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3. Swelling of Ti3C2Tx MXene in Water and Methanol at Extreme Pressure Conditions

Author

Artem Iakunkov, Ulrich Lienert, Jinhua Sun, and Alexandr V. Talyzin

Subjects
2D materials, compressibility, high pressure, MXene, swelling, Science
Abstract

Abstract Pressure‐induced swelling has been reported earlier for several hydrophilic layered materials. MXene Ti3C2Tx is also a hydrophilic layered material composed by 2D sheets but so far pressure‐induced swelling is reported for this material only under conditions of shear stress at MPa pressures. Here, high‐pressure experiments are performed with MXenes prepared by two methods known to provide “clay‐like” materials. MXene synthesized by etching MAX phase with HCl+LiF demonstrates the effect of pressure‐induced swelling at 0.2 GPa with the insertion of additional water layer. The transition is incomplete with two swollen phases (ambient with d(001) = 16.7Å and pressure‐induced with d(001) = 19.2Å at 0.2 GPa) co‐existing up to the pressure point of water solidification. Therefore, the swelling transition corresponds to change from two‐layer water intercalation (2L‐phase) to a never previously observed three‐layer water intercalation (3L‐phase) of MXene. Experiments with MXene prepared by LiCl+HF etching have not revealed pressure‐induced swelling in liquid water. Both MXenes also show no anomalous compressibility in liquid methanol. The presence of pressure‐induced swelling only in one of the MXenes indicates that the HCl+LiF synthesis method is likely to result in higher abundance of hydrophilic functional groups terminating 2D titanium carbide.

Published
2024
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4. Effect of Chain Length on Swelling Transitions of Brodie Graphite Oxide in Liquid 1‐Alcohols

Author

Artem Iakunkov, Andreas Nordenström, Nicolas Boulanger, Gui Li, Christoph Hennig, Mads Ry Vogel Jørgensen, Innokenty Kantor, and Alexander V. Talyzin

Subjects
alcohols, graphene, graphene oxide, swelling, X‐ray diffraction, Physics, QC1-999, Technology
Abstract

Abstract Swelling is the most fundamental property of graphite oxides (GO). Here, a structural study of Brodie graphite oxide (BGO) swelling in a set of long chain 1‐alcohols (named C11 to C22 according to the number of carbons) performed using synchrotron radiation X‐ray diffraction at elevated temperatures is reported. Even the longest of tested alcohols (C22) is found to intercalate BGO with enormous expansion of the interlayer distance from ≈6Å up to ≈63Å, the highest expansion of GO lattice ever reported. Swelling transitions from low temperature α‐phase to high temperature β‐phase are found for BGO in all alcohols in the C11–C22 set. The transitions correspond to decrease of inter‐layer distance correlating with the length of alcohol molecules, and change in their orientation from perpendicular to GO planes to layered parallel to GO (Type II transitions). These transitions are very different compared to BGO swelling transitions (Type I) found in smaller alcohols and related to insertion/de‐insertion of additional layer of alcohol parallel to GO. Analysis of general trends in the whole set of 1‐alcohols (C1 to C22) shows that the 1‐alcohol chain length defines the type of swelling transition with Type I found for alcohols with C10.

Published
2024
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8. Effect of chain length on swelling transitions of Brodie graphite oxide in liquid 1-alcohols

Author

Iakunkov, Artem, Nordenström, Andreas, Boulanger, Nicolas, Li, Gui, Hennig, Christoph, Jørgensen, Mads Ry Vogel, Kantor, Innokenty, Talyzin, Aleksandr V., Iakunkov, Artem, Nordenström, Andreas, Boulanger, Nicolas, Li, Gui, Hennig, Christoph, Jørgensen, Mads Ry Vogel, Kantor, Innokenty, and Talyzin, Aleksandr V.

Abstract

Originally included in thesis in manuscript form. This article also appears in: Advanced Materials Interfaces Editors' Choice.

Published
2024
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9. Temperature dependent swelling transitions of hummers graphite oxide in liquid 1-Alcohols

Author

Li, Gui, Gurzęda, Bartosz, Iakunkov, Artem, Nordenström, Andreas, Boulanger, Nicolas, Hennig, Christoph, Dejoie, Catherine, Talyzin, Aleksandr V., Li, Gui, Gurzęda, Bartosz, Iakunkov, Artem, Nordenström, Andreas, Boulanger, Nicolas, Hennig, Christoph, Dejoie, Catherine, and Talyzin, Aleksandr V.

Abstract

Graphite oxides (GO) swell in liquid alcohols with significant expansion of c-lattice. However, temperature-dependent swelling of Hummers GO (HGO) has so far been reported only for methanol and ethanol. Here, HGO swelling in liquid 1-alchohols (C1 to C22 according to the number of carbons) is studied as a function of temperature using in situ synchrotron radiation XRD. Swelling transitions never previously observed for HGO in any kind of polar solvents are found, enthalpy of these transition and compositions of HGO-Cx solid solvates near the point of solvent melting reported. Swelling transitions from low temperature to high-temperature phase are found for HGO in C10–C22 alcohols, similarly to earlier reported transitions in Brodie graphite oxide (BGO). The transitions correspond to a strong change of inter-layer distance correlating with the alcohol molecules length and change in molecules orientation from perpendicular to parallel to GO planes (Type II transitions). However, Type I swelling transitions (related to insertion/removal of one layer of alcohol molecules) reported earlier for BGO are not found in HGO. Continuous changes of the d(001) spacing are revealed for HGO immersed in all smaller alcohols in the range C1 (methanol) to C9 (nonanol).

Published
2024
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10. In operando study of microsupercapacitors with gel electrolytes using nano-beam synchrotron X-ray diffraction

Author

Li, Gui, Boulanger, Nicolas, Iakunkov, Artem, Xue, Han, Li, Jiantong, Tucoulou, Rémi, Talyzin, Aleksandr V., Li, Gui, Boulanger, Nicolas, Iakunkov, Artem, Xue, Han, Li, Jiantong, Tucoulou, Rémi, and Talyzin, Aleksandr V.

Abstract

Synchrotron radiation X-ray diffraction (XRD) with nanoscale beam size was used here for in situ and in operando study of micro-supercapacitors (MSC) with gel electrolyte and MXene Ti3C2Tx electrodes. The electrode structure was characterized as a function of applied voltage and distance from the gap separating electrodes using microscopic cells with cylindrical shape designed for transmission mode XRD. The devices with gel electrolytes based on H2SO4 (with H2O/PVA and DMSO/PVA) showed stable performance with no changes in MXene structure under voltage swaps between positive and negative values. Experiments with KI-based electrolytes demonstrated changes of MXene structure correlated with decrease of energy storage parameters under conditions of increased operation voltage starting from 0.8 V. The optimal performance of the MSCs was observed when the MXene structure remained unchanged upon switching the applied voltage polarity. The changes of inter-layer distance of MXene upon swap of applied voltage correlate with decrease of device performance and are undesirable for stable operation of MSC's. We also tested feasibility of X-ray fluorescence (XRF) for characterization of electrolyte ion migration in MSCs using 2D element mapping. Irreversible sorption of iodine by MXene was found using XRF mapping of charged electrodes using standard in-plane MSC device and KI electrolyte.

