Regenerable Polyelectrolyte Membrane for Ultimate Fouling Control in

Feb 16, 2017 - fresh one. A promising candidate membrane material for such ultimate fouling control is the layer-by-layer (LbL) assembled polyelectrol...
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Regenerable Polyelectrolyte Membrane for Ultimate Fouling Control in Forward Osmosis Yan Kang, Sunxiang Zheng, Casey Finnerty, Michael J. Lee, and Baoxia Mi Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.6b05665 • Publication Date (Web): 16 Feb 2017 Downloaded from http://pubs.acs.org on February 24, 2017

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Regenerable Polyelectrolyte Membrane for Ultimate Fouling

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Control in Forward Osmosis

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Second revision submitted to

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Environmental Science & Technology

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February 14, 2017

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Yan Kanga, Sunxiang Zhengb, Casey Finnertyb, Michael J. Leea, Baoxia Mib*

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a

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Department of Civil and Environmental Engineering

University of Maryland, College Park, Maryland 20742, United States

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b

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Department of Civil and Environmental Engineering

University of California, Berkeley, California 94720, United States

16 17 18 19 *

The author to whom correspondence should be addressed. fax: +1-510-643-5264

e-mail: [email protected]; tel.: +1-510-664-7446,

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ABSTRACT

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This study demonstrated the feasibility of using regenerable polyelectrolyte membranes to

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ultimately control the irreversible membrane fouling in a forward osmosis (FO) process.

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regenerable membrane was fabricated by assembling multiple polyethyleneimine (PEI) and

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poly(acrylic acid) (PAA) bilayers on a polydopamine-functionalized polysulfone support.

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resulting membrane exhibited higher water flux and lower solute flux in FO mode (with the

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active layer facing feed solution) than in PRO mode (with the active layer facing draw solution)

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using trisodium citrate as draw solution, most likely due to the unique swelling behavior of the

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polyelectrolyte membrane.

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existing PEI-PAA bilayers using strong acid and then reassembling fresh PEI-PAA bilayers on

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the membrane support.

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PEI layer and some realigned PAA remained on the membrane support, acting as a beneficial

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barrier that prevented the acid-foulant mixture from penetrating into the porous support during

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acid treatment.

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the original membrane regardless of alginate fouling, suggesting an ultimate solution to

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eliminating the irreversible membrane fouling in an FO process.

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the typical membrane cleaning protocol, in-situ membrane regeneration is not expected to

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noticeably increase the membrane operational burden but can satisfactorily avoid the expensive

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replacement of the entire membrane module after irreversible fouling, thereby hopefully

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reducing the overall cost of the membrane-based water treatment system.

The

The

Membrane regeneration was conducted by first dissembling the

It was found that, after the acid treatment, the first covalently bonded

Water and solute flux of the regenerated membrane was very similar to that of

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With a procedure similar to

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Table of Contents (TOC) and Abstract Art

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INTRODUCTION

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Membrane processes, including the traditional nanofiltration (NF) and reverse osmosis (RO) as

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well as the emerging forward osmosis (FO), are among the most effective approaches to treating

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water, especially that from non-traditional sources.1, 2 The semipermeable membranes commonly

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used in these processes are mostly of thin-film composite polyamide and cellulose triacetate

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types due to their good separation capability and reasonable chemical resistance.3-5

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membrane fouling aggravates the long-term membrane separation efficiency

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significantly increases the capital costs associated with fouling-preventive pretreatment as well

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as membrane cleaning and replacement.

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FO membrane alleviates its fouling problem to some extent,10-13 irreversible fouling (i.e.,

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accumulation of foulants that cannot be removed from the active layer by physical cleaning) still

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poses a major obstacle to the sustainable application of FO technology.

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6-9

However,

and as a result

Although the lack of fouling layer compaction for an

Membrane surface characteristics (e.g., hydrophilicity, charge, and chemistry) play a key

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role in the foulant deposition and fouling layer formation.

