Cu-air-PS system

Received: 10 January 2019

Revised: 21 March 2019

Accepted: 8 April 2019

DOI: 10.1002/aic.16611

EDITOR’S CHOICE: AICHE LETTER: SEPARATIONS: MATERIALS, DEVICES AND PROCESSES

Ultra-thin skin carbon hollow fiber membranes for sustainable molecular separations Chen Zhang

| Rachana Kumar | William J. Koros

School of Chemical & Biomolecular Engineering, Georgia Institute of Technology, Atlanta, Georgia

Significance A transformative platform is reported to derive ultra-thin carbon molecular sieve

Correspondence William J. Koros, School of Chemical & Biomolecular Engineering, Georgia Institute of Technology, 311 Ferst Drive, Atlanta, GA 30332. Email: [email protected] Chen Zhang, School of Chemical & Biomolecular Engineering, Georgia Institute of Technology, 311 Ferst Drive, Atlanta, GA 30332. Email: [email protected]

(CMS) hollow fiber membranes from dual-layer precursor hollow fibers with indepen-

Present address Chen Zhang, Department of Chemical and Biomolecular Engineering, University of Maryland 4418 Stadium Dr. College Park, MD 20742.

KEYWORDS

dently tuned skin layer and substrate properties. These ultra-thin CMS hollow fiber membranes show attractive CO2/CH4 separation factors and excellent CO2 permeances up to ~1,400% higher than state-of-the-art asymmetric CMS hollow fiber membranes. They provide a unique combination of permeance and selectivity competitive with zeolite membranes, but with much higher membrane packing density and potentially much lower costs.

carbon molecular sieve membranes, hollow fiber membranes, molecular separations, natural gas purification, ultra-thin membranes

Funding information Basic Energy Sciences, Grant/Award Number: DE-FG02-04ER15510; Shell International Exploration and Production Inc.

that are more rigid than flexible polymers.6,7 Rigid membrane mate-

1 | I N T RO D UC T I O N

rials can provide exceptional entropic diffusion selectivities for closely Molecularly selective membranes can enable sustainable large-scale

sized and/or shaped molecular pairs.8 Carbon molecular sieves (CMS)

molecular separations by reducing the required thermal energy inputs

represent a class of rigid membrane materials having excellent bal-

and CO2 footprints.1 One of the most commercially successful exam-

ances between transport properties, tunability, and scalability.9 CMS

ples is membrane desalination accounting for over 50% of worldwide

materials comprise micropores made by packing imperfections of

2

desalination capacity. The breakthrough allowing its large-scale prac-

graphene-like sheets. These graphene-like sheets are populated by

tice was the invention of thin-film composite membranes comprising

molecular-size features that allow precise differentiation between

selective crosslinked aromatic polyamides. The intrinsic water perme-

molecules with only 0.1–0.2 Å size difference.10 CMS materials are

ability of the material is moderate; however, defect-free ultra-thin

formed by controlled pyrolysis of polymer precursors. By tuning pre-

(~100–500 nm) separation (skin) layers can be formed via in situ inter-

cursor chemistry and pyrolysis conditions, the pore structure of CMS

facial polymerization, thereby enabling attractive productivity in prac-

materials can be controlled to provide desirable transport properties

tical spiral-wound modules.4,5 Indeed, economically translating high-

for target molecular separations (e.g., O2/N2, CO2/CH4, C2H4/C2H6,

performance materials into scalable devices with ultra-thin skin layers

C3H6/C3H8, xylene isomers).8,11-14 Notably, the family of 6FDA poly-

is key to enable large-scale application of any molecularly selective

imides

membrane.