Published
2024
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11. Swelling of Ti3C2Tx mxene in water and methanol at extreme pressure conditions

Author

Iakunkov, Artem, Lienert, Ulrich, Sun, Jinhua, Talyzin, Aleksandr V., Iakunkov, Artem, Lienert, Ulrich, Sun, Jinhua, and Talyzin, Aleksandr V.

Abstract

Pressure-induced swelling has been reported earlier for several hydrophilic layered materials. MXene Ti3C2Tx is also a hydrophilic layered material composed by 2D sheets but so far pressure-induced swelling is reported for this material only under conditions of shear stress at MPa pressures. Here, high-pressure experiments are performed with MXenes prepared by two methods known to provide “clay-like” materials. MXene synthesized by etching MAX phase with HCl+LiF demonstrates the effect of pressure-induced swelling at 0.2 GPa with the insertion of additional water layer. The transition is incomplete with two swollen phases (ambient with d(001) = 16.7Å and pressure-induced with d(001) = 19.2Å at 0.2 GPa) co-existing up to the pressure point of water solidification. Therefore, the swelling transition corresponds to change from two-layer water intercalation (2L-phase) to a never previously observed three-layer water intercalation (3L-phase) of MXene. Experiments with MXene prepared by LiCl+HF etching have not revealed pressure-induced swelling in liquid water. Both MXenes also show no anomalous compressibility in liquid methanol. The presence of pressure-induced swelling only in one of the MXenes indicates that the HCl+LiF synthesis method is likely to result in higher abundance of hydrophilic functional groups terminating 2D titanium carbide.

Published
2024
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17. Rapid Aging of Bilayer Graphene Oxide

Author

Hu Lin, Artem Iakunkov, Nikolai Severin, Alexandr V. Talyzin, and Jürgen P. Rabe

Subjects
General Energy, Physical and Theoretical Chemistry, Condensed Matter Physics, Den kondenserade materiens fysik, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials
Abstract

Atomic force microscopy (AFM) imaging was used to study swelling of individual bilayer graphene oxide (GO) flakes in water and ethanol vapors. We found that within 5 days after sample deposition the swelling of bilayered Hummers GO (HGO) in ethanol vapors disappears nearly completely, whereas the swelling in water remains not affected. Swelling can therefore be used as a sensitive indicator of rapid aging of bilayered HGO, which occurs both in air and under inert gas. The surprising ability of 5-days-aged bilayered HGO to swell in water but not in ethanol fits to the effects observed in μm-thick GO membranes after several years of aging. Remarkably, bilayered Brodie GO (BGO) maintains swelling in ethanol after storing it under the same conditions as HGO. Moreover, we demonstrate that AFM can be used to detect hole defects in individual GO sheets. The BGO bilayer swelling in ethanol vapors starts either on the flake edges or in very few points, forming ∼2 Å height fronts, which propagate slowly within interlayer spaces in all directions. The increase of the average distance between HGO sheets occurs simultaneously all over the flake, demonstrating a high abundance of hole defects. Our results imply that the permeation path length in HGO membranes must be significantly shorter compared to BGO, which is important to take into account in the modeling of membrane permeation.

Published
2022
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19. Dynamic Networks of Cellulose Nanofibrils Enable Highly Conductive and Strong Polymer Gel Electrolytes for Lithium-Ion Batteries

Author

Wang, Zhen, Heasman, Patrick, Rostami, Jowan, Benselfelt, Tobias, Linares, Mathieu, Li, Hailong, Iakunkov, Artem, Sellman, Farhiya Alex, Östmans, Rebecca, Hamedi, Mahiar Max, Zozoulenko, Igor, Wågberg, Lars, Wang, Zhen, Heasman, Patrick, Rostami, Jowan, Benselfelt, Tobias, Linares, Mathieu, Li, Hailong, Iakunkov, Artem, Sellman, Farhiya Alex, Östmans, Rebecca, Hamedi, Mahiar Max, Zozoulenko, Igor, and Wågberg, Lars

Abstract

Tunable dynamic networks of cellulose nanofibrils (CNFs) are utilized to prepare high-performance polymer gel electrolytes. By swelling an anisotropically dewatered, but never dried, CNF gel in acidic salt solutions, a highly sparse network is constructed with a fraction of CNFs as low as 0.9%, taking advantage of the very high aspect ratio and the ultra-thin thickness of the CNFs (micrometers long and 2–4 nm thick). These CNF networks expose high interfacial areas and can accommodate massive amounts of the ionic conductive liquid polyethylene glycol-based electrolyte into strong homogeneous gel electrolytes. In addition to the reinforced mechanical properties, the presence of the CNFs simultaneously enhances the ionic conductivity due to their excellent strong water-binding capacity according to computational simulations. This strategy renders the electrolyte a room-temperature ionic conductivity of 0.61 ± 0.12 mS cm−1 which is one of the highest among polymer gel electrolytes. The electrolyte shows superior performances as a separator for lithium iron phosphate half-cells in high specific capacity (161 mAh g−1 at 0.1C), excellent rate capability (5C), and cycling stability (94% capacity retention after 300 cycles at 1C) at 60 °C, as well as stable room temperature cycling performance and considerably improved safety compared with commercial liquid electrolyte systems., QC 20231115

Published
2023
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20. Activated carbons with extremely high surface area produced from cones, bark and wood using the same procedure

Author

Li, Gui, Iakunkov, Artem, Boulanger, Nicolas, Lazar, Oana Andreea, Enachescu, Marius, Grimm, Alejandro, Talyzin, Aleksandr V., Li, Gui, Iakunkov, Artem, Boulanger, Nicolas, Lazar, Oana Andreea, Enachescu, Marius, Grimm, Alejandro, and Talyzin, Aleksandr V.

