Your search keyword '"Minelli, Matteo"' showing total 22 results

1. CO2 plasticization effect on glassy polymeric membranes

Author

Matteo Minelli, Stefano Oradei, Maurizio Fiorini, Giulio Cesare Sarti, Minelli, Matteo, Oradei, Stefano, Fiorini, Maurizio, and Sarti, Giulio C.

Subjects

chemistry.chemical_classification, Dynamic mechanical analysis, Materials science, Polymers and Plastics, Glassy polymer, Plasticization, Organic Chemistry, 02 engineering and technology, Polymer, Permeation, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, Membrane, Penetrant (mechanical, electrical, or structural), CO2 content, chemistry, Materials Chemistry, Polystyrene, Composite material, 0210 nano-technology, Polyimide

Abstract

The effect of CO2 on the mechanical properties of three different glassy polymeric materials, polystyrene (PS), polymethylmethacrylate (PMMA) and Matrimid polyimide (PI), has been investigated by dedicated Dynamic Mechanical Analysis (DMA) at 35 degrees C on samples equilibrated at different penetrant pressures (0-30 bar). The experimental campaign has been designed to inspect the mechanical properties associated to the so-called plasticization phenomenon, which has been invoked as responsible for the increase of gas permeability versus feed pressure in glassy polymeric membranes. The main aim of the work is to find if any correlation holds between the effects induced on polymer mechanical properties and on gas permeability by the presence of different amounts of penetrant gas.The DMA analysis revealed that CO2 produces a decrease of polymer storage modulus E' and an enhancement of tan delta factor. Experimental data for both E' and tan delta vary regularly and monotonically with CO2 content in the membrane, with no indication of the onset of other new phenomena at pressures higher than the "plasticization pressure" associated to permeability data. The mechanical properties show very similar behaviors with CO2 content for all polymers analyzed, notwithstanding their CO2 permeability behaviors are different decreasing with upstream pressure for PS, increasing for PMMA and nonmonotonous for Matrimid. The results obtained indicate that there is no direct correlation between gas permeation dependence on CO2 content and the changes in the polymer mechanical properties induced by the same CO2 content.

Published

2019

2. Modeling mass transport in dense polymer membranes: cooperative synergy among multiple scale approaches

Author

Matteo Minelli, Giulio Cesare Sarti, Minelli Matteo, and Giulio C. Sarti

Subjects

Mass transport, Equation of state, Computer science, Scale (chemistry), Synthetic membrane, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Process conditions, General Energy, Membrane, polymer, membrane, trasport, sorption, Polymeric membrane, 0210 nano-technology, Transport phenomena, Biological system

Abstract

The modeling description of basic transport phenomena of either liquid, gas or vapor molecules in dense polymeric membranes is of tremendous impact for the separation industry, which relies on solid models for the design of optimal process conditions, for the selection of the most suitable membrane materials as well as for the development of novel ones. Such models need to deal with several physical aspects and phenomena, spanning over broad time and length scales, thus requiring multiple approaches. The solid frameworks now available mainly rely on the solution–diffusion theory, in which equation of state models and free volume theories are applied for the description of thermodynamic and kinetic properties, to be coupled in appropriate transport schemes.

Published

2020

3. Hybrid Pla/wild garlic antimicrobial composite films for food packaging application

Author

Aleksandra Novaković, Ivan Ristić, Ljubiša Šarić, Tanja Radusin, Alena Tomšik, Marco Giacinti Baschetti, Matteo Minelli, Radusin, Tanja, Tomšik, Alena, Šarić, Ljubiša, Ristić, Ivan, Giacinti Baschetti, Marco, Minelli, Matteo, and Novaković, Aleksandra

Subjects

Materials Chemistry2506 Metals and Alloys, Polymers and Plastic, Materials science, Polymers and Plastics, biology, 010405 organic chemistry, Chemistry (all), Composite number, Ceramics and Composite, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Antimicrobial, biology.organism_classification, 01 natural sciences, 0104 chemical sciences, Food packaging, Wild garlic, Materials Chemistry, Ceramics and Composites, Food science, Composite material, 0210 nano-technology

