Tuning Selectivities in Gas Separation Membranes Based on Polymer-Grafted Nanoparticles.

Polymer membranes are critical to many sustainability applications that require the size-based separation of gas mixtures. Despite their ubiquity, there is a continuing need to selectively affect the transport of different mixture components while enhancing mechanical strength and hindering aging. Polymer-grafted nanoparticles (GNPs) have recently been explored in the context of gas separations. Membranes made from pure GNPs have higher gas permeability and lower selectivity relative to the neat polymer because they have increased mean free volume. Going beyond this ability to manipulate the mean free volume by grafting chains to a nanoparticle, the conceptual advance of the present work is our finding that GNPs are spatially heterogeneous transport media, with this free volume distribution being easily manipulated by the addition of free polymer. In particular, adding a small amount of appropriately chosen free polymer can increase the membrane gas selectivity by up to two orders of magnitude while only moderately reducing small gas permeability. Added short free chains, which are homogeneously distributed in the polymer layer of the GNP, reduce the permeability of all gases but yield no dramatic increases in selectivity. In contrast, free chains with length comparable to the grafts, which populate the interstitial pockets between GNPs, preferentially hinder the transport of the larger gas and thus result in large selectivity increases. This work thus establishes that we can favorably manipulate the selective gas transport properties of GNP membranes through the entropic effects associated with the addition of free chains.

[1]  Sanat K. Kumar,et al.  Structure of Polymer-Grafted Nanoparticle Melts. , 2020, ACS nano.

[2]  M. Gauthier,et al.  Colloidal Jamming in Multiarm Star Polymer Melts , 2019, Macromolecules.

[3]  Sanat K. Kumar,et al.  High-Frequency Mechanical Behavior of Pure Polymer-Grafted Nanoparticle Constructs. , 2019, ACS macro letters.

[4]  J. Jestin,et al.  Location of Imbibed Solvent in Polymer-Grafted Nanoparticle Membranes. , 2018, ACS macro letters.

[5]  I. Pinnau,et al.  Polymers of intrinsic microporosity for energy-intensive membrane-based gas separations , 2018, Materials Today Nano.

[6]  Yang Liu,et al.  Mixed matrix formulations with MOF molecular sieving for key energy-intensive separations , 2018, Nature Materials.

[7]  T. Merkel,et al.  50th Anniversary Perspective: Polymers and Mixed Matrix Membranes for Gas and Vapor Separation: A Review and Prospective Opportunities , 2017 .

[8]  B. Freeman,et al.  Physical aging, CO2 sorption and plasticization in thin films of polymer with intrinsic microporosity (PIM-1) , 2017 .

[9]  Benny D. Freeman,et al.  Maximizing the right stuff: The trade-off between membrane permeability and selectivity , 2017, Science.

[10]  A. Sokolov,et al.  Polymer-Grafted Nanoparticle Membranes with Controllable Free Volume , 2017 .

[11]  Chen Zhang,et al.  Materials for next-generation molecularly selective synthetic membranes. , 2017, Nature materials.

[12]  B. Freeman,et al.  Energy-efficient polymeric gas separation membranes for a sustainable future: A review , 2013 .

[13]  Brian C. Benicewicz,et al.  Nanocomposites with Polymer Grafted Nanoparticles , 2013 .

[14]  K. Matyjaszewski,et al.  Impact of polymer graft characteristics and evaporation rate on the formation of 2-D nanoparticle assemblies. , 2010, Langmuir : the ACS journal of surfaces and colloids.

[15]  D. Gigmes,et al.  "Wet-to-Dry" Conformational Transition of Polymer Layers Grafted to Nanoparticles in Nanocomposite , 2010, 1005.1551.

[16]  Linda S. Schadler,et al.  Anisotropic self-assembly of spherical polymer-grafted nanoparticles. , 2009, Nature materials.

[17]  L. Robeson,et al.  The upper bound revisited , 2008 .

[18]  Young Moo Lee,et al.  Polymers with Cavities Tuned for Fast Selective Transport of Small Molecules and Ions , 2007, Science.

[19]  Markus Antonietti,et al.  Large-scale synthesis of organophilic zirconia nanoparticles and their application in organic-inorganic nanocomposites for efficient volume holography. , 2007, Small.

[20]  S. Takahashi,et al.  Gas permeation in poly(ether imide) nanocomposite membranes based on surface-treated silica. Part 1: Without chemical coupling to matrix , 2006 .

[21]  P. Budd,et al.  Polymers of intrinsic microporosity (PIMs): organic materials for membrane separations, heterogeneous catalysis and hydrogen storage. , 2006, Chemical Society reviews.

[22]  Donald R Paul,et al.  Physical aging of thin glassy polymer films: Free volume interpretation , 2006 .

[23]  C. Ryu,et al.  A Versatile Method To Prepare RAFT Agent Anchored Substrates and the Preparation of PMMA Grafted Nanoparticles , 2006 .

[24]  T. Fukuda,et al.  Suspensions of Silica Particles Grafted with Concentrated Polymer Brush: A New Family of Colloidal Crystals , 2006 .

[25]  Linda J. Broadbelt,et al.  Structural Relaxation of Polymer Glasses at Surfaces, Interfaces, and In Between , 2005, Science.

[26]  B. Freeman,et al.  MATERIALS SELECTION GUIDELINES FOR MEMBRANES THAT REMOVE CO2 FROM GAS MIXTURES , 2005 .

[27]  L. Leibler,et al.  Enthalpic Stabilization of Brush-Coated Particles in a Polymer Melt , 2002 .

[28]  A. J. Hill,et al.  Ultrapermeable, Reverse-Selective Nanocomposite Membranes , 2002, Science.

[29]  Benny D. Freeman,et al.  Basis of Permeability/Selectivity Tradeoff Relations in Polymeric Gas Separation Membranes , 1999 .

[30]  K. Ikeda,et al.  Gas permeation property of polyaniline films , 1995 .

[31]  T. Hashimoto,et al.  Ordered structure in mixtures of a block copolymer and homopolymers. 1. Solubilization of low molecular weight homopolymers , 1991 .

[32]  M. Daoud,et al.  Star shaped polymers : a model for the conformation and its concentration dependence , 1982 .

[33]  David Turnbull,et al.  Molecular Transport in Liquids and Glasses , 1959 .