Abstract

Activated carbons have been previously produced from a huge variety of biomaterials often reporting advantages of using certain precursors. Here we used pine cones, spruce cones, larch cones and a pine bark/wood chip mixture to produce activated carbons in order to verify the influence of the precursor on properties of the final materials. The biochars were converted into activated carbons with extremely high BET surface area up to ∼3500 m2 g−1 (among the highest reported) using identical carbonization and KOH activation procedures. The activated carbons produced from all precursors demonstrated similar specific surface area (SSA), pore size distribution and performance to electrodes in supercapacitors. Activated carbons produced from wood waste appeared to be also very similar to “activated graphene” prepared by the same KOH procedure. Hydrogen sorption of AC follows expected uptake vs. SSA trends and energy storage parameters of supercapacitor electrodes prepared from AC are very similar for all tested precursors. It can be concluded that the type of precursor (biomaterial or reduced graphene oxide) has smaller importance for producing high surface area activated carbons compared to details of carbonization and activation. Nearly all kinds of wood waste provided by the forest industry can possibly be converted into high quality AC suitable for preparation of electrode materials.

Published
2023
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21. Effect of Chain Length on Swelling Transitions of Brodie Graphite Oxide in Liquid 1-Alcohols

Author

Iakunkov, A., Nordenström, A., Boulanger, N., Li, G., (0000-0001-6393-2778) Hennig, C., Jørgensen, M. R. V., Kantor, I., Talyzin, . A. V., Iakunkov, A., Nordenström, A., Boulanger, N., Li, G., (0000-0001-6393-2778) Hennig, C., Jørgensen, M. R. V., Kantor, I., and Talyzin, . A. V.

Abstract

Swelling is the most fundamental property of graphite oxides (GO). Here, a structural study of Brodie graphite oxide (BGO) swelling in a set of long chain 1-alcohols (named C11 to C22 according to the number of carbons) performed using synchrotron radiation X-ray diffraction at elevated temperatures is reported. Even the longest of tested alcohols (C22) is found to intercalate BGO with enormous expansion of the interlayer distance from ≈6Å up to ≈63Å, the highest expansion of GO lattice ever reported. Swelling transitions from low temperature alpha-phase to high temperature beta-phase are found for BGO in all alcohols in the C11–C22 set. The transitions correspond to decrease of inter-layer distance correlating with the length of alcohol molecules, and change in their orientation from perpendicular to GO planes to layered parallel to GO (Type II transitions). These transitions are very different compared to BGO swelling transitions (Type I) found in smaller alcohols and related to insertion/de-insertion of additional layer of alcohol parallel to GO. Analysis of general trends in the whole set of 1-alcohols (C1 to C22) shows that the 1-alcohol chain length defines the type of swelling transition with Type I found for alcohols with C<10 and Type II for C>10.

Published
2023

22. Swelling of Ti3C2Tx MXene in Water and Methanol at Extreme Pressure Conditions.

Author

Iakunkov, Artem, Lienert, Ulrich, Sun, Jinhua, and Talyzin, Alexandr V.

Subjects
TITANIUM carbide, SHEARING force, METHANOL, WATER pressure, FUNCTIONAL groups
Abstract

Pressure‐induced swelling has been reported earlier for several hydrophilic layered materials. MXene Ti3C2Tx is also a hydrophilic layered material composed by 2D sheets but so far pressure‐induced swelling is reported for this material only under conditions of shear stress at MPa pressures. Here, high‐pressure experiments are performed with MXenes prepared by two methods known to provide "clay‐like" materials. MXene synthesized by etching MAX phase with HCl+LiF demonstrates the effect of pressure‐induced swelling at 0.2 GPa with the insertion of additional water layer. The transition is incomplete with two swollen phases (ambient with d(001) = 16.7Å and pressure‐induced with d(001) = 19.2Å at 0.2 GPa) co‐existing up to the pressure point of water solidification. Therefore, the swelling transition corresponds to change from two‐layer water intercalation (2L‐phase) to a never previously observed three‐layer water intercalation (3L‐phase) of MXene. Experiments with MXene prepared by LiCl+HF etching have not revealed pressure‐induced swelling in liquid water. Both MXenes also show no anomalous compressibility in liquid methanol. The presence of pressure‐induced swelling only in one of the MXenes indicates that the HCl+LiF synthesis method is likely to result in higher abundance of hydrophilic functional groups terminating 2D titanium carbide. [ABSTRACT FROM AUTHOR]

Published
2024
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23. A Theoretical Investigation of the Polyaddition of an AB 2 +A 2 +B 4 Monomer Mixture.

Author

Karpov, Sergei V., Iakunkov, Artem, Chernyaev, Dmitry A., Kurbatov, Vladimir G., Malkov, Georgiy V., and Badamshina, Elmira R.

Subjects
*POLYMERS, *MONOMERS, *POLYMERIZATION, *DEGREE of polymerization, *ORGANIC semiconductors, *GENERATING functions, *MIXTURES, *POLYMER colloids
Abstract

Hyperbranched polymers (HBPs) are widely applied nowadays as functional materials for biomedicine needs, nonlinear optics, organic semiconductors, etc. One of the effective and promising ways to synthesize HBPs is a polyaddition of AB2+A2+B4 monomers that is generated in the A2+CB2, AA′+B3, A2+B′B2, and A2+C2+B3 systems or using other approaches. It is clear that all the foundational features of HBPs that are manufactured by a polyaddition reaction are defined by the component composition of the monomer mixture. For this reason, we have designed a structural kinetic model of AB2+A2+B4 monomer mixture polyaddition which makes it possible to predict the impact of the monomer mixture's composition on the molecular weight characteristics of hyperbranched polymers (number average (DPn) and weight average (DPw) degree of polymerization), as well as the degree of branching (DB) and gel point (pg). The suggested model also considers the possibility of a positive or negative substitution effect during polyaddition. The change in the macromolecule parameters of HBPs formed by polyaddition of AB2+A2+B4 monomers is described as an infinite system of kinetic equations. The solution for the equation system was found using the method of generating functions. The impact of both the component's composition and the substitution effect during the polyaddition of AB2+A2+B4 monomers on structural and molecular weight HBP characteristics was investigated. The suggested model is fairly versatile; it makes it possible to describe every possible case of polyaddition with various monomer combinations, such as A2+AB2, AB2+B4, AB2, or A2+B4. The influence of each monomer type on the main characteristics of hyperbranched polymers that are obtained by the polyaddition of AB2+A2+B4 monomers has been investigated. Based on the results obtained, an empirical formula was proposed to estimate the pg = pA during the polyaddition of an AB2+A2+B4 monomer mixture: pg = pA = (−0.53([B]0/[A]0)1/2 + 0.78)υAB2 + (1/3)1/2([B]0/[A]0)1/2, where (1/3)1/2([B]0/[A]0)1/2 is the Flory equation for the A2+B4 polyaddition, [A]0 and [B]0 are the A and B group concentration from A2 and B4, respectively, and υAB2 is the mole fraction of the AB2 monomer in the mixture. The equation obtained allows us to accurately predict the pg value, with an AB2 monomer content of up to 80%. [ABSTRACT FROM AUTHOR]

