of charge on the ACS Publications

4

website.

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Schematic of the membrane filtration system, SEM images and nitrogen

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adsorption-desorption results of various samples, the kinetic degradation curves, the

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photocatalytic activities, the membrane fluxes under various conditions, the photos of

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contaminated membranes under visible light with different time.

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ACKNOWLEDGEMENTS

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Gonggang Liu received funding from PhD research startup foundation of Central

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South University of Forestry and Technology (104-0456). Kai Han received funding

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from the National Natural Science Foundation of China (No. 21706292), China

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Postdoctoral Science Foundation (2015M582343, 2016T90758) and Hunan Provincial

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Natural Science Foundation of China (No. 2017JJ3376). Yonghua Zhou received

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funding from the National Natural Science Foundation of China (NO. 21676303).

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Jinbo Hu received funding from Hunan Provincial Natural Science Foundation of

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China (No. 2017JJ1038).

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REFERENCES

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GRAPHIC ABSTRACT: Ag doped GO/Titanate nanotubes membranes endowing GO

membranes with enhanced visible light degradation ability could alleviate their membrane fouling problem for long term water treatment and achieve sustainable use.

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graphical abstract 87x32mm (600 x 600 DPI)

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