DETDA/DABA) are outstanding precursor materials.11,15,16 Pyrolysis

3

(e.g.,

6FDA/BPDA-DAM,

6FDA-mPDA/DABA,

6FDA-

Expanding the boundaries of large-scale membrane separations

of these advanced polyimides has been shown to create CMS mate-

beyond desalination, however, requires advanced membrane materials

rials with remarkably high CO2 permeability (~7,200–22,000 Barrer)

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© 2019 American Institute of Chemical Engineers

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AIChE Journal. 2019;65:e16611. https://doi.org/10.1002/aic.16611

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ZHANG ET AL.

and simultaneously attractive CO2/CH4 ideal selectivity (~30–50) suit-

the core polymer dope. Compositions of the polymer dopes (Table S1)

able for membrane-based natural gas purification.

and spinning parameters (Table S2) can be found in the Supporting

Two challenges of CMS membranes must be addressed before a

Information.

breakthrough similar to the one made by thin-film composite mem-

The dual-layer precursor hollow fibers were soaked in a 10 wt%

branes can occur. First, 6FDA-polyimides are more expensive than

VTMS/hexane solution for 24 hr followed by hydrolysis/condensation

commercially available polymers. Producing CMS membranes can be

in saturated water vapor.18 The hollow fiber skin layer was then in situ

costly if the entire precursor hollow fiber consists of these advanced

hybridized by sequential soaking in two monomer solutions. The first

polymers. Second, although translating CMS materials to scalable hol-

solution comprises 0.001–0.1 wt% diethyltoluenediamine (DETDA)

low fiber formats was demonstrated, a platform has not been devel-

dissolved in hexane, and the second solution comprises 0.001–0.1 wt

oped to create CMS hollow fiber membranes with ultra-thin (<1 μm)

% trimesoyl chloride (TMC) dissolved in hexane. Following hybridiza-

skin layers. The porous substrate of precursor hollow fibers can col-

tion, the precursor hollow fibers were dried in a vacuum oven at

lapse during pyrolysis, providing CMS hollow fiber membranes with

150 C for 12 hr prior to controlled pyrolysis under continuous purge

thick skin layers (15–50 μm).

Treating precursor hollow fibers

(200 cc/min) of ultra-high-purity Argon at 550 C. Details regarding

with silane (e.g., vinyltrimethoxysilane, VTMS) prior to pyrolysis sup-

heating protocols and construction of CMS hollow fiber modules can

presses substrate collapse.18 Skin layer thickness of asymmetric CMS

be found in the Supporting Information.

17,18

hollow fiber membranes prepared by this method can be reduced to

Separation performance of the ultra-thin CMS hollow fiber mem-

~3–6 μm, which is still much thicker than the precursor hollow fibers.

branes was studied using the constant-pressure permeation method

Further reducing CMS hollow fiber skin layer thickness (ideally to that

with an equimolar CO2/CH4 mixture at 100 psia and 35 C. Membrane

of the precursor hollow fibers, i.e., <1 μm) will provide significantly

permeate pressure was kept at 1 atm. Permeate flow rate was mea-

higher permeances to reduce required membrane area and system

sured using a bubble flow meter (10 mL) and compositions were ana-

footprint. Clearly, addressing the two challenges will drastically

lyzed using a Varian-430 gas chromatograph (GC). The stage-cut,

enhance the economic viability of CMS membranes.

which is the percentage of feed mixture that permeates through the

In this letter, we report a transformative ultra-thin CMS hollow

membrane, was kept less than 1%. Permeation data were collected

fiber platform that addresses both challenges using Matrimid®

after bubble flow meter and GC readings became stabilized. A mini-

(MA) and 6FDA/BPDA-DAM (6F) as precursors. The terminology used

mum of three GC injections were made for each individual membrane

to refer to these ultra-thin CMS hollow fibers is ULT CMS-X#, where

module. Permeation data of individual membrane modules can be

X refers to the sheath precursor material and # refers to the CMS skin

found in Table S3. Scanning electron microscope (SEM) images were

layer thickness in μm. The intrinsic structural and transport properties

obtained in a LEO 1530 field emission SEM. Fourier transform infra-

of CMS materials derived from these two precursors have been

red spectroscopy (FT-IR) was done using a Bruker Tensor

19-21

reported in the literature.