Published
2024
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24. Dynamic Networks of Cellulose Nanofibrils Enable Highly Conductive and Strong Polymer Gel Electrolytes for Lithium‐Ion Batteries

Author

Wang, Zhen, primary, Heasman, Patrick, additional, Rostami, Jowan, additional, Benselfelt, Tobias, additional, Linares, Mathieu, additional, Li, Hailong, additional, Iakunkov, Artem, additional, Sellman, Farhiya, additional, Östmans, Rebecca, additional, Hamedi, Mahiar Max, additional, Zozoulenko, Igor, additional, and Wågberg, Lars, additional

Published
2023
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26. High-surface-area activated carbon from pine cones for semi-industrial spray deposition of supercapacitor electrodes

Author

Andreas Nordenström, Nicolas Boulanger, Artem Iakunkov, Gui Li, Roman Mysyk, Gaetan Bracciale, Paolo Bondavalli, and Alexandr V. Talyzin

Subjects
Annan materialteknik, General Engineering, Other Materials Engineering, General Materials Science, Bioengineering, General Chemistry, Atomic and Molecular Physics, and Optics
Abstract

High surface area carbons are so far the best materials for industrial manufacturing of supercapacitor electrodes. Here we demonstrate that pine cones, an abundant bio-precursor currently considered as a waste in the wood industry, can be used to prepare activated carbons with a BET surface area exceeding 3000 m2 g−1. It is found that the same KOH activation procedure applied to reduced graphene oxide (rGO) and pine cone derived biochars results in carbon materials with a similar surface area, pore size distribution and performance in supercapacitor (SC) electrodes. It can be argued that “activated graphene” and activated carbon are essentially the same kind of material with a porous 3D structure. It is demonstrated that the pine cone derived activated carbon (PC-AC) can be used as a main part of aqueous dispersions stabilized by graphene oxide for spray deposition of electrodes. The PC-AC based electrodes prepared using a semi-industrial spray gun machine and laboratory scale blade deposition of these dispersions were compared to pellet electrodes.

Published
2022
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27. Activated carbons with extremely high surface area produced from cones, bark and wood using the same procedure

Author

Gui Li, Artem Iakunkov, Nicolas Boulanger, Oana Andreea Lazar, Marius Enachescu, Alejandro Grimm, and Alexandr V. Talyzin

Subjects
General Chemical Engineering, Biomaterials Science, Materials Chemistry, Materialkemi, General Chemistry
Abstract

Activated carbons have been previously produced from a huge variety of biomaterials often reporting advantages of using certain precursors. Here we used pine cones, spruce cones, larch cones and a pine bark/wood chip mixture to produce activated carbons in order to verify the influence of the precursor on properties of the final materials. The biochars were converted into activated carbons with extremely high BET surface area up to similar to 3500 m(2) g(-1) (among the highest reported) using identical carbonization and KOH activation procedures. The activated carbons produced from all precursors demonstrated similar specific surface area (SSA), pore size distribution and performance to electrodes in supercapacitors. Activated carbons produced from wood waste appeared to be also very similar to "activated graphene" prepared by the same KOH procedure. Hydrogen sorption of AC follows expected uptake vs. SSA trends and energy storage parameters of supercapacitor electrodes prepared from AC are very similar for all tested precursors. It can be concluded that the type of precursor (biomaterial or reduced graphene oxide) has smaller importance for producing high surface area activated carbons compared to details of carbonization and activation. Nearly all kinds of wood waste provided by the forest industry can possibly be converted into high quality AC suitable for preparation of electrode materials.

Published
2023

29. One-Pot Synthesis of Hyperbranched Polyurethane-Triazoles with Controlled Structural, Molecular Weight and Hydrodynamic Characteristics

Author

Sergei V. Karpov, Artem Iakunkov, Alexander V. Akkuratov, Artem O. Petrov, Eugenia O. Perepelitsina, Georgiy V. Malkov, and Elmira R. Badamshina

Subjects
Polymers and Plastics, General Chemistry, hyperbranched polymers, polyurethane-triazoles, degree of branching, polyaddition
Abstract

We report a simple and convenient approach to the one-pot synthesis of hyperbranched polyurethane-triazoles with desirable properties. This method is based on in situ generation of an AB2 + A2 + B4 azide-acetylene monomer mixture of known composition, due to quantitative reactions of urethane formation between isophorone diisocyanate (IPDI), 1,3-diazidopropanol-2 (DAPOL) (in the first stage) and propargyl alcohol (in the second stage). The obtained monomer mixture can be involved in step-growth polymerization by azide-alkyne cycloaddition without additional purification (in the third stage). The properties of the resulting polymers should depend on the composition of the monomer mixture. Therefore, first the model revealing the correlation between the monomer composition and the ratio and reactivity of the IPDI and DAPOL active groups is developed and proven. In addition, the newly developed structural kinetic model considering the substitution effect at polyaddition of the complex mixture of monomers allows the prediction of the degree of branching of the target polymer. Based on our calculations, the hyperbranched polyurethane-triazoles were synthesized under found conditions. All products were characterized by 1H NMR, FTIR, SEC, DLS, DSC, TGA and viscometry methods. It was shown that the degree of branching, molecular weight, intrinsic viscosity, and hydrodynamic radius of the final hyperbranched polymers can be specified at the first stage of one-pot synthesis. The obtained hyperbranched polyurethane-triazoles showed a degree of branching from 0.21 to 0.44 (calculated DB-0.25 and 0.45, respectively).

Published
2022
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32. Temperature-dependent swelling transitions in MXene Ti

Author

Artem, Iakunkov, Andreas, Nordenström, Nicolas, Boulanger, Christoph, Hennig, Igor, Baburin, and Alexandr V, Talyzin

Abstract

Swelling is a property of hydrophilic layered materials, which enables the penetration of polar solvents into an interlayer space with expansion of the lattice. Here we report an irreversible swelling transition, which occurs in MXenes immersed in excess dimethyl sulfoxide (DMSO) upon heating at 362-370 K with an increase in the interlayer distance by 4.2 Å. The temperature dependence of MXene Ti

Published
2022

33. Swollen Structures of Brodie Graphite Oxide as Solid Solvates

Author

Alexandr V. Talyzin, Artem Iakunkov, Anastasiya T. Rebrikova, Mikhail V. Korobov, Jinhua Sun, Natalya V. Avramenko, and Alexey Klechikov

Subjects
Fysikalisk kemi, Diffraction, Thermogravimetric analysis, Materials science, Graphite oxide, Condensed Matter Physics, Physical Chemistry, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, General Energy, chemistry, medicine, Methanol, Physical and Theoretical Chemistry, Swelling, medicine.symptom, Den kondenserade materiens fysik, Nuclear chemistry
Abstract