Abstract

Composite films based on poly(lactic acid) filled by 0.5 and 5 wt.% of Allium ursinum extract (wild garlic) for food packaging applications were prepared. Obtained films were examined from the view of characterization material properties and antimicrobial potential. The addition of two different amounts of A. ursinum extract improved thermal and mechanical properties of neat PLA (increase in Tgand tensile strength for both loadings). The oxygen barrier properties of the obtained hybrid films in dry condition were not significantly modified, while a slight increase of oxygen transmission rate was observed for the 5% loaded samples. Differences were detected in ΔE* values among the films containing A. ursinum extract in comparison with neat PLA. A marked difference between neat PLA and sample with 0.5 wt% of A. ursinum extract (3-6) was observed, while the color of the samples with 5 wt% was characterized by a completely different shade compared with neat PLA (>12). The antimicrobial activity of PLA films (neat and with 0.5 and 5 wt% of A. ursinum extract) was tested against Gram-negative bacterium Escherichia coli and both polymer composites with 0.5 and 5 wt% AU extract showed antimicrobial activity.

Published

2018

4. A predictive model for the permeability of gas mixtures in glassy polymers

Author

Enrico Toni, Matteo Minelli, Giulio Cesare Sarti, Toni, Enrico, Minelli, Matteo, and Sarti, Giulio C.

Subjects

Imagination, Chemical substance, General Chemical Engineering, media_common.quotation_subject, General Physics and Astronomy, Non-equilibrium thermodynamics, Thermodynamics, 02 engineering and technology, Permeability, Physics and Astronomy (all), Penetrant (mechanical, electrical, or structural), 020401 chemical engineering, Chemical Engineering (all), 0204 chemical engineering, Physical and Theoretical Chemistry, Solubility, media_common, Gas mixture, chemistry.chemical_classification, Glassy polymer, Polymer, Permeation, Thermodynamic model, 021001 nanoscience & nanotechnology, Dilution, chemistry, 0210 nano-technology

Abstract

The transport of gaseous mixtures in glassy polymers is analyzed by means of a thermodynamic based model, which is applied to describe the permeability of CO 2 /CH 4 50/50 binary mixtures in various glassy polymeric membranes. The approach relies on the description of the solubility behavior of penetrant/polymer mixtures provided by the nonequilibrium thermodynamics for glassy polymers (NET-GP), and considers the gradient in penetrant chemical potential of each species as the actual driving force of the diffusive mass fluxes. Such an approach is specialized to dilute solutions conditions, as it is typically of interest for the transport of light gas (e.g. CO 2 , N 2 , CH 4 , O 2 ) in glassy polymeric membranes; that allows for the simple and successful prediction of the gas permeability of gas mixtures based on single component transport data, with no additional parameters required. The NET-GP model is used in combination with an equation of state (lattice fluid theory by Sanchez and Lacombe) to obtain the solubility of pure and mixed gases at various pressures and compositions, as well as the thermodynamic factors accounting for the dependence of chemical potentials of the solutes on the concentrations of both penetrants. An exponential dependence on penetrant concentration is used to describe the mobility coefficient behavior, so that only two adjustable parameters are required for the pure penetrant case (infinite dilution mobility and plasticization factor). A simple but effective linear mixing rule is considered to describe transport in the binary mixture case, which does not introduce any additional adjustable parameter due to the presence of a second penetrating species. The comparison with permeation data of gas mixtures in different polymers shows the good predictive ability of the model.

Published

2018

5. A multiscale approach to predict the mixed gas separation performance of glassy polymeric membranes for CO 2 capture: the case of CO 2 /CH 4 mixture in Matrimid ®

Author

Matteo Minelli, Eleonora Ricci, Maria Grazia De Angelis, Ricci, Eleonora, Minelli, Matteo, and De Angelis, Maria Grazia

Subjects

Equation of state, Thermodynamics, Filtration and Separation, 02 engineering and technology, 010402 general chemistry, Thermal diffusivity, 01 natural sciences, Biochemistry, Methane, chemistry.chemical_compound, Organic chemistry, General Materials Science, Gas separation, Physical and Theoretical Chemistry, Solubility, Chemistry, Molecular Dynamic, Equations of state, NET-GP model, Multiscale simulation method, Sorption, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Membrane, Materials Science (all), 0210 nano-technology, Glass transition, Polyimide