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characteristics via appropriate surface modification provides an effective route to improving the

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membrane resistance to various types of fouling.14, 15 Typical surface modification strategies

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include decreasing membrane surface roughness, increasing membrane surface hydrophilicity,

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and introducing anti-adhesive monomers, polymers, or particles onto membrane surface.14-19

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Recent advances in nanotechnology, polymer science, and biomimetic surface engineering have

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greatly accelerated the development of antifouling strategies for membrane surface modification,

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covering the following emerging areas: (1) bio-inspired engineered topography, where various

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biomimetic surface patterns are designed to deter fouling;20 (2) nano-structured amphiphilic

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Hence, optimizing these

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coating, where hydrophobic and hydrophilic segments are combined to create a nano-scaled,

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chemically heterogeneous surface to repel foulants;21-23 (3) super-hydrophilic zwitterionic

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polymerization, where an electrostatically induced strong zwitterionic hydration layer created by

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zwitterions effectively repels the attachment of proteins and cells;

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strategies leading to, for example, phase-segregating copolymers,26 super-hydrophobic surfaces,

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24, 25

and (4) many other

and nanocomposite materials. 28-30

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Although the above antifouling strategies have proven effective for controlling

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individual types of membrane fouling, they usually become inadequate when various types of

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foulants are present simultaneously and may even interact with one another to further complicate

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the fouling problem.31 Moreover, after an extended period of operation, irreversible membrane

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fouling may eventually occur but cannot be effectively mitigated using the membrane cleaning

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protocols, causing the costly replacement of membrane modules.32 Therefore, an ultimate

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approach to irreversible fouling control is to make a new type of antifouling membrane that

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allows for the releasing of the severely fouled membrane active layer and regeneration of a fresh

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one.

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A promising candidate membrane material for such ultimate fouling control is the layer-

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by-layer (LbL) assembled polyelectrolyte.

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been developed by adjusting fabrication conditions, altering surface charge and functionality,

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and/or selecting different polyelectrolyte species.33-37 These membranes showed satisfactory

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separation

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polyelectrolyte layer can be released under controlled conditions,41, 42 a unique property that

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enables the possibility of (i) removing the polyelectrolyte active layer of the membrane as a

performance

Various polyelectrolyte membranes have recently

under diverse circumstances.36,

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38-40

More important,

the

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sacrificial layer along with the irreversible foulants and then (ii) assembling in-situ a new

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polyelectrolyte layer to restore the membrane functionality.

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polyelectrolytes were used in the synthesis of regenerable NF membranes, and strong acids or

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bases were employed to detach the polyelectrolyte active layer from these membranes.43-45

In previous studies, weak

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However, the fouling behavior of polyelectrolyte membranes or their regenerability for

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fouling control in an osmotically driven FO process, for which the fouling behavior and

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mechanisms can be considerably different from those for a pressure-driven NF process,46 has not

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been investigated.

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nor the fouling layer formed on top would experience hydraulic pressure-induced compression in

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an FO process,11 thus potentially resulting in different separation behavior and regeneration

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capability.

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by electrostatic interaction, which could be significantly affected by the high ionic strength of the

For example, unlike in an NF/RO process, neither the polyelectrolyte layer

In addition, the structure and integrity of a polyelectrolyte membrane are maintained

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draw solution used in an FO process.

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examine the feasibility of developing a regenerable polyelectrolyte membrane for FO

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applications and in the meantime to fundamentally understand the corresponding mechanisms.

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Therefore, research is definitely needed to thoroughly

This paper reports the regenerability of a polyelectrolyte membrane in the FO process,

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without and with alginate fouling, respectively.

This membrane was fabricated by the LbL

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assembly of a polyelectrolyte layer on top of a porous support.

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polyelectrolyte membrane were measured in FO and pressure-retarded osmosis (PRO) modes,

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respectively, and the effect of polyelectrolyte layer thickness on such performances was

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examined.