Swelling of Brodie graphite oxide (B-GO) was studied for a series of normal alcohols from methanol to 1-nonanol. Isopiestic, X-ray diffraction (XRD), thermogravimetric, and differential scanning calorimetry data demonstrated that sorption of polar liquids into GO lamellas formed the set of regular swollen structures, simple binary “solid solvates”, characterized by the distance between the GO planes and the value of sorption. Temperature–composition behavior of the swollen structures was adequately described by conventional binary phase diagrams. Phase transformation of the low-temperature swollen structure of B-GO with 1-nonanol gave a clear example of incongruent melting transition typical for the binary solvates. A discreet set of the interplane distances observed by XRD and the stepwise equilibrium desorption pointed to the layered arrangement of solvent molecules in the swollen structures. The swollen structures with one to five parallel layers were observed for a series of normal alcohols with B-GO. The average volume of one layer, 0.36 ± 0.06 cm3 g–1 B-GO, was almost the same for rather different organic liquids and was possibly restricted by the internal geometry of B-GO. This internal volume available for the sorption of the first layer was reasonably estimated from geometrical parameters of B-GO.

Published
2020
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35. Temperature-dependent swelling transitions in MXene Ti3C2Tx

Author

Iakunkov, Artem, Nordenström, Andreas, Boulanger, Nicolas, Hennig, Christoph, Baburin, Igor, Talyzin, Aleksandr V., Iakunkov, Artem, Nordenström, Andreas, Boulanger, Nicolas, Hennig, Christoph, Baburin, Igor, and Talyzin, Aleksandr V.

Abstract

Swelling is a property of hydrophilic layered materials, which enables the penetration of polar solvents into an interlayer space with expansion of the lattice. Here we report an irreversible swelling transition, which occurs in MXenes immersed in excess dimethyl sulfoxide (DMSO) upon heating at 362-370 K with an increase in the interlayer distance by 4.2 Å. The temperature dependence of MXene Ti3C2Tx swelling in several polar solvents was studied using synchrotron radiation X-ray diffraction. MXenes immersed in excess DMSO showed a step-like increase in the interlayer distance from 17.73 Å at 280 K to 22.34 Å above ∼362 K. The phase transformation corresponds to a transition from the MXene structure with one intercalated DMSO layer into a two-layer solvate phase. The transformation is irreversible and the expanded phase remains after cooling back to room temperature. A similar phase transformation was observed also for MXene immersed in a 2 : 1 H2O : DMSO solvent ratio but at a lower temperature. The structure of MXene in the mixed solvent below 328 K was affected by the interstratification of differently hydrated (H2O)/solvated (DMSO) layers. Above the temperature of the transformation, the water was expelled from MXene interlayers and the formation of a pure two-layer DMSO-MXene phase was found. No changes in the swelling state were observed for MXenes immersed in DMSO or methanol at temperatures below ambient down to 173 K. Notably, MXenes do not swell in 1-alcohols larger than ethanol at ambient temperature. Changing the interlayer distance of MXenes by simple temperature cycling can be useful in membrane applications, e.g. when a larger interlayer distance is required for the penetration of ions and molecules into membranes. Swelling is also very important in electrode materials since it allows penetration of the electrolyte ions into the interlayers of the MXene structure.

Published
2022
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36. High Surface Area '3D Graphene Oxide' for Enhanced Sorption of Radionuclides

Author

Boulanger, Nicolas, Kuzenkova, Anastasiia S., Iakunkov, Artem, Nordenström, Andreas, Romanchuk, Anna Yu., Trigub, Alexander L., Zasimov, Pavel V., Prodana, Mariana, Enachescu, Marius, Bauters, Stephen, Amidani, Lucia, Kvashnina, Kristina O., Kalmykov, Stepan N., Talyzin, Aleksandr V., Boulanger, Nicolas, Kuzenkova, Anastasiia S., Iakunkov, Artem, Nordenström, Andreas, Romanchuk, Anna Yu., Trigub, Alexander L., Zasimov, Pavel V., Prodana, Mariana, Enachescu, Marius, Bauters, Stephen, Amidani, Lucia, Kvashnina, Kristina O., Kalmykov, Stepan N., and Talyzin, Aleksandr V.

Abstract

Here preparation of high surface area activated reduced graphene oxide (arGO) oxidized into a 3D analogue of defect-rich GO (dGO) is reported. Surface oxidation of arGO results in carbon to oxygen ratio C/O = 3.3, similar to the oxidation state of graphene oxide while preserving high BET surface area of about 880 m2 g−1. Analysis of surface oxidized arGO shows high abundance of oxygen functional groups which converts hydrophobic precursor into hydrophilic material. High surface area carbons provide the whole surface for oxidation without the need of intercalation and lattice expansion. Therefore, surface oxidation methods are sufficient to convert the materials into 3D architectures with chemical properties similar to graphene oxide. The "3D graphene oxide" shows high sorption capacity for U(VI) removal in an extraordinary broad interval of pH. Notably, the surface oxidized carbon material has a rigid 3D structure with micropores accessible for penetration of radionuclide ions. Therefore, the bulk "3D GO" can be used as a sorbent directly without dispersing, the step required for GO to make its surface area accessible for pollutants., This article also appears in: "Hot Topic: Carbon, Graphite, and Graphene"

Published
2022
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37. One-Pot Synthesis of Hyperbranched Polyurethane-Triazoles with Controlled Structural, Molecular Weight and Hydrodynamic Characteristics

Author

Karpov, Sergei, V, Iakunkov, Artem, Akkuratov, Alexander, V, Petrov, Artem O., Perepelitsina, Eugenia O., Malkov, Georgiy, V, Badamshina, Elmira R., Karpov, Sergei, V, Iakunkov, Artem, Akkuratov, Alexander, V, Petrov, Artem O., Perepelitsina, Eugenia O., Malkov, Georgiy, V, and Badamshina, Elmira R.