Abstract

The gas solubility in polymeric membranes affects the separation performance, particularly in the case of CO2 capture processes. Solubility and solubility-selectivity in membranes of multicomponent mixtures can deviate rather markedly from the corresponding pure gas values, due to swelling and competition phenomena, and require dedicated time-consuming measurements. Many experiments can be avoided by using a suitable thermodynamic tool, such as an Equation of State (EoS) model, to represent the gases sorption in the membrane. Such models require, for parameterization, knowledge of the polymer behavior above the glass transition Tg, which is a limit for membrane modeling, because the most attractive polymers for gas separation are rigid matrices characterized by very high Tg values, difficult to reach experimentally. In this work, we study the sorption of CO2/CH4 mixtures in a high-Tg polyimide membrane (Matrimid®) using a bottom-up approach. Pressure-volume-temperature data for Matrimid® above Tg are generated using NPT Molecular Dynamics simulations: the results are regressed to find Matrimid® parameters for the PC-SAFT Equation of State. Finally, the Non Equilibrium PC-SAFT macroscopic model (NE-PC-SAFT) is used to calculate CO2 and CH4 solubility and solubility-selectivity as a function of gas mixture pressure, composition and temperature. The approach is tested successfully over many experimental pure gas and vapor sorption data in Matrimid®. Mixed gas calculations predict a marked competition, which affects more methane than CO2 sorption, and results in a higher-than-ideal value of solubility-selectivity. Combined with the fact that experimental mixed gas permeability-selectivity is lower than the ideal value, such results indicate that the diffusivity of CH4 in Matrimid is significantly enhanced in presence of CO2, causing a decrease of diffusivity-selectivity. The gas solubility in polymeric membranes affects the separation performance, particularly in the case of CO2 capture processes. Solubility and solubility-selectivity in membranes of multicomponent mixtures can deviate rather markedly from the corresponding pure gas values, due to swelling and competition phenomena, and require dedicated time-consuming measurements. Many experiments can be avoided by using a suitable thermodynamic tool, such as an Equation of State (EoS) model, to represent the gases sorption in the membrane. Such models require, for parameterization, knowledge of the polymer behavior above the glass transition Tg which is a limit for membrane modeling, because the most attractive polymers for gas separation are rigid matrices characterized by very high Tg values, difficult to reach experimentally. In this work, we study the sorption of CO2/CH4 mixtures in a high-Tg polyimide membrane (Matrimid®) using a bottom-up approach. Pressure-volume-temperature data for Matrimid® above Tg are generated using NPT Molecular Dynamics simulations: the results are regressed to find Matrimid® parameters for the PC-SAFT Equation of State. Finally, the Non Equilibrium PC-SAFT macroscopic model (NE-PC-SAFT) is used to calculate CO2 and CH4 solubility and solubility-selectivity as a function of gas mixture pressure, composition and temperature. The approach is tested successfully over many experimental pure gas and vapor sorption data in Matrimid®. Mixed gas calculations predict a marked competition, which affects more methane than CO2 sorption, and results in a higher-than-ideal value of solubility-selectivity. Combined with the fact that experimental mixed gas permeability-selectivity is lower than the ideal value, such results indicate that the diffusivity of CH4 in Matrimid® is significantly enhanced in presence of CO2, causing a decrease of diffusivity-selectivity.

Published

2017

6. Gas permeability in glassy polymers: A thermodynamic approach

Author

Matteo Minelli, Giulio Cesare Sarti, Minelli, Matteo, and Sarti, Giulio Cesare

Subjects

Hydrogen, General Chemical Engineering, General Physics and Astronomy, chemistry.chemical_element, Non-equilibrium thermodynamics, Thermodynamics, 02 engineering and technology, 010402 general chemistry, Thermal diffusivity, 01 natural sciences, Diffusion, Penetrant (mechanical, electrical, or structural), Organic chemistry, Physical and Theoretical Chemistry, Solubility, Helium, chemistry.chemical_classification, Gas permeability, Glassy polymer, Plasticizer, NELF model, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Condensed Matter::Soft Condensed Matter, chemistry, 0210 nano-technology

Abstract

The permeability of various low molecular weight species (both gases and vapors) in a series of glassy polymers has been extensively analyzed by means of a thermodynamic based approach for solubility and diffusivity, recently proposed and already applied to a few penetrant/polymer systems. The model relies on the thermodynamic description of the solubility behaviors of the solutes provided by the nonequilibrium thermodynamic model for glassy polymers (NET-GP), while the diffusivity is the product of the mobility coefficient, a purely kinetic quantity, and the thermodynamic factor, accounting for the dependence of the penetrant chemical potential on its concentration in the glassy polymer matrix. The model is applied to permeability data of many penetrant species from very light gases, such as hydrogen or helium, to hydrocarbons and fluorocarbons, in several different glasses, including very high free volume materials, polyimides and fluoropolymers. The model proved to be effective in the representation of all types of permeability behaviors with respect to penetrant upstream pressure, which may be either decreasing, increasing, or with a nonmonotonous trend showing a minimum value at the so-called plasticization pressure.