By using dual-layer precursor hollow

27 spectrometer.

fibers, this novel platform enables creation of advanced CMS hollow fiber membranes with ultra-thin skin layers. These advanced structures provide highly attractive permeance more than one order of magnitude higher than state-of-the-art asymmetric CMS hollow fiber membranes. Additionally, the approach allows derivation of CMS hollow fiber membranes from 6FDA-polyimides with minimal consumption (up to 98% less) of the expensive polymer. Last, we report an innovative in situ hybridization method to effectively repair skin layer defects of CMS hollow fiber membranes.

3 | RESULTS AND DISCUSSION CMS hollow fiber membranes are traditionally derived from monolithic precursor hollow fibers (Figure 1a). Monolithic Matrimid® precursor hollow fibers (Figure 1b) have skin layers ~1 μm. Following silane treatment and pyrolysis, the porous substrate underneath the skin layer partially collapsed, and the skin layer thickness of the asymmetric CMS hollow fiber membrane (CMS-MA) increased to ~6 μm (Figure 1c). To create CMS hollow fiber membranes with ultra-thin

2 | EXPERIMENTAL METHODS

skin layers, substrate collapse of precursor hollow fibers must be totally avoided. Investigating substrate collapse of asymmetric CMS

The dual-layer precursor hollow fibers were formed using dry-jet wet-

hollow fiber membranes suggests that a highly porous substrate can

quench spinning by coextruding the sheath and core polymer dopes

provide improved collapse resistance during pyrolysis (Figure S4).

®

from a multichannel spinneret. To form dual-layer Matrimid /

With monolithic precursor hollow fibers, however, it's challenging to

Matrimid® precursor hollow fibers, both the sheath and core polymer

independently control the substrate porosity without introducing skin

dopes comprise Matrimid® 5218 polyimide (Huntsman Advanced

layer defects. To overcome this challenge, we derived CMS hollow

Materials). To form dual-layer 6F/Matrimid® precursor hollow fibers,

fiber membranes from dual-layer precursor hollow fibers with tailored

the sheath polymer dope comprises 6FDA/BPDA-DAM polyimide

chemistry and substrate morphology (Figure 1d). A dual-layer precur-

and the core polymer dope comprises Matrimid® 5218 polyimide. To

sor hollow fiber consists of an outside sheath layer and an inside core

increase core layer porosity of the dual-layer precursor hollow fibers,

layer formed by co-extruding sheath and core polymer dopes. By dis-

polyvinylpyrrolidone (Mw~1,300,000, Sigma-Aldrich) was dissolved in

solving pore formers22 (e.g., polyvinylpyrrolidone, PVP) in the core

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ZHANG ET AL.

F I G U R E 1 Formation of ultra-thin CMS hollow fiber membranes. (a) Schematic showing formation of asymmetric CMS hollow fiber membranes using monolithic precursor hollow fibers; (b, c) scanning electron microscope (SEM) images of monolithic Matrimid® precursor hollow fibers and asymmetric CMS hollow fiber membrane (skin layer 6 μm) derived thereof (CMS-MA); (d) schematic showing formation of ultra-thin CMS hollow fiber membranes using dual-layer precursor hollow fibers comprising the same polymer in the sheath and core layer; (e, f) SEM images of dual-layer Matrimid®/Matrimid® precursor hollow fibers and ultra-thin (skin layer 1 μm) CMS hollow fiber membranes (ULT CMSMA1) derived thereof; (g, h) SEM images of dual-layer Matrimid®/Matrimid® precursor hollow fibers and ultra-thin (skin layer 0.5 μm) CMS hollow fiber membranes (ULT CMS-MA0.5) derived thereof; (i) schematic showing formation of ultra-thin CMS hollow fiber membranes using dual-layer precursor hollow fibers comprising different polymers in the sheath and core layer; (j, k) SEM images of dual-layer 6F/Matrimid® precursor hollow fibers and ultra-thin (skin layer 0.5 μm) CMS hollow fiber membranes (ULT CMS-6F0.5) derived thereof. 6F, 6FDA/BPDADAM; CMS, carbon molecular sieve; HF, hollow fiber; MA, Matrimid®; ULT, ultra-thin [Color figure can be viewed at wileyonlinelibrary.com] polymer dope, we found that the substrate porosity of dual-layer ®

®

Without substrate collapse, skin layer thickness of ultra-thin

precursor hollow fiber can be dramatically

CMS hollow fiber membranes is determined by sheath layer thick-

increased (Figure 1e). Fortunately, a dense sheath layer can still be

ness of the dual-layer precursor hollow fibers. The sheath layer

formed as it relies upon independently extruded sheath polymer dope

thickness can be controlled by spinning parameters of the dual-layer

without dissolved pore formers. With the aid of silane treatment, sub-

precursor hollow fibers. A smaller ratio of sheath versus core dope

strate collapse was totally avoided during pyrolysis at 550 C

flow rate will provide dual-layer precursor hollow fibers with thinner

(Figure 1f). This gives CMS hollow fiber membranes (ULT CMS-MA1)

sheath layer. For example, by reducing the flow rate ratio from 1:30

with much more open substrate and ultra-thin skin layer (~1 μm).

to 1:50 (Table S2), we reduced sheath layer thickness of the dual-

Interestingly, a clear boundary is seen between the skin layer and the

layer Matrimid®/Matrimid® precursor hollow fibers from ~1 to

Matrimid /Matrimid

highly porous substrate, which does not exist in asymmetric CMS hol-

~0.5 μm (Figure 1g). The reduction contributes to thinner skin layer

low fiber membranes derived from monolithic precursor hollow fibers

(~0.5 μm, Figure 1h) of ultra-thin CMS hollow fiber membranes (ULT

(Figure 1c).

CMS-MA0.5). Clearly, ultra-thin CMS hollow fiber membranes with

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ZHANG ET AL.

even thinner skin layer (<0.5 μm) can be made by further tuning spin-

to derive defect-free CMS hollow fiber membranes, which has limited

ning parameters of dual-layer precursor hollow fibers.

the scope of suitable precursor chemistry and structures for CMS

This highly versatile platform was successfully adapted to dual-layer

membrane formation. To address this challenge, we developed a

precursor hollow fibers comprising different sheath and core layer poly-

method to enhance separation factors of defective CMS membranes

mers (Figure 1i). We derived ultra-thin CMS hollow fiber membranes

by hybridizing precursor hollow fiber skin layers with in situ synthe-

using a 6FDA-polyimide with minimal need for the advanced polymer

sized polyamide. The hybridization occurs by sequentially soaking the

(2 wt% of the entire hollow fiber, Table S2). Sheath layer (~0.5 μm) of

precursor hollow fibers in diamine DETDA/hexane and acid chloride

®

the dual-layer 6F/Matrimid

precursor hollow fibers comprises

TMC/hexane solutions. Condensation polymerization of the highly

6FDA/BPDA-DAM polyimide (Figure 1j). The core layer does not con-

reactive monomers forms branched or crosslinked polyamide, filling

tribute to formation of the CMS membrane skin layer and thus only

the skin layer defects (Figure 2a).26 As the hybridized precursor hol-

comprises the less expensive Matrimid® polyimide. As shown in

low fibers undergo pyrolysis, the crosslinked polyamides inside the

Figure 1k, pyrolysis of the dual-layer 6F/Matrimid® precursor hollow

defects were presumably transformed into CMS, thereby eliminating

fibers gives CMS hollow fiber membranes (ULT CMS-6F0.5) with highly

skin layer defects on CMS hollow fiber membranes.

open substrate and crack-free ultra-thin skin layer (~0.5 μm). This result

Ultra-thin CMS hollow fiber membranes (ULT CMS-MA1) were

may seem surprising considering the different thermal expansion coeffi-

derived from dual-layer Matrimid®/Matrimid® precursor hollow fibers

23

It's hypothesized that as

hybridized with 0.1 wt% DETDA/0.1 wt% TMC prior to pyrolysis. The

the sheath and core layers undergo thermal decomposition during

hybridization dramatically increased CO2/CH4 separation factor of

pyrolysis, they were both transformed into disordered defective

the ultra-thin CMS hollow fiber membrane from ~7.9 to ~36.7,

graphene-like sheets with similar chemistry and thermal expansion

suggesting that hybridization was highly effective to repair skin layer

coefficients. Hence, an integral skin layer can be formed without crack-

defects of CMS hollow fiber membranes. To our best knowledge, this

ing. The ultra-thin CMS hollow fiber membranes were evaluated for

is the first time that a method to repair CMS hollow fiber membranes

CO2/CH4 separation using an equimolar CO2/CH4 feed mixture at

skin defect is reported. Notably, the ultra-thin CMS hollow fiber mem-

100 psia and 35 C. Compared with asymmetric CMS hollow fibers with

branes provide excellent CO2 permeance ~1,177 GPU. This may seem

cients of the sheath and core layer polymers.

24

these specific ultra-thin CMS hollow fibers show

surprising because the crosslinked polyamide may introduce signifi-

unattractive CO2/CH4 separation factor (~7.9). This result indicates that

cant mass transfer resistance if a continuous film is formed on precur-

defects exist in the skin layer of the ultra-thin CMS hollow fiber mem-

sor hollow fiber skin layer due to hybridization. Unlike interfacial

branes, which was likely because the dual-layer precursor hollow fibers

polymerization of monomers dissolved in two immiscible solvents

were defective (Figure 2a). This was evidenced by low O2/N2 ideal

(e.g., water and hexane),27 the hybridization method relies upon

selectivities of the dual-layer precursor hollow fibers (Table S4).

monomers dissolved in the same solvent (hexane). The diamine mono-

thicker skin layers,

Skin layer defects of precursor hollow fibers can be repaired by 25

mer solution was sorbed into the defects at the membrane surface,

caulking ; however, to our best knowledge, methods that can repair

thereby providing reactants for film growth inside the defects, and

skin layer defects of CMS hollow fiber membranes have not been

possibly at the membrane surface surrounding the defects. As the

reported. Defect-free precursor hollow fibers are generally preferred

defect density was low, we anticipate that a continuous polyamide film

F I G U R E 2 Repairing skin layer defects of ultra-thin CMS hollow fiber membranes. (a) Schematic showing repairing CMS hollow fiber membrane skin defects by in situ hybridization. The inset represents chemical structure of crosslinked polyamide formed by highly reactive monomers (DETDA and TMC); (b) effects of hybridization monomer concentrations on CO2/CH4 separation performance of ultra-thin CMS hollow fiber membranes (ULT CMS-MA1); (c) comparing FT-IR spectra of dual-layer Matrimid®/Matrimid® precursor hollow fiber prior to and after hybridization with 0.1 wt% DETDA/0.1 wt% TMC. The spectra of bulk polyamide formed by solution polymerization of DETDA and TMC are shown for reference. CMS, carbon molecular sieve; DETDA, diethyltoluenediamine; FT-IR, Fourier transform infrared spectroscopy; TMC, trimesoyl chloride; ULT, ultra-thin [Color figure can be viewed at wileyonlinelibrary.com]

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ZHANG ET AL.

was not able to cover the entire membrane surface. This hypothesis

~1,400% higher CO2 permeance, respectively. Similarly, ULT CMS-

was supported by comparing morphology of the precursor hollow fiber

6F0.5 with ultra-thin skin layer (~0.5 μm) was ~830% more permeable

skin layer before and after hybridization (Figures S6 and S7). It is worth-

than asymmetric CMS hollow fiber membranes (CMS-6F) derived

while to note that this is quite different from formation of polyamide

from monolithic 6FDA/BPDA-DAM precursor hollow fibers.31 While

thin-film composite membranes often studied for desalination. With

CO2/CH4 separation factors of ultra-thin CMS hollow fiber mem-

highly porous substrates (e.g., ultrafiltration membranes), the surface

branes were ~15–25% lower than asymmetric CMS hollow fiber

pore density is sufficiently high that the polyamide film formed at indi-

membranes with thicker skin layers, they remain highly attractive for

vidual pore surface can connect to provide a continuous film.28

energy-efficient natural gas purification.32

Our results further suggest that separation performance of the

One would expect ULT CMS-MA0.5 (skin layer ~0.5 μm) with 50%

ultra-thin CMS hollow fiber membranes can be tuned by optimization

thinner skin layer to provide 100% higher CO2 permeance than ULT

of monomer concentrations (Figure 2b). By reducing monomer con-

CMS-MA1 (skin layer ~1 μm). However, ULT CMS-MA0.5 (CO2

centration from 0.1 to 0.001 wt%, CO2 permeance of the ultra-thin

permeance ~1,310 GPU) was only slightly more permeable than ULT

CMS hollow fiber membrane (ULT CMS-MA1) increased from 1,177

CMS-MA1 (CO2 permeance ~1,177 GPU). This was likely due to exis-

to 1,452 GPU. CO2/CH4 separation factor dropped to ~18, which was

tence of the so-called “hyperskin” at the outmost region of CMS hollow

still quite attractive for bulk acid gas removal.29 It is hypothesized that

fiber membrane skin layer.33 The hyperskin has extremely low perme-

at higher monomer concentrations, a larger percentage of skin layer

ability, and limits membrane permeance as the membrane skin layer

defects can be filled by polyamides providing higher membrane sepa-

thickness approaches that of the hyperskin. Eliminating the hyperskin

ration factors. We studied surface chemistry of the precursor hollow

will be useful to further increase CO2 permeance; however, is not within

fibers before and after hybridization using FT-IR. The characteristic

the scope of the current work. Permeance change due to physical aging

band (1,637 cm−1) of amide linkages30 was not observed in dual-layer

is often discussed for CMS membranes.31,34 Separation performance of

precursor hollow fiber hybridized with 0.1 wt% DETDA/0.1 wt% TMC

a ultra-thin CMS hollow fiber membrane module (M7, Table S3) was

(Figure 2c). This supports our hypothesis that the crosslinked polyam-

periodically measured as it was stored under 100 psia pure CO2 for

ide only exists inside skin layer defects and its concentration in the

275 days (Figure 3b). The separation performance stabilized ~100 days

polyimide skin layer was possibly too low for FT-IR detection.

following membrane formation, before which CO2 permeances dropped

We compared CO2/CH4 separation performance (Figure 3a) of

by ~35% and CO2/CH4 separation factor increased by ~23%. The stabi-

ultra-thin CMS hollow fiber membranes (ULT CMS-MA1, ULT CMS-

lized CO2 permeances ~850 GPU remains highly attractive (840% higher

MA0.5, and ULT CMS-6F0.5) derived from dual-layer precursor hol-

than the asymmetric CMS hollow fiber membranes).

low fibers with silane treatment and hybridization (0.1 wt%

Competing with zeolite membranes has been challenging for poly-

DETDA/0.1 wt% TMC). Clearly, CO2 permeances of the ultra-thin

mer membranes and polymer-derived membranes (e.g., CMS mem-

CMS hollow fiber membranes were remarkably higher than conven-

branes, mixed-matrix membranes).35-41 We compared the ultra-thin

tional asymmetric CMS hollow fiber membranes. Compared with

CMS hollow fiber membranes with tubular zeolite membranes and

CMS-MA with thicker skin layer (~6 μm), ULT CMS-MA1 (skin layer

other polymer or polymer-derived hollow fiber membranes for CO2/

~1 μm), and ULT CMS-MA0.5 (skin layer ~0.5 μm) provide ~1,200 and

CH4 separation (Figure 3c). It should be noted that permeation data

F I G U R E 3 Evaluation of membrane separation performance. (a) CO2/CH4 separation performance of ultra-thin CMS hollow fiber membranes (ULT CMS-MA1, ULT CMS-MA0.5, ULT CMS-6F0.5). The ultra-thin CMS hollow fiber membranes were all pyrolyzed (550 C) from precursors hybridized with 0.1 wt% DETDA/0.1 wt% TMC. Separation performance of asymmetric CMS hollow fiber membranes (CMS-MA and CMS-6F) pyrolyzed (550 C) from monolithic precursors are also shown for comparison. (b) Periodically measured CO2/CH4 separation performance of a ultra-thin CMS hollow fiber membrane module within 275 days. The module was stored under 100 psia pure CO2 between permeation measurements. (c) Comparing CO2/CH4 separation performance of hollow fiber membranes and tubular membranes (Table S5). The solid gray line represents the converted (assuming 1 μm skin layer) Robeson upper bond for the CO2/CH4 pair. Solid squares represent ultra-thin CMS hollow fiber membranes reported in this work. (Hollow triangles: tubular zeolite membranes; hollow squares: asymmetric CMS hollow fiber membranes derived from monolithic precursor hollow fibers; hollow circles: polymeric hollow fiber membranes). CMS, carbon molecular sieve; DETDA, diethyltoluenediamine; MA, Matrimid®; TMC, trimesoyl chloride; ULT, ultra-thin [Color figure can be viewed at wileyonlinelibrary.com]

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ZHANG ET AL.

measured using films were not used for comparison as film-based membrane formats (e.g., plate-and-frame, spiral-wound) have much lower packing density.42 Remarkably, the ultra-thin CMS hollow fiber membranes offer competitive CO2 permeance and CO2/CH4 separation factors with selected tubular zeolite membranes (e.g., SiCHA, SSZ-13, NaX, KY) under similar testing conditions.43-45 SAPO-34 is possibly the most extensively studied and arguably the highestperforming zeolite membrane material for the CO2/CH4 pair.35,46,47 Compared with tubular SAPO-34 membranes, the ultra-thin CMS hollow fiber membranes (ULT CMS-6F0.5) show competitive CO2 permeance (2,546 GPU) with lower (24.1), yet attractive CO2/CH4 separation factors under similar measurement conditions. By further tuning pyrolysis and hybridization conditions, a closing-up of the gap can be expected. Hollow fiber membranes can provide up to ~10× higher packing density with much lower manufacturing cost than tubular zeolite membranes.48 Notably, ultra-thin CMS hollow fiber membranes are the only hollow fiber membranes that exceed the converted (assuming 1 μm skin layer) Robeson upper bound (Figure 3c).49 By translating high-performance CMS materials to scalable hollow fibers with ultra-thin skin layers, this work can potentially transform membrane-based gas and vapor separations as thin-film composite membranes accomplished for desalination.

4 | CO NC LUSIO NS We report novel ultra-thin CMS hollow fiber membranes derived from tunable dual-layer precursor hollow fibers for sustainable CO2/CH4 separation. These advanced CMS membranes provide outstanding CO2 permeances (1,177–2,546 GPU) one order of magnitude higher than state-of-the-art structures while maintaining highly attractive CO2/CH4 separation factors (~24–37). Additionally, using dual-layer precursor hollow fibers, we have shown that ultra-thin CMS hollow fiber membranes can be economically derived from advanced 6FDA-polyimide precursors. Given the exceptional tunability of CMS materials, it is clear that the ultra-thin CMS hollow fiber platform can be extended to other economically important molecular separations (e.g., CO2/N2, olefins/ paraffins, and hydrocarbon isomers) with a broad impact.

ACKNOWLEDGMENTS The authors gratefully acknowledge financial support from Shell International Exploration and Production, Inc. We thank Dr. Joseph M. Mayne and Dr. P. Jason Williams for useful discussions. W.J.K. acknowledges additional financial support from Office of Basic Energy Science of the U.S. Department of Energy (Grant DEFG02-04ER15510) and equipment support through the Specialty Separations Center at Georgia Institute of Technology.

ORCID Chen Zhang

https://orcid.org/0000-0002-0071-2898

William J. Koros

https://orcid.org/0000-0001-5873-0899

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How to cite this article: Zhang C, Kumar R, Koros WJ. Ultrathin skin carbon hollow fiber membranes for sustainable molecular separations. AIChE J. 2019;65:e16611. https://doi. org/10.1002/aic.16611