Abstract

We report a simple and convenient approach to the one-pot synthesis of hyperbranched polyurethane-triazoles with desirable properties. This method is based on in situ generation of an AB(2) + A(2) + B-4 azide-acetylene monomer mixture of known composition, due to quantitative reactions of urethane formation between isophorone diisocyanate (IPDI), 1,3-diazidopropanol-2 (DAPOL) (in the first stage) and propargyl alcohol (in the second stage). The obtained monomer mixture can be involved in step-growth polymerization by azide-alkyne cycloaddition without additional purification (in the third stage). The properties of the resulting polymers should depend on the composition of the monomer mixture. Therefore, first the model revealing the correlation between the monomer composition and the ratio and reactivity of the IPDI and DAPOL active groups is developed and proven. In addition, the newly developed structural kinetic model considering the substitution effect at polyaddition of the complex mixture of monomers allows the prediction of the degree of branching of the target polymer. Based on our calculations, the hyperbranched polyurethane-triazoles were synthesized under found conditions. All products were characterized by H-1 NMR, FTIR, SEC, DLS, DSC, TGA and viscometry methods. It was shown that the degree of branching, molecular weight, intrinsic viscosity, and hydrodynamic radius of the final hyperbranched polymers can be specified at the first stage of one-pot synthesis. The obtained hyperbranched polyurethane-triazoles showed a degree of branching from 0.21 to 0.44 (calculated DB-0.25 and 0.45, respectively)., QC 20221130

Published
2022
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38. High-surface-area activated carbon from pine cones for semi-industrial spray deposition of supercapacitor electrodes

Author

Nordenström, Andreas, Boulanger, Nicolas, Iakunkov, Artem, Li, Gui, Mysyk, Roman, Bracciale, Gaetan, Bondavalli, Paolo, Talyzin, Aleksandr V., Nordenström, Andreas, Boulanger, Nicolas, Iakunkov, Artem, Li, Gui, Mysyk, Roman, Bracciale, Gaetan, Bondavalli, Paolo, and Talyzin, Aleksandr V.

Abstract

High surface area carbons are so far the best materials for industrial manufacturing of supercapacitor electrodes. Here we demonstrate that pine cones, an abundant bio-precursor currently considered as a waste in the wood industry, can be used to prepare activated carbons with a BET surface area exceeding 3000 m2 g−1. It is found that the same KOH activation procedure applied to reduced graphene oxide (rGO) and pine cone derived biochars results in carbon materials with a similar surface area, pore size distribution and performance in supercapacitor (SC) electrodes. It can be argued that “activated graphene” and activated carbon are essentially the same kind of material with a porous 3D structure. It is demonstrated that the pine cone derived activated carbon (PC-AC) can be used as a main part of aqueous dispersions stabilized by graphene oxide for spray deposition of electrodes. The PC-AC based electrodes prepared using a semi-industrial spray gun machine and laboratory scale blade deposition of these dispersions were compared to pellet electrodes.

Published
2022
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39. Temperature dependent swelling transitions in MXene Ti3C2Tx

Author

Iakunkov, A., Nordenström, A., Boulanger, N., (0000-0001-6393-2778) Hennig, C., Baburin, I., Talyzin, A., Iakunkov, A., Nordenström, A., Boulanger, N., (0000-0001-6393-2778) Hennig, C., Baburin, I., and Talyzin, A.

Abstract

Swelling is a property of hydrophilic layered materials, which enables the penetration of polar solvents into an interlayer space with expansion of the lattice. Here we report an irreversible swelling transition, which occurs in MXenes immersed in excess dimethyl sulfoxide (DMSO) upon heating at 362-370 K with an increase in the interlayer distance by 4.2 Å. The temperature dependence of MXene Ti3C2Tx swelling in several polar solvents was studied using synchrotron radiation X-ray diffraction. MXenes immersed in excess DMSO showed a step-like increase in the interlayer distance from 17.73 Å at 280 K to 22.34 Å above ∼362 K. The phase transformation corresponds to a transition from the MXene structure with one intercalated DMSO layer into a two-layer solvate phase. The transformation is irreversible and the expanded phase remains after cooling back to room temperature. A similar phase transformation was observed also for MXene immersed in a 2 : 1 H2O : DMSO solvent ratio but at a lower temperature. The structure of MXene in the mixed solvent below 328 K was affected by the interstratification of differently hydrated (H2O)/solvated (DMSO) layers. Above the temperature of the transformation, the water was expelled from MXene interlayers and the formation of a pure two-layer DMSO-MXene phase was found. No changes in the swelling state were observed for MXenes immersed in DMSO or methanol at temperatures below ambient down to 173 K. Notably, MXenes do not swell in 1-alcohols larger than ethanol at ambient temperature. Changing the interlayer distance of MXenes by simple temperature cycling can be useful in membrane applications, e.g. when a larger interlayer distance is required for the penetration of ions and molecules into membranes. Swelling is also very important in electrode materials since it allows penetration of the electrolyte ions into the interlayers of the MXene structure.

Published
2022

40. High surface area “3D Graphene Oxide” for enhanced sorption of radionuclides

Author

Boulanger, N., Kuzenkova, A. S., Iakunkov, A., Nordenström, A., Romanchuk, A. Y., Trigub, A. L., Zasimov, P. V., Podana, M., Enachescu, M., Bauters, S., Amidani, L., Kvashnina, K. O., Kalmykov, S. N., Talyzin, A. V., Boulanger, N., Kuzenkova, A. S., Iakunkov, A., Nordenström, A., Romanchuk, A. Y., Trigub, A. L., Zasimov, P. V., Podana, M., Enachescu, M., Bauters, S., Amidani, L., Kvashnina, K. O., Kalmykov, S. N., and Talyzin, A. V.

Abstract

Earlier studies demonstrated that graphene oxide (GO) with large number of defects is favorable for the sorption of radionuclides. Here we report oxidation treatment which converts high surface area activated reduced graphene oxide (arGO) into a 3D analogue of defect-rich GO (dGO). Oxidation of arGO using ammonium persulfate results in oxidation corresponding to carbon to oxygen ratio C/O=3.3, similar to the oxidation state of graphene oxide while preserving high BET surface area of about 880 m2/g. Analysis of surface oxidized arGO shows high abundance of oxygen functional groups very similar to dGO and hydrophilic properties. The “3D graphene oxide” showed high sorption capacity for U(VI) removal in an extraordinary broad interval of pH. Notably, the surface oxidized carbon material has a rigid 3D structure with micropores accessible for penetration of radionuclide ions. Therefore, the bulk “3D GO” can be used as a sorbent directly without dispersing, the step required for GO to make its surface area accessible for pollutants

Published
2022

41. High Surface Area “3D Graphene Oxide” for Enhanced Sorption of Radionuclides (Adv. Mater. Interfaces 18/2022)

Author

Boulanger, Nicolas, primary, Kuzenkova, Anastasiia S., additional, Iakunkov, Artem, additional, Nordenström, Andreas, additional, Romanchuk, Anna Yu., additional, Trigub, Alexander L., additional, Zasimov, Pavel V., additional, Prodana, Mariana, additional, Enachescu, Marius, additional, Bauters, Stephen, additional, Amidani, Lucia, additional, Kvashnina, Kristina O., additional, Kalmykov, Stepan N., additional, and Talyzin, Alexandr V., additional

Published
2022
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42. Temperature-dependent swelling transitions in MXene Ti3C2Tx

Author

Artem Iakunkov, Andreas Nordenström, Nicolas Boulanger, Christoph Hennig, Igor Baburin, and Alexandr V. Talyzin

Subjects
Materials Chemistry, Materialkemi, General Materials Science, Condensed Matter Physics, Den kondenserade materiens fysik
Abstract

Swelling is a property of hydrophilic layered materials, which enables the penetration of polar solvents into an interlayer space with expansion of the lattice. Here we report an irreversible swelling transition, which occurs in MXenes immersed in excess dimethyl sulfoxide (DMSO) upon heating at 362-370 K with an increase in the interlayer distance by 4.2 Å. The temperature dependence of MXene Ti3C2Tx swelling in several polar solvents was studied using synchrotron radiation X-ray diffraction. MXenes immersed in excess DMSO showed a step-like increase in the interlayer distance from 17.73 Å at 280 K to 22.34 Å above ∼362 K. The phase transformation corresponds to a transition from the MXene structure with one intercalated DMSO layer into a two-layer solvate phase. The transformation is irreversible and the expanded phase remains after cooling back to room temperature. A similar phase transformation was observed also for MXene immersed in a 2 : 1 H2O : DMSO solvent ratio but at a lower temperature. The structure of MXene in the mixed solvent below 328 K was affected by the interstratification of differently hydrated (H2O)/solvated (DMSO) layers. Above the temperature of the transformation, the water was expelled from MXene interlayers and the formation of a pure two-layer DMSO-MXene phase was found. No changes in the swelling state were observed for MXenes immersed in DMSO or methanol at temperatures below ambient down to 173 K. Notably, MXenes do not swell in 1-alcohols larger than ethanol at ambient temperature. Changing the interlayer distance of MXenes by simple temperature cycling can be useful in membrane applications, e.g. when a larger interlayer distance is required for the penetration of ions and molecules into membranes. Swelling is also very important in electrode materials since it allows penetration of the electrolyte ions into the interlayers of the MXene structure.

Published
2022

45. New Kinetic Model of Polyaddition of Asymmetric ABВ/ Monomer in the Presence of Trifunctional Core with Substitution Effect

Author

Sergei V. Karpov, A.G. Iakunkov, and G. V. Malkov

Subjects
Kinetic model, Mechanical Engineering, Kinetic analysis, Hyperbranched polymers, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Core (optical fiber), chemistry.chemical_compound, Monomer, chemistry, Mechanics of Materials, Polymer chemistry, General Materials Science, Substitution effect, 0210 nano-technology
Abstract

Three-dimensional step polymerization of ABB/ and В3 monomers (ABB/+В3) was described using the new structural-kinetic model. Polymerization process was simulated with the variation of reactivity of B groups in the ABB/ and B3 monomers during the process (substitution effect). Polymerization simulation with substitution effect represents the most general case of three-dimensional step polymerization ABB/+В3.

Published
2019
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46. Carboxyl groups do not play the major role in binding metal cations by graphene oxide

Author

Ayrat M. Dimiev, Alexandr V. Talyzin, Artem Iakunkov, Julia Shayimova, and Rustem Amirov

Subjects
Aqueous solution, Graphene, Chemistry, Metal ions in aqueous solution, Oxide, General Physics and Astronomy, Exfoliation joint, law.invention, Metal, chemistry.chemical_compound, law, visual_art, Polymer chemistry, visual_art.visual_art_medium, Physical and Theoretical Chemistry, Solubility, Bond cleavage
Abstract

In this study, we investigate the chemical interactions of Mn2+ ions with graphene oxides, prepared by Hummers' (HGO) and Brodie's (BGO) methods in aqueous solutions by means of NMR relaxation. Carboxyl groups, which are always present in HGO in significant quantities, are often considered as the main binding sites for metal ions. Here we demonstrate that metal ions are bound efficiently by BGO, containing a negligibly small quantity of carboxyl groups. The difference in the shape of the relaxation curves is due mostly to the difference in the solubility and exfoliation degree of the two GO samples in aqueous media. HGO binds Mn2+ in the broad pH range, including highly acidic solutions, while BGO binds only at pH > 6, since it is not dispersible in water at lower pH values. The ability of BGO to chemically bind Mn2+ despite lacking sulfate and carboxyl groups, coupled with our earlier published findings, strongly suggests that carboxyl groups do not play the main role in binding metal ions by GO, as is commonly believed. We propose that metal ions initiate a significant transformation in the GO structure to attain the most efficient coordination of metal ions. This reorganization might involve the metal cation induced C–C bond cleavage with the formation of enols at the newly formed edges.

Published
2021

47. Materials prepared using graphite oxides : properties and applications

Author

Iakunkov, Artem

Subjects
Supercapacitor, Sorption of radionuclides, Materialteknik, Activated Graphene, Materials Engineering, Swelling, Condensed Matter Physics, Den kondenserade materiens fysik, Graphene oxide
Abstract

Graphite oxides are hydrophilic materials, which have attracted a lot of attention due to unique properties and possible applications. The current thesis includes studies of fundamental properties and applications of graphite oxides as well as materials prepared from graphite oxides such as graphene oxide membranes, defect-rich graphite oxide, reduced graphene oxide and activated reduced graphene oxide. We have studied Hummers and Brodie graphite oxides swelling in a set of normal alcohols from methanol to 1-nonanol using XRD, TGA, DSC, vapour and liquid sorption. Swollen structures with one to five parallel layers of intercalated alcohol molecules were found for Brodie graphite oxide immersed in liquid alcohols. Phase transitions between some of these phases were observed at low temperatures. Brodie graphite oxide was also studied for swelling in molten sugar alcohols. We have demonstrated the formation of an expanded structure of graphite oxide intercalated by molten xylitol and sorbitol. The structure remains stable at ambient conditions after the melt solidification. The swelling of graphite oxide was also investigated in tetrafluoroborate solution in acetonitrile, the solution used as a common electrolyte in energy storage applications. Graphite oxide in these experiments served as a model system due to flexible "pores" provided by temperature-dependent swelling in acetonitrile. Intercalation of electrolyte ions into GO structure resulted in a formation of distinct phase with expanded inter-layer distance. Results of our experiments allow to evaluate minimal “pore size” required to accommodate electrolyte ions in solvate and desolvated states. Swelling pressure is one of the fundamental properties of graphite oxide, which has not been reported previously but important in applications involving swelling under confinement conditions. Significant pressures up to 220bar were measured for bulk graphite oxide due to swelling in water and ethanol. Swelling pressure in the range 3-25 bar was also measured for μm thick membranes. Both powder and membrane samples showed a significant difference in kinetics of building pressure in water and ethanol. Ageing effects were studied using graphene oxide membranes stored on air over prolonged periods starting from weeks and up to five years. The pronounced effects of ageing on chemical composition and swelling of graphene oxide membranes in a set of alcohols (methanol to 1-nonanol) were found. These effects were assigned to chemical modification during air storage rather than to intrinsic metastability of graphene oxide. The structural changes related to the chemical modification of graphene oxide on air are crucial for membrane applications because they significantly affect the size of “permeation channels” provided by swelling. Extremely defective graphene oxide was demonstrated as a promising material for sorbent applications. The defect-rich graphene oxide was prepared using Hummers oxidation of strongly defective reduced graphite oxide instead of well crystalline graphite. The defect-rich graphene oxide showed significant improvement in sorption of radionuclides (U(VI), Am(III), and Eu(III)) compared to standard graphite oxides. High abundance of defects was demonstrated to correlate with the maximal sorption capacity of graphite oxide towards radionuclides and methylene blue. Finally, we have studied activated reduced graphene oxide for application in supercapacitors. This study aimed to reveal correlations between structural parameters of electrode material and supercapacitor performance. We have prepared two sets of materials with a broad range of N2 BET surface area 1000-3000m2g-1 , significant variation of pore size distribution and oxygen content using change of activation temperature and post-synthesis mechanical treatment. Analysis of nitrogen and water sorption isotherms showed that despite negligibly small H2O BET surface area, the total pore volume is very similar for nitrogen and water sorption. The best supercapacitor performance was found to depend on combination of several parameters in a delicate balance of specific surface area, oxygen content, micropore volume and conductivity

Published
2021

48. Intercalation of Dyes in Graphene Oxide Thin Films and Membranes

Author

Alexandr V. Talyzin, Artem Iakunkov, Alexey Klechikov, Alexei Vorobiev, Andreas Nordenström, Nicolas Boulanger, and Igor A. Baburin

Subjects
Materials science, Intercalation (chemistry), Oxide, Graphite oxide, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Physical Chemistry, Article, law.invention, chemistry.chemical_compound, law, Graphite, Physical and Theoretical Chemistry, Fysikalisk kemi, Graphene, Sorption, Permeation, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, General Energy, Membrane, chemistry, Chemical engineering, 0210 nano-technology
Abstract

Intercalation of dyes into thin multilayered graphene oxide (GO) films was studied by neutron reflectivity and X-ray diffraction. Methylene blue (MB) penetrates the interlayer space of GO in ethanol solution and remains intercalated after the solvent evaporation, as revealed by the expansion of the interlayer lattice and change in chemical composition. The sorption of MB by thin GO films is found to be significantly stronger compared to the sorption of Crystal violet (CV) and Rose bengal (RB). This effect is attributed to the difference in the geometrical shape of planar MB and essentially nonflat CV and RB molecules. Graphite oxides and restacked GO films are found to exhibit different methylene blue (MB) sorptions. MB sorption by precursor graphite oxide and thin spin-coated films of GO is significantly stronger compared to freestanding micrometer-thick membranes prepared by vacuum filtration. Nevertheless, the sorption capacity of GO membranes is sufficient to remove a significant part of the MB from diluted solutions tested for permeation in several earlier studies. High sorption capacity results in strong modification of the GO structure, which is likely to affect permeation properties of GO membranes. Therefore, MB is not suitable for testing size exclusion effects in the permeation of GO membranes. It is not only hydration or solvation diameter but also the exact geometrical shape of molecules that needs to be taken into account considering size effects for penetration of molecules between GO layers in membrane applications.

Published
2021

49. Facile fabrication of graphene-based high-performance microsupercapacitors operating at a high temperature of 150 °C

Author

Szymon Sollami Delekta, Jiantong Li, Nicolas Boulanger, Viktoriia Mishukova, Xiaodong Zhuang, Alexandr V. Talyzin, and Artem Iakunkov

Subjects
Materials science, Fabrication, Materialkemi, Bioengineering, 02 engineering and technology, Temperature cycling, 010402 general chemistry, 01 natural sciences, 7. Clean energy, Capacitance, Physical Chemistry, Energy storage, law.invention, law, Materials Chemistry, Fysik, General Materials Science, Thermal stability, Electronic circuit, Fysikalisk kemi, Graphene, business.industry, General Engineering, General Chemistry, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Physical Sciences, Optoelectronics, Degradation (geology), 0210 nano-technology, business
Abstract

Many industry applications require electronic circuits and systems to operate at high temperatures over 150 °C. Although planar microsupercapacitors (MSCs) have great potential for miniaturized on-chip integrated energy storage components, most of the present devices can only operate at low temperatures (

Published
2021

50. Enhanced Sorption of Radionuclides by Defect-Rich Graphene Oxide

Author

Stephen Bauters, Anna Yu. Romanchuk, Kristina O. Kvashnina, Alexander V. Egorov, Alexander L. Trigub, Alexandr V. Talyzin, Anastasiia S. Kuzenkova, Marius Retegan, Artem Iakunkov, Nicolas Boulanger, Stepan N. Kalmykov, and Lucia Amidani

Subjects
Solid-state chemistry, Materials science, Sorbent, Oxide, chemistry.chemical_element, Materialkemi, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, law.invention, uranium, chemistry.chemical_compound, law, Materials Chemistry, General Materials Science, radionuclides, defects, sorption, Graphene, Radioactive waste, Sorption, Uranium, Contamination, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, chemistry, Environmental chemistry, graphene oxide, 0210 nano-technology, Den kondenserade materiens fysik, Research Article
Abstract

Extremely defect graphene oxide (dGO) is proposed as an advanced sorbent for treatment of radioactive waste and contaminated natural waters. dGO prepared using a modified Hummers oxidation procedure, starting from reduced graphene oxide (rGO) as a precursor, shows significantly higher sorption of U(VI), Am(III), and Eu(III) than standard graphene oxides (GOs). Earlier studies revealed the mechanism of radionuclide sorption related to defects in GO sheets. Therefore, explosive thermal exfoliation of graphite oxide was used to prepare rGO with a large number of defects and holes. Defects and holes are additionally introduced by Hummers oxidation of rGO, thus providing an extremely defect-rich material. Analysis of characterization by XPS, TGA, and FTIR shows that dGO oxygen functionalization is predominantly related to defects, such as flake edges and edge atoms of holes, whereas standard GO exhibits oxygen functional groups mostly on the planar surface. The high abundance of defects in dGO results in a 15-fold increase in sorption capacity of U(VI) compared to that in standard Hummers GO. The improved sorption capacity of dGO is related to abundant carboxylic group attached hole edge atoms of GO flakes as revealed by synchrotron-based extended X-ray absorption fine structure (EXAFS) and high-energy resolution fluorescence detected X-ray absorption near edge structure (HERFD-XANES) spectroscopy.

Published
2020

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