Published

2016

7. Non-equilibrium thermodynamics of glassy polymers: Use of equations of state to predict gas solubility and heat capacity

Author

Christopher J. Durning, Sanat K. Kumar, Matteo Minelli, Ferruccio Doghieri, Doghieri, Ferruccio, Minelli, Matteo, Durning, C. J., and Kumar, S.

Subjects

Heat capacity, Work (thermodynamics), Bulk modulus, Chemistry, Non-equilibrium thermodynamic, General Chemical Engineering, Glassy polymer, General Physics and Astronomy, Non-equilibrium thermodynamics, Thermodynamics, 02 engineering and technology, Gas solubility, 021001 nanoscience & nanotechnology, Thermal expansion, Physics and Astronomy (all), 020401 chemical engineering, Phase (matter), Chemical Engineering (all), 0204 chemical engineering, Physical and Theoretical Chemistry, Solubility, 0210 nano-technology, Glass transition, SAFT

Abstract

The use of Non-Equilibrium Thermodynamics for Glassy Polymers (NET-GP) model to predict infinite dilution gas solubility coefficient is revised in this work and its extension to the analysis of apparent constant pressure heat capacity in polymeric materials below the glass transition temperature Tg is developed. Use is made of different Equations of State (EoS), in the class of tangent-hard-spheres-chain theories, to predict the thermal expansion coefficient below Tg, resulting in consistent representations of the Henry's coefficient for gaseous species in the same temperature range, for the case of different versions of Statistical Associating Fluid Theory (SAFT) EoS. With reference to calorimetric properties, the analysis here performed indicates that NET-GP endowed with EoS tuned on melt phase equilibrium properties does not allow for the prediction of the bulk modulus of the glassy polymeric phase, and only qualitative behavior for the apparent heat capacity are reproduced. On the other hand, after the use of experimental data from structural relaxation experiments to evaluate the bulk modulus in glassy state, a satisfactory prediction of the excess heat capacity is obtained within the same framework, for the case of different non-equilibrium conditions. Conclusion are finally drawn for the need to account for additional order parameters in NET-GP approach in order to address the representation of the complex calorimetric behavior exhibited by glassy polymeric materials.

Published

2016

8. Graphene-based coatings on polymer films for gas barrier applications

Author

Meganne Christian, Ferruccio Doghieri, Matteo Minelli, Zhenyuan Xia, Vincenzo Palermo, Simone Ligi, Vittorio Morandi, Davide Pierleoni, Pierleoni, Davide, Xia, Zhen Yuan, Christian, Meganne, Ligi, Simone, Minelli, Matteo, Morandi, Vittorio, Doghieri, Ferruccio, and Palermo, Vincenzo

Subjects

polymer films, Materials science, Oxide, coatings, 02 engineering and technology, Adipamide, engineering.material, 010402 general chemistry, 01 natural sciences, law.invention, gas barrier, chemistry.chemical_compound, Oxygen transmission rate, Coating, law, General Materials Science, Graphite, Composite material, chemistry.chemical_classification, Graphene, Chemistry (all), graphene, General Chemistry, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, engineering, 0210 nano-technology, Dispersion (chemistry)

Abstract

We used soluble graphene derivatives to fabricate gas barrier coatings on the surface of several industrially relevant commodity polymers. The coatings are prepared using electrochemically exfoliated graphene oxide, featuring both monoatomic thickness and micron-scale lateral size, showing better gas barrier performance as compared to films of commercial graphene products. A 74% decrease of oxygen transmission rate is found using loadings as low as 0.4 wt. % (0.2 vol. %). The coating process is performed using a combination of solution processing, filtering, and transfer. It is a robust and versatile approach, working with different transfer processes, different starting graphite materials and a wide range of well-known polymeric substrates: poly(ethylene terephthalate), poly(lactic acid), poly(hexamethylene adipamide), poly(propylene), and poly(vinyl chloride). The use of 2D sheets as surface coatings instead of bulk additives overcomes common issues related to dispersion of graphene in a polymer matrix, and gives a clear advantage in preserving the mechanical properties of the bulk polymer. Furthermore, it is a scalable approach able to significantly improve the barrier properties of polymeric films for large-scale applications.

