A Hyphenated Approach Combining Pressure-Decay and <i>In Situ</i> FT-NIR Spectroscopy to Monitor Penetrant Sorption and Concurrent Swelling in Polymers

Loianno, Valerio; Baldanza, Antonio; Scherillo, Giuseppe; Jamaledin, Rezvan; Musto, Pellegrino; Mensitieri, Giuseppe

doi:10.1021/acs.iecr.1c00264

Cited by 6 publications

(8 citation statements)

References 31 publications

(46 reference statements)

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“…Our results are in excellent agreement with those from Story and Koros as expected since the sample preparation method was the same and the density of the two amorphous samples were very close (1.068 g cm -3 for our samples vs a value of 1.063 g cm -3 in the case of the samples used by Story and Koros) [7,40]. Conversely, the solubility data reported by Galizia et al [38] are systematically lower than the ones we obtained and, specifically, in the case of carbon dioxide and methane an average reduction of 20% and 76% of the solubility coefficient is observed, respectively. The reason lies in the different method of preparation of the samples that in [38] were melt at 290°C and then compression molded, thus resulting in a lower film density equal to 1.016 g cm -3 .…”

Section: Sorption Of Pure Co2 and Ch4 In Pposupporting

confidence: 92%

“…The concentration of the gas is evaluated from the NIST Standard Reference Database 69: NIST Chemistry WebBook [37]. The same approach has been already adopted to investigate the sorption of CO2 in polydimethylsiloxane [38]. In that case, a single polymer slab was tested while, in the present case, multiple pieces of PPO were inserted into the volume of the measuring chamber to reduce the uncertainty of the solubility measurement.…”

Section: Sorption Of Pure Co2 and Ch4 In Ppomentioning

confidence: 99%

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Sorption of CO2, CH4 and their mixtures in Amorphous Poly(2,6-dimethyl-1,4-phenylene)oxide (PPO)

Loianno¹,

Baldanza²,

Scherillo³

et al. 2023

Preprint

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Sorption of pure CO2 and CH4 and CO2/CH4 binary gas mixtures in amorphous glassy Poly(2,6-dimethyl-1,4-phenylene) oxide (PPO) at 35°C up to 1000 Torr is investigated. Sorption experiments were carried out using an approach that combines barometry with FTIR spectroscopy in the transmission mode to quantify the sorption of pure and mixed gases in polymers. The pressure range is chosen to prevent any variation of the glassy polymer density. The solubility within the polymer of the CO2 present in the gaseous binary mixtures is practically coincident with the solubility of pure gaseous CO2, up to a total pressure of the gaseous mixtures equal to 1000 Torr and for CO2 mole fraction of ~0.5 mol mol-1 and ~0.3 mol mol-1. The Non-Equilibrium Thermodynamics for Glassy Polymers (NET-GP) modelling approach has been applied to the Non-Random Hydrogen Bonding (NRHB) lattice fluid model to fit the solubility data of pure gases. We have assumed here that no specific interactions are occurring between the matrix and the absorbed gas. The same thermodynamic approach has been then used to predict the solubility of CO2/CH4 mixed gases in PPO resulting in a deviation lower than 9.5% from the experimental results for CO2 solubility.

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Section: Sorption Of Pure Co2 and Ch4 In Pposupporting

confidence: 92%

Section: Sorption Of Pure Co2 and Ch4 In Ppomentioning

confidence: 99%

Sorption of CO2, CH4 and their mixtures in Amorphous Poly(2,6-dimethyl-1,4-phenylene)oxide (PPO)

Loianno¹,

Baldanza²,

Scherillo³

et al. 2023

Preprint

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“…Considering first the antisymmetric stretching of CO 2 , it is known that, according to the theory of vibrational line shapes, the profile of this transition can be described by the sum of a Gaussian and a Lorentzian band shape, both centered at the peak maximum. The two-component profile is evident in systems with no molecular interactions . In the case of a collisional relaxation mechanism, this complex band shape is due to the probe dynamics, in particular to free rotation in the early stages of the relaxation process, producing the Gauss component and a faster decay at later stages, giving rise to the Lorentz band.…”