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and deposit a fresh one.

Water and solute fluxes of the

Membrane regeneration was carried out to release the existing polyelectrolyte layer The structure and properties of polyelectrolyte layers before, during,

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and after membrane regeneration were characterized.

The effect of alginate fouling on

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membrane regeneration was investigated.

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MATERIALS AND METHODS

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Membrane Synthesis.

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purchased from Sigma-Aldrich (St. Louis, MO) and were used as received.

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support was made of polysulfone (PSf, with a molecular weight Mw of 22,000) using a

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conventional phase-inversion method with polyvinylpyrrolidone (PVP, Mw 55,000) as a pore-

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forming agent.

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PSf/PVP/NMP weight ratio of 16/4/80, and kept in vacuum for 48 h. Next, the solution was

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cast on a glass plate to form a 125-µm-thick film using a stainless steel casting knife, and the

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glass plate was immediately immersed into a water bath for 10 min.

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support was then peeled off from the glass plate and transferred to another water bath, which was

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refreshed several times to rinse out any residual solvent.

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a refrigerator and ready for use.

Unless specified otherwise, all materials and chemicals were The membrane

PSf and PVP were fully dissolved in N-Methyl-2-pyrrolidone (NMP), with a

The thus formed PSf

Finally, the PSf support was stored in

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To synthesize the polyelectrolyte membrane, the PSf support was first soaked in a

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freshly prepared dopamine solution (2 mg/mL dopamine in 10mM Tris-HCl, pH 8.5) for 5 h.

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Then, the polydopamine-coated PSf was alternately immersed in 1 g/L polyethyleneimine (PEI,

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Mw 750,000) and 1 g/L poly(acrylic acid) (PAA, Mw 450,000) solutions for a specified number of

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cycles.

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Deionized (DI) water was used to rinse the membrane between any two dipping steps.

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LbL assembly process created the polyelectrolyte membrane with a desired number of PEI-PAA

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bilayers on the polydopamine-coated PSf support.

Each dipping step lasted 20 min except that the first PEI dipping step took 1 h.

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Membrane Fouling, Regeneration, and Performance Tests. The membrane fouling

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tests used a mixture of 200 mg/L alginate and feed solution that contained 50 mM NaCl and 0.5

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mM CaCl2.7

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sufficient deposition of foulants, followed by the disassembly of the fouled polyelectrolyte layer,

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regeneration of a fresh polyelectrolyte layer, and evaluation of the membrane performance.

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tests were repeated multiple times to ensure the reliability of data.

Each fouling test typically lasted 18 h with about 2 L of filtrate to allow for

The

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To disassemble the polyelectrolyte layer, the membrane was immersed in HCl solution

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(pH 1) for 30 min, rinsed with DI water for several times, and then stabilized in DI water for 1 h.

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The effectiveness of disassembly by HCl solution at higher pH (2 to 3) was also evaluated.

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Regeneration of the fresh polyelectrolyte layer followed a procedure similar to that for

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membrane synthesis — the acid-treated membrane was alternately soaked in the PEI and PAA

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solutions to deposit a desired number of new PEI-PAA bilayers.

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Membrane performances before and after the regeneration of the fresh polyelectrolyte

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layer were evaluated using a lab-scale FO system.47 The membrane was installed in a cross-flow

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cell at a constant flow rate of 8.5 cm/s and then tested in FO mode (with the membrane top

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surface facing feed solution) and PRO mode (with the membrane top surface facing draw

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solution), respectively.

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used as a draw solution.

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reached a steady state (typically in 30 min) was monitored for 2 h using a conductivity meter

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(Accumet Excel XL30, Thermo Scientific, Marietta, OH).

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concentrations (1 to 100 mM) of TSC were first used to establish a standard curve, which was

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then employed to convert the conductivity measurements to solute concentrations so that the

0.5 M trisodium citrate (TSC, Fisher Scientific, Pittsburgh, PA) was The change in the conductivity of feed solution after the water flux

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Solutions with known

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reverse solute flux could be calculated.

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Membrane Characterization.

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Fourier transform infrared (FTIR) spectroscopy (Nicolet 6700, Thermo Scientific, Marietta, OH),

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scanning electron microscopy (SEM, SU-70, Hitachi High Technologies America, Gaithersburg,

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MD), and quartz crystal microbalance with dissipation (QCM-D, Q-sense E4 system, Sweden).

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For the FTIR and SEM analyses, the samples were dried overnight at room temperature and

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placed in an oven at 60 °C for 30 min to remove moisture content before characterization.

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SEM samples were sputtered with a thin (~2 nm) layer of gold nanoparticles on top to eliminate

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the electron-charging effect.

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procedure as that for membrane synthesis.

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used to monitor the changes in vibration frequency and energy dissipation, which were modeled

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using the Q-Tools software (Q-sense, Sweden) to calculate the amount of mass deposited on or

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released from the sensor surface.

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Lincoln, NE) was coupled with the QCM-D to measure the thickness of the polyelectrolyte

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layers deposited on the QCM-D sensor.

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JEM 2100, Peabody, MA) was also employed to examine the structural change in the

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polyelectrolyte layer due to acid treatment.

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PEI and PAA solutions following the steps for membrane synthesis excluding the step of

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polydopamine functionalization.

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RESULTS AND DISCUSSION

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LbL Membrane Synthesis.

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deposited on the PSf support, respectively.

The polyelectrolyte membrane was characterized by the

The

The QCM-D sensors were prepared using the same LbL assembly A flow chamber at a flow rate of 0.1 mL/min was

An ellipsometer (FS-1 Multi-wavelength, Film Sense,

The transmission electron microscopy (TEM, JEOL

A TEM copper grid was alternately dipped into the

Different numbers (2, 4, and 6) of PEI-PAA bilayers were The top surface (Figure 1(a)) of the PSf support,

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facing the ambient water when formed during phase inversion synthesis, was denser (i.e., less

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porous) than the bottom surface (Figure 1(b)), which was attached to the glass plate during the

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support synthesis.

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surface roughness of PSf (Figure 1(c)), the subsequent polyelectrolyte deposition, either with

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only two PEI-PAA bilayers (Figure 1(d-e)) or more bilayers (Figure S1), created relatively

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smooth and featureless surfaces .

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Although the pretreatment by polydopamine significantly increased the top

The successful LbL deposition of PEI-PAA bilayers was also confirmed by FTIR spectra

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(Figure 1(f)).

Compared with the control PSf support, the polyelectrolyte membranes showed a

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small characteristic peak of carboxylates near 1700 cm-1.

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increased, two new broad peaks were predominant at around 1550 cm-1 and 1410 cm-1,

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representing the asymmetric carboxylate stretching due to PEI-PAA binding.48

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the characteristic peaks of PSf in the range of 1250 cm-1 to 700 cm-1 became less intensive as the

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number of PEI-PAA bilayers increased.

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As the number of PEI-PAA bilayers

In the meantime,

FIGURE 1

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Membrane Transport Behavior.

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membrane using 0.5 M TSC as draw solution. The water flux and reverse solute flux were

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measured in FO and PRO modes, respectively.

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modes, as the number of PEI-PAA bilayers increased (i.e., the membrane active layer became

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thicker), the membrane resistance to water permeation was enhanced and thus the water flux

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decreased.

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transport, the reverse solute flux may not necessarily decrease in inverse proportion to the active

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layer thickness.

The polyelectrolyte membrane was tested as an FO

As shown in Figure 2(a), in both FO and PRO

In contrast, although a thicker membrane also generates a higher resistance to solute

As shown in Figure 2(b), although the thinnest 2-bilayer membrane had the

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highest reverse solute flux, the 6-bilayer membrane turned out to have a slightly higher solute

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flux than the 4-bilayer membrane.