Published

2016

9. Modeling Retrograde Vitrification in the Polystyrene-Toluene System

Author

Giuseppe Scherillo, Davide Pierleoni, Ferruccio Doghieri, Matteo Minelli, Giuseppe Mensitieri, Valerio Loianno, Rosario Esposito, Antonio Brasiello, Scherillo, Giuseppe, Loianno, Valerio, Pierleoni, Davide, Esposito, Rosario, Brasiello, Antonio, Minelli, Matteo, Doghieri, Ferruccio, and Mensitieri, Giuseppe

Subjects

retrograde vitrification, toluene, Materials science, Thermodynamics, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, chemistry.chemical_compound, Natural rubber, Materials Chemistry, glass transition, Vitrification, Physical and Theoretical Chemistry, Polystyrene, chemistry.chemical_classification, glass transition temperature, glassy polymers, Sorption, Polymer, 021001 nanoscience & nanotechnology, Toluene, 0104 chemical sciences, Surfaces, Coatings and Films, Condensed Matter::Soft Condensed Matter, NRHB, chemistry, retrograde vitrification, visual_art, visual_art.visual_art_medium, Polymer blend, polystyrene, mathematical model, 0210 nano-technology, Glass transition

Abstract

Atactic polystyrene, as reported in a recent contribution by our group, displays a marked change in glass transition when exposed to toluene vapor due to plasticization associated with vapor sorption within the polymer. The dependence of the glass transition temperature of the polymer−penetrant mixture on the pressure of toluene vapor is characterized by the so-called “retrograde vitrification” phenomenon, in that, at a constant pressure, a rubber to glass transition occurs by increasing the temperature. In this contribution, we have used a theoretical approach, based on the nonrandom lattice fluid thermodynamic model for the polymer−toluene mixture, to predict the state of this system, i.e., rubbery or glassy, as a function of fluid pressure and system temperature. The experimentally detectable glass transition is assumed to be a kinetically affected evidence of an underlying II order thermodynamic transition of the polymer mixture. On the basis of this hypothesis, the Gibbs−Di Marzio criterion, stating that equilibrium configurational entropy is zeroed at the glass transition, has been applied to locate the transition. The working set of equations consists of the expression of configurational entropy obtained from the adopted lattice fluid model equated to zero, coupled with the equation expressing the phase equilibrium between the polymer phase and the pure toluene vapor phase in contact and with the equations of state for the two phases. Theoretical predictions are in good qualitative and quantitative agreement with the experimental results previously obtained gravimetrically performing “dynamic” sorption experiments, which represent a neat example of the occurrence of so-called “type IV” glass transition temperature vs pressure behavior. The peculiar retrograde vitrification phenomenon and the glass transition temperature vs pressure envelope determined experimentally are well described by the proposed theoretical approach.

Published

2018

10. Thermodynamic Modeling of Gas Transport in Glassy Polymeric Membranes

Author

Giulio Cesare Sarti, Matteo Minelli, Minelli, Matteo, and Sarti, Giulio Cesare

Subjects

glassy polymers, gas solubility, gas permeability, thermodynamics, NELF model, Non-equilibrium thermodynamics, Thermodynamics, Filtration and Separation, 02 engineering and technology, lcsh:Chemical technology, 010402 general chemistry, Kinetic energy, Thermal diffusivity, 01 natural sciences, Article, Penetrant (mechanical, electrical, or structural), Thermodynamic, Chemical Engineering (miscellaneous), lcsh:TP1-1185, lcsh:Chemical engineering, Solubility, chemistry.chemical_classification, Chemistry, Process Chemistry and Technology, Glassy polymer, lcsh:TP155-156, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Exponential function, Permeability (earth sciences), Materials Science (all), 0210 nano-technology