Section: Results and Discussionmentioning

confidence: 98%

“…The two-component profile is evident in systems with no molecular interactions. 80 In the case of a collisional relaxation mechanism, this complex band shape is due to the probe dynamics, in particular to free rotation in the early stages of the relaxation process, producing the Gauss component and a faster decay at later stages, giving rise to the Lorentz band. Whenever a Gaussian component is evident, a significant free-rotation regime exists, which, in turn, indicates that the probe interrogates a poorly or noninteractive environment with a sizable free volume.…”

Section: Resultsmentioning

confidence: 99%

“…The mutual diffusivity coefficient, D 12 , in a penetrant–rubbery polymer binary system can be expressed − in terms of the so-called intra diffusion coefficient of the penetrant, D 1 , that represents the intrinsic mobility of penetrant in a binary mixture in the case of a null value of the gradients of the chemical potentials of the two components: D 12 = D 1 p = D 1 ρ p V̂ p ρ 1 true( ∂ μ 1 ∂ ρ 1 true) T , P , ρ p R T This equation holds true not only at small penetrant concentrations but also over a major portion of the concentration interval of the binary system. , In eq V̂ p is the partial mass volume of the polymer in the mixture.…”

Section: Materials and Methodsmentioning

confidence: 99%

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Weak Interactions between Poly(ether imide) and Carbon Dioxide: A Multiscale Investigation Combining Experiments, Theory, and Simulations

et al. 2022

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This contribution aims at an understanding, at a molecular scale, of the state of CO2 molecules absorbed in glassy poly(ether imide) (PEI). This issue has been challenged by combining different approaches that tackle the problem from both the experimental and the theoretical viewpoints and providing a comprehensive physicochemical picture. In situ FTIR spectroscopy and gravimetry were exploited to gather relevant experimental information, while molecular dynamics (MD), density functional theory (DFT), and statistical thermodynamics approaches were used to model the behavior of the binary system at different scales. Based on the findings of FTIR spectroscopy and on DFT and MD calculations, it was determined that, among the possible interaction configurations, some are prevailing. In particular, the carbon atom of carbon dioxide molecules establishes relatively weak interactions prevalently with the carbonyl groups of PEI. A quantitative estimate of such interaction has been provided by MD calculations. The system was also analyzed using a lattice fluid model, specifically developed to deal with sorption of low molecular weight compounds in glassy polymers, that is rooted on statistical thermodynamics, determining the values of the isosteric heat of sorption and carbon-dioxide–polymer interaction energy. Finally, experimental data of CO2–PEI mutual diffusivity have been interpreted using a semiempirical theoretical model accounting for the effects of the penetrant concentration, of energy barriers associated with the occurrence of an effective diffusive jump, and of a thermodynamic factor.

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Combining FTIR spectroscopy and pressure-decay techniques to analyze sorption isotherms and sorption kinetics of pure gases and their mixtures in polymers: The case of CO2 and CH4 sorption in polydimethylsiloxane

Loianno

Mensitieri

Baldanza

et al. 2022

Journal of Membrane Science

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A Hyphenated Approach Combining Pressure-Decay and In Situ FT-NIR Spectroscopy to Monitor Penetrant Sorption and Concurrent Swelling in Polymers

Cited by 6 publications

References 31 publications

Sorption of CO2, CH4 and their mixtures in Amorphous Poly(2,6-dimethyl-1,4-phenylene)oxide (PPO)

Sorption of CO2, CH4 and their mixtures in Amorphous Poly(2,6-dimethyl-1,4-phenylene)oxide (PPO)

Weak Interactions between Poly(ether imide) and Carbon Dioxide: A Multiscale Investigation Combining Experiments, Theory, and Simulations

Combining FTIR spectroscopy and pressure-decay techniques to analyze sorption isotherms and sorption kinetics of pure gases and their mixtures in polymers: The case of CO2 and CH4 sorption in polydimethylsiloxane

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