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membrane helps reduce the resistance to solute transport, thereby counteracting with the original

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resistance increase for the thicker membrane.

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was compared in Fig. 2 (a-b) with that of a citrate triacetate (CTA) FO membrane commercially

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available from Hydration Technology Innovations (Albany, OR).

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bilayer membrane exhibited high water flux of ~22 L/m2/h (more than three times that of the

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CTA membrane) and reasonable reverse solute flux of ~0.06 mole/m2/h (about twice that of the

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CTA membrane), while both 4 and 6-bilayer membranes demonstrated moderately higher water

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flux but slower solute flux than the CTA membrane. Therefore, the 2-bilayer membrane was

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selected as a representative polyelectrolyte membrane for the subsequent regeneration tests.

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This is because the lowered water flux of a thicker

The performance of PEI-PAA bilayer membranes

Tested in FO mode, the 2-

It is interesting to observe in Figure 2(a) that the water flux of a polyelectrolyte

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membrane in PRO mode was significantly lower than that in FO mode.

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dramatically differs from the behavior of a traditional FO membrane, which typically has a lower

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water flux in FO mode than in PRO mode due to the membrane’s asymmetric structure that leads

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to a lesser degree of internal concentration polarization in PRO mode.49, 50 Such a unique flux

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behavior of the polyelectrolyte membrane was most likely attributed to the swelling of the

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polyelectrolyte layer in a high ionic strength solution (0.5 M TSC), and this active layer could be

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further loosened under the impact of water flow.

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has a dense active layer on top of its support only, both top and bottom surfaces of the

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asymmetric PSf support in this study were coated with polyelectrolyte layers, with the top layer

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being denser and thicker than the bottom one.

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contributed to solute rejection because relatively large pores (> 400 nm) of the PSf support were

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This observation

In contrast to a traditional FO membrane that

The bottom polyelectrolyte layer unlikely

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not fully covered by the polyelectrolyte layer (Figure 1(e)).

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illustrated in Figure 2(c), when the polyelectrolyte membrane was operated in FO mode, its top

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surface facing the feed solution (with low ionic strength) was relatively dense and acted as an

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effective osmotic barrier to generate high water flux and low reverse solute flux.

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when the membrane was operated in PRO mode, its top polyelectrolyte layer swelled due to

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exposure to 0.5 M TSC solution (with high ionic strength) and hence became less effective as an

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osmotic barrier, leading to lower water flux and higher solute flux.

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the swelling of a 2-bilayer polyelectrolyte film under high ionic strength was confirmed by the

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change in the film thickness, which increased from 23 nm in DI water to 45 nm in 0.5 M TSC

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solution.

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Therefore, as schematically

In comparison,

As shown in Figure 2(d),

FIGURE 2

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Acid Treatment and Regeneration of Membrane.

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membrane, the first step is to dissemble the existing polyelectrolyte layer from the original

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membrane so that a fresh layer can be deposited.

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disassembly approach is to treat the polyelectrolyte membrane with a strong acid that can the

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protonate carboxylate groups and neutralize the negative charge of PAA, thereby destroying the

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electrostatic binding between PEI and PAA.

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a fresh PSf support (Figure S2) with the 2-bilayer membrane (Figure 3(b, d)) and 6-bilayer

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membrane (Figure 3(c, e)) before and after pH 1 HCl treatment, respectively, demonstrated the

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effectiveness in detaching the existing PEI-PAA bilayers by strong acid.

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residual polyelectrolytes could still remain after acid treatment, especially for membranes with a

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relatively thick polyelectrolyte layer.

To regenerate a polyelectrolyte

As illustrated in Figure 3(a), an effective

Comparison of the cross-sectional SEM images of

Note that some

For example, acid treatment reduced the thickness of the

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polyelectrolyte layer of the 6-bilayer membrane from ~2 µm (Figure 3(c)) to ~0.5 µm (Figure

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3(e)).

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FIGURE 3

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In order to more accurately characterize the membrane regeneration, QCM-D was

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employed to monitor the mass change during the LbL assembly and acid treatment of the 2-

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bilayer membrane.

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membrane pretreatment and then deposited with two PEI-PAA bilayers.

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3(f) that the mass of the second PEI-PAA bilayer was much larger than that of the first bilayer.

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This is because the first PEI layer was covalently bonded to polydopamine through nucleophilic

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addition,51, 52 resulting in a low degree of PEI attachment.

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bilayer increased the number of charged sites on the exposed membrane surface, attracting more

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polyelectrolyte and thus increasing the mass for the subsequent bilayer deposition.

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The QCM-D sensor was first coated with polydopamine to simulate the It is observed in Figure

Besides, deposition of a PEI-PAA

As shown in Figure 3(g), the mass changes associated with the process of regenerating

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the 2-bilayer thin film are normalized by its original mass.

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treatment removed about 70% of the total mass of the 2-bilayer thin film.

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observed in Figure 3(f), the masses of the first and second bilayers are approximately equal to 30%

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and 70%, respectively, of the total mass, indicating that acid treatment mainly removed the outer

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second bilayer while leaving the inner first bilayer intact.

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treatment, only one new bilayer was deposited on the QCM-D sensor in order to maintain a

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relatively constant mass of the 2-bilayer membrane.

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regeneration cycle, the normalized mass of the regenerated membrane is close to unity,

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indicating that its thickness was similar to that of the original 2-bilayer membrane.

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It is observed that the first acid Note that, as

For this reason, after each acid

Figure 3(g) shows that, after each

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The nearly 30% residual mass after each acid treatment, as observed in Figure 3(g), was

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most likely associated with the first PEI layer, which was covalently attached to polydopamine,

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as well as some undetached PAA due to the partial protonation of its carboxylate groups.

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is because, although the theoretical pKa of carboxylate groups in PAA is around 4.5 and thus

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would be fully protonated at pH 1, the effective pKa can be very different when these functional

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groups are localized and constrained instead of moving freely on a surface.53

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much lower than 4.5 was confirmed by the non-effective acid treatment at higher pH (Figure S3)

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— the fact that polyelectrolyte layers were almost unaffected by acid treatment at pH 2 to 3

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indicated an effective pKa of less than 2.

This

An effective pKa

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The residual polyelectrolyte layer after acid treatment was actually beneficial for the

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membrane regeneration because it helped prevent the acid-foulant mixture from penetrating into

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the membrane support during the acid treatment.

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attached PEI layer unlikely changes during regeneration, the amount of residual mass after each

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regeneration cycle mainly depends on the effectiveness of acid treatment in breaking the

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electrostatic interactions between polyelectrolytes.

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membrane before and after acid treatment (Figure S4) are similar, indicating that no chemical

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reaction or change in the polyelectrolyte chemistry was introduced by acid treatment.

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Since the mass of the first chemically

Besides, the FTIR spectra of the 2-bilayer

TEM characterization as shown in Figure 4 reveals that acid treatment caused some

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structural changes in the residual polyelectrolyte layer.

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exhibited a smooth, featureless surface, as similarly observed in the SEM image (Figure 1(d)).

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After the pH 1 acid treatment, the residual polyelectrolyte layer led to a rougher surface (Figure

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4(d)) with aligned features at a few spots (Figure 4(e)), indicating that the acid treatment did not

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The as-prepared 2-bilayer sample

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evenly or entirely dissemble the existing polyelectrolyte layer.

Besides, the TEM diffraction

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patterns show that the acid-treated sample had a bright ring compared with the as-prepared

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sample, indicating the existence of some aligned polyelectrolytes.

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likely caused by the realignment of partially protonated PAA as pH decreased. Note that a

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similar pH effect on the structure of polyelectrolyte layers was also reported in the literature.54

Such a structural change was

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The TEM-EDX analysis (Figure S5) showed an almost complete PEI removal by acid

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treatment, as no nitrogen (N) peak was detected for the acid-treated 2-bilayer sample. Note that

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because the TEM sample holder was not pre-treated with polydopamine, PEI was not covalently

295

attached to the TEM sample holder.

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electrostatically deposited PEI and only left the first layer of covalently bonded PEI and some

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partially protonated, well aligned PAA in the residual polyelectrolyte layer.

In summary, acid treatment was able to remove almost all

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FIGURE 4

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Membrane Performance in FO Process. The performances of both the original 2-bilayer

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membrane and the membrane after each cycle of acid treatment and regeneration were tested in

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FO mode.

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water flux, obviously because the decrease in the polyelectrolyte layer thickness lowered the

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water resistance. Note that the water flux after each membrane regeneration was lower than

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that of the original membrane due to the existence of a residual polyelectrolyte layer (after acid

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treatment) that increased the water resistance.

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general not significantly affected by acid treatment or regeneration, indicating the residual

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polyelectrolyte layer, mainly composed of the first PEI-PAA bilayer based on mass analysis, was

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also a somewhat effective solute barrier.

Figure 5(a) shows that the acid treatment in each cycle increased the membrane

As shown in Figure 5(b), the solute flux was in

However, the solute flux dramatically increased after

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the third acid treatment.

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after each acid treatment (Figure 5(a)), is consistent with our previous understanding that acid

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treatment alone did not evenly or entirely dissemble the existing polyelectrolyte layer.

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demonstrated by the TEM image in Figure 4(d), the acid treatment resulted in a heterogeneous

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structure with realignment of residual PAA, thus potentially leading to defects that result in

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increased solute passage. Although such defects are fully sealed by the subsequent bilayer

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deposition in the next regeneration cycle, it is predicted that the efficiency of polyelectrolyte

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layer removal and regeneration could be further improved by employing useful membrane

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cleaning strategies such as surfactant and back wash.

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This observation, along with the noticeable variations in water flux

As

FIGURE 5

The regenerability of the polyelectrolyte membrane fouled by alginate was also tested in

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the FO membrane system.

The flux decline curves of the original and regenerated membranes

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obtained from the alginate fouling experiments are shown in Figure 5(c).

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water flux of the original membrane declined by more than 30% due to alginate fouling,

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indicating a thick fouling layer was formed on the membrane surface.

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treatment and regeneration, the regenerated membrane regained an initial water flux that was

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almost the same as that of the original clean membrane.

It is observed that

After each cycle of acid

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Such effective membrane regeneration after significant fouling offers a great opportunity

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to ultimately control the irreversible membrane fouling, a long-standing problem that

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considerably deteriorates membrane performance and shortens membrane lifetime.

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conventional fouling control procedures such as physical and chemical cleaning for which the

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fouling-control effectiveness depends on foulant types and attachment mechanisms, membrane

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regeneration breaks the electrostatic interactions between the polyelectrolyte layers and thus

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removes the bilayers together with various foreign substances attached to them, including

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irreversible foulants.

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that is not affected by the type of foulants or level of their attachment to the membrane.

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the procedure for dissembling and regenerating the polyelectrolyte layer of the present

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membrane is quite similar to a typical membrane cleaning protocol, it is reasonable to believe

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that the in-situ membrane regeneration may not significantly increase the membrane operation

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cost but can satisfactorily avoid the expensive replacement of the entire membrane module due

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to irreversible fouling, thereby potentially reducing the overall cost of the membrane-based water

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treatment system.

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cost-effectiveness of the proposed membrane technology.

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out of the scope of the present study.

Therefore, membrane regeneration offers a universal cleaning strategy Since

Indeed, a thorough cost-benefit analysis is warranted to assess the long-term However, research in this direction is

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ASSOCIATED CONTENT

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Supporting Information. SEM images of the top surfaces of polyelectrolyte membranes

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made with 2, 4, and 6 PEI-PAA bilayers, respectively (Figure S1); cross-sectional SEM image of

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the PSf support (Figure S2); changes in sensor frequency from the QCM-D measurement of a 2-

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bilayer film after subsequent acid treatments at pH 2-3 (Figure S3); FTIR spectra of 2-bilayer

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and 4-bilayer membranes before and after pH 1 acid treatment (Figure S4); and TEM-EDX

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analysis of a 2-bilayer film on a TEM copper grid after pH 1 acid treatment (Figure S5).

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ACKNOWLEDGEMENTS

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The material is based upon work supported by the U.S. National Science Foundation under

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Award Number CBET-1565452 and the U.S. Department of Energy under Award Number DE-

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IA0000018.

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reflect those of the sponsors.

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The opinions expressed herein are those of the authors and do not necessarily

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359 360 361

Figure 1. SEM images of the (a) top surface and (b) bottom surface of the PSf support, (c) top

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surface of the polydopamine-coated PSf support, (d) top surface and (e) bottom surface of the 2-

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bilayer membrane, and (f) FTIR spectra of the PSf support before and after being deposited with

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different numbers of PEI-PAA bilayers.

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366 367 (a)

(b) 30

0.6

Water Flux (L/m2/h)

Solute Flux (mol/m2/h)

FO Mode PRO Mode

25 20 15 10 5 0

FO Mode PRO Mode 0.4

0.2

0.0 CTA

2-bilayer 4-bilayer 6-bilayer

CTA

2-bilayer 4-bilayer 6-bilayer

368 369

370 371

Figure 2. (a) Water flux and (b) reverse solute flux of polyelectrolyte membranes made with

372

different numbers of PEI-PAA bilayers, using 0.5 M TSC draw solution. (c) Schematic

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illustration of the swelling of the polyelectrolyte layers on the draw side in FO and PRO modes,

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respectively, making the membrane less effective for rejecting solutes. (d) Thickness of

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polyelectrolyte layer in DI water and 0.5 M TSC solution, as measured by ellipsometer.

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379 380 381

Figure 3.

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from the membrane; cross-sectional SEM images of (b) original 2-bilayer membrane, (c) original

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6-bilayer membrane, (d) acid-treated 2-bilayer membrane, and (e) acid-treated 6-bilayer

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membrane; and QCM-D measurements of (f) the PEI-PAA bilayer deposition and (g) repeated

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cycles of acid treatment and regeneration of a 2-bilayer membrane. Note that the masses in (g)

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were normalized by the mass of the original 2-bilayer membrane.

(a) Schematic illustration of acid treatment for the disassembly of PEI-PAA bilayers

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390 391 392

Figure 4. TEM surface images and diffraction patterns of a 2-bilayer sample (a-c) before and (d-

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f) after the pH 1 acid treatment.

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(a)

30

After acid treatment After regeneration

Water Flux (L/m2/h)

25 20 15 10 5 0

Original

1st 3rd 2nd Membrane Regeneration Stage

395 (b) 0.35 After acid treatment After regeneration

Solute Flux (mol/m2/h)

0.30 0.25 0.20 0.15 0.10 0.05 0.00

396

(c)

Original

30 25

Water Flux (L/m2/h)

1st 3rd 2nd Membrane Regeneration Stage

Original membrane

20

Regenerated membrane

15 10 Alginate fouling

5 0

0

200

400 Time(min)

600

800

397 398

Figure 5.

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declines of the original 2-bilayer membrane and membrane after each cycle of acid treatment and

400

regeneration.

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solution, 20 mM NaCl and 0.5 M CaCl2 as feed solution, and 200 mg/L alginate for fouling

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experiments.

(a) Pure water fluxes, (b) reverse solute fluxes, and (c) fouling-induced water flux

The experiments were conducted in FO mode, 0.5 M TSC was used as draw

The blue-colored data points in (c) represent the initial water flux measured 22

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without foulants.

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