Abstract

Solubility and permeability of gases in glassy polymers have been considered with the aim of illustrating the applicability of thermodynamically-based models for their description and prediction. The solubility isotherms are described by using the nonequilibrium lattice fluid (NELF) (model, already known to be appropriate for nonequilibrium glassy polymers, while the permeability isotherms are described through a general transport model in which diffusivity is the product of a purely kinetic factor, the mobility coefficient, and a thermodynamic factor. The latter is calculated from the NELF model and mobility is considered concentration-dependent through an exponential relationship containing two parameters only. The models are tested explicitly considering solubility and permeability data of various penetrants in three glassy polymers, PSf, PPh and 6FDA-6FpDA, selected as the reference for different behaviors. It is shown that the models are able to calculate the different behaviors observed, and in particular the permeability dependence on upstream pressure, both when it is decreasing as well as when it is increasing, with no need to invoke the onset of additional plasticization phenomena. The correlations found between polymer and penetrant properties with the two parameters of the mobility coefficient also lead to the predictive ability of the transport model.

Published

2017

11. Modeling of oxygen permeation through filled polymeric layers for barrier coatings

Author

Lars Järnström, Magnus Lestelius, Matteo Minelli, Chris Bonnerup, Ellen Moons, Åsa Nyflött, Yana Petkova-Olsson, Gunilla Carlsson, Nyflött, Åsa, Petkova-Olsson, Yana, Moons, Ellen, Bonnerup, Chri, Järnström, Lar, Carlsson, Gunilla, Lestelius, Magnu, and Minelli, Matteo

Subjects

Materials Chemistry2506 Metals and Alloys, Vinyl alcohol, Materials science, Polymers and Plastics, Crystallization of polymers, Surfaces, Coatings and Film, 02 engineering and technology, engineering.material, 010402 general chemistry, 01 natural sciences, Tortuosity, modelling, chemistry.chemical_compound, Oxygen permeability, Penetrant (mechanical, electrical, or structural), Coating, Materials Chemistry, kaolin, Composite material, PVOH, chemistry.chemical_classification, Polymers and Plastic, Chemistry (all), mass transport, General Chemistry, Polymer, Permeation, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Surfaces, Coatings and Films, chemistry, engineering, permeation, 0210 nano-technology

Abstract

This paper presents an extended model for gas permeation through a filled polymer layer, and it is applied to the case of oxygen permeability through a poly(vinyl alcohol)/kaolin dispersion coating. The model is based on a description of polymer and penetrant properties in a thermodynamically consistent framework. The gradient in chemical potential is considered the driving force for the diffusion of the penetrating gas. The well-established nonequilibrium lattice fluid (NELF) model for the polymer phase is extended in order to account for the additional features of the polymer/filler system, such as the concentration and aspect ratio of the inorganic filler, which enhance the penetrant tortuosity. The model predicts the behavior of penetrant permeability with respect to polymer crystallinity and filler fraction. The calculated results are compared to experimentally obtained data for oxygen permeability through a dispersion coating layer consisting of poly(vinyl alcohol) (PVOH) and two types of kaolin with different aspect ratios. A good agreement is found in terms of the effects of polymer crystallinity, filler concentration, and filler aspect ratio. The experimental results also indicate a complex interplay between the polymer and the filler as the permeability of two differently surface modified kaolin clays was determined, displaying slight deviations from model predictions. Significant differences were observed in the experimental results between the two fillers investigated, and the one characterized by the smaller aspect ratio affects to a minor extent the oxygen permeability, as illustrated by the model. Furthermore, the lower hydrolysis degree of PVOH gives a reduced barrier performance, as expected. © 2017 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2017, 134, 44834.

Published

2017

12. Predictive model for gas and vapor sorption and swelling in glassy polymers: II. Effect of sample previous history

Author

Matteo Minelli, Ferruccio Doghieri, Minelli, Matteo, and Doghieri, Ferruccio

Subjects

General Chemical Engineering, General Physics and Astronomy, Thermodynamics, Non-equilibrium thermodynamics, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Physics and Astronomy (all), Penetrant (mechanical, electrical, or structural), Thermodynamic, Rheology, Polymer chemistry, medicine, Chemical Engineering (all), Solubility, Fluid solubility, Physical and Theoretical Chemistry, chemistry.chemical_classification, Chemistry, Polymer swelling, Glassy polymer, NELF model, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Condensed Matter::Soft Condensed Matter, Compressibility, Polymer blend, Swