Bottom-up synthesis of graphene films hosting atom-thick molecular-sieving apertures

Villalobos, Luis Francisco; Goethem, Cédric Van; Hsü, Kenneth J.; Li, Shaoxian; Moradi, Mohammad Hassan; Zhao, Kangning; Dakhchoune, Mostapha; Huang, Shiqi; Shen, Yueqing; Oveisi, Emad; Boureau, Victor; Agrawal, Kumar Varoon

doi:10.1073/pnas.2022201118

Cited by 15 publications

(19 citation statements)

References 66 publications

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“…Recently, in this direction, we introduced an advanced image analysis to investigate the grain orientation in nanocrystalline nanoporous graphene samples by calculating the local FFT around each pixel of the HRTEM and using these data to produce an orientation map (Figure 8H−I). 42 While the advances mentioned above allow characterization of porous graphene lattice, it is currently extremely challenging to resolve functional groups around the nanopores, which tend to gasify during sample preparation and imaging. Ongoing developments in (i) atomic resolution using low electron accelerating voltages, 50 (ii) high-speed imaging by coupling ultrafast isolated electron pulses 53 with direct counting electron detectors, 54 (iii) in situ cleaning protocols, and (iv) scanning atomic electron tomography, will open venues for studying the dynamics of structural changes and the threedimensional position of atoms and functional groups at the edge of graphene nanopores.…”

Section: Nanoporesmentioning

confidence: 99%

“…We recently exploited this route to prepare porous graphene with a high density of intrinsic vacancy defects. Depositing a small amount of carbon precursor on the foil as a thin polymer film followed by a short heat treatment at 500 °C, produced porous nanocrystalline graphene (PNG) (Figure E) . The heat treatment resulted in the pyrolysis of the polymer, which built a C reservoir in the Ni matrix.…”

Section: Gas Sieving From Graphene Nanoporesmentioning

confidence: 99%

“…While it is crucial to develop sample preparation techniques that allow imaging of a large volume of nanopores per sample, it is equally important to develop computational methods capable of efficiently analyzing the increasingly large volume of data. Recently, in this direction, we introduced an advanced image analysis to investigate the grain orientation in nanocrystalline nanoporous graphene samples by calculating the local FFT around each pixel of the HRTEM and using these data to produce an orientation map (Figure H–I) …”

Section: Understanding the Structure Of Nanoporesmentioning

confidence: 99%

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Gas Separation Membranes with Atom-Thick Nanopores: The Potential of Nanoporous Single-Layer Graphene

et al. 2022

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Conspectus Gas separation is one of the most important industrial processes and is poised to take a larger role in the transition to renewable energy, e.g., carbon capture and hydrogen purification. Conventional gas separation processes involving cryogenic distillation, solvents, and sorbents are energy intensive, and as a result, the energy footprint of gas separations in the chemical industry is extraordinarily high. This has motivated fundamental research toward the development of novel materials for high-performance membranes to improve the energy efficiency of gas separation. These novel materials are expected to overcome the intrinsic limitations of the conventional membrane material, i.e., polymers, where a longstanding trade-off between the separation selectivity and the permeance has motivated research into nanoporous materials as the selective layer for the membranes. In this context, atom-thick materials such as nanoporous single-layer graphene constitute the ultimate limit for the selective layer. Gas transport from atom-thick nanopores is extremely fast, dependent primarily on the energy barrier that the gas molecule experiences in translocating the nanopore. Consequently, the difference in the energy barriers for two gas molecules determines the gas pair selectivity. In this Account, we summarize the development in the field of nanoporous single-layer graphene membranes for gas separation. We start by discussing the mechanism for gas transport across atom-thick nanopores, which then yields the crucial design elements needed to achieve high-performance membranes: (i) nanopores with an adequate electron-density gap to sieve the desired gas component (e.g., smaller than 0.289, 0.33, 0.346, 0.362, and 0.38 nm for H2, CO2, O2, N2, and CH4, respectively), (ii) narrow pore size distribution to limit the nonselective effusive transport from the tail end of the distribution, and (iii) high density of selective pores. We discuss and compare the state-of-the-art bottom-up and top-down routes for the synthesis of nanoporous graphene films. Mechanistic insights and parameters controlling the size, distribution, and density of nanopores are discussed. Fundamental insights are provided into the reaction of ozone with graphene, which has been successfully used by our group to develop membranes with record-high carbon capture performance. Postsynthetic modifications, which allow the tuning of the transport by (i) tailoring the relative contributions of adsorbed-phase and gas-phase transport, (ii) competitive adsorption, and (iii) molecular cutoff adjustment, are discussed. Finally, we discuss practical aspects that are crucial in successfully preparing practical membranes using atom-thick materials as the selective layer, allowing the eventual scale-up of these membranes. Crack- and tear-free preparation of membranes is discussed using the approach of mechanical reinforcement of graphene with nanoporous carbon and polymers, which led to the first reports of millimeter- and centimeter-scale gas-sieving membranes in t...

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Section: Nanoporesmentioning

confidence: 99%

Section: Gas Sieving From Graphene Nanoporesmentioning

confidence: 99%

Section: Understanding the Structure Of Nanoporesmentioning

confidence: 99%

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Gas Separation Membranes with Atom-Thick Nanopores: The Potential of Nanoporous Single-Layer Graphene

et al. 2022

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“…Other experimental work has also reported the presence of gas-sieving defects in large-area CVD-grown graphene ( Huang et al., 2018 ; Khan et al., 2019 ), with the latter work employing a benzene-based CVD process. Reduction in the CVD temperature has been successfully used to introduce defects into graphene ( Kidambi et al., 2018 ; Villalobos et al., 2021 ), by promoting polycrystalline growth. Despite these experimental advances, there is a lack of understanding about how nanopores are formed during the CVD process and how their shape and size may be controlled.…”

Section: Knowledge Gaps and Future Research Directionsmentioning

confidence: 99%

Chemical vapor deposition of 2D materials: A review of modeling, simulation, and machine learning studies

Bhowmik¹,

Rajan²

2022

iScience

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“…In this context, scalable cost-effective synthesis of 2D materials via CVD − ,, and related processes have typically focused on minimizing defects in the 2D lattice and/or minimizing grain boundaries by forming larger domains ,,− to yield high-quality continuous monolayers for electronic applications. Some studies have explored the synthesis of nanoporous graphene for size-selective membrane applications by using lower CVD synthesis temperature, , pyrolyzing polymers/sugars on Ni substrate, quenched hot Pt foils in hydrocarbons to form nanoporous graphene, synthesized monolayer amorphous carbon (MAC) via laser-assisted CVD, introduced N dopants into graphene . Notably, Griffin et al measured enhanced proton transport through micron-scale membranes of nanoporous graphene ∼2 S cm –2 and MAC ∼1 S cm –2 with H + /Li + selectivity ∼10 for both, while Zeng et al measured proton conductance of ∼1.4 × 10 5 S m –2 (1 M HCl) for N-doped graphene (1 min N 2 plasma treatment of graphene) with H + /Cl – selectivity ∼40 and H + /methanol selectivity ∼1–2 orders of magnitude higher than Nafion.…”

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confidence: 99%

Kinetic Control of Angstrom-Scale Porosity in 2D Lattices for Direct Scalable Synthesis of Atomically Thin Proton Exchange Membranes

et al. 2022

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Angstrom-scale pores introduced into atomically thin 2D materials offer transformative advances for proton exchange membranes in several energy applications. Here, we show that facile kinetic control of scalable chemical vapor deposition (CVD) can allow for direct formation of angstrom-scale proton-selective pores in monolayer graphene with significant hindrance to even small, hydrated ions (K+ diameter ∼6.6 Å) and gas molecules (H2 kinetic diameter ∼2.9 Å). We demonstrate centimeter-scale Nafion|Graphene|Nafion membranes with proton conductance ∼3.3–3.8 S cm–2 (graphene ∼12.7–24.6 S cm–2) and H+/K+ selectivity ∼6.2–44.2 with liquid electrolytes. The same membranes show proton conductance ∼4.6–4.8 S cm–2 (graphene ∼39.9–57.5 S cm–2) and extremely low H2 crossover ∼1.7 × 10–1 – 2.2 × 10–1 mA cm–2 (∼0.4 V, ∼25 °C) with H2 gas feed. We rationalize our findings via a resistance-based transport model and introduce a stacking approach that leverages combinatorial effects of interdefect distance and interlayer transport to allow for Nafion|Graphene|Graphene|Nafion membranes with H+/K+ selectivity ∼86.1 (at 1 M) and record low H2 crossover current density ∼2.5 × 10–2 mA cm–2, up to ∼90% lower than state-of-the-art ionomer Nafion membranes ∼2.7 × 10–1 mA cm–2 under identical conditions, while still maintaining proton conductance ∼4.2 S cm–2 (graphene stack ∼20.8 S cm–2) comparable to that for Nafion of ∼5.2 S cm–2. Our experimental insights enable functional atomically thin high flux proton exchange membranes with minimal crossover.

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Bottom-up synthesis of graphene films hosting atom-thick molecular-sieving apertures

Cited by 15 publications

References 66 publications

Gas Separation Membranes with Atom-Thick Nanopores: The Potential of Nanoporous Single-Layer Graphene

Gas Separation Membranes with Atom-Thick Nanopores: The Potential of Nanoporous Single-Layer Graphene

Chemical vapor deposition of 2D materials: A review of modeling, simulation, and machine learning studies

Kinetic Control of Angstrom-Scale Porosity in 2D Lattices for Direct Scalable Synthesis of Atomically Thin Proton Exchange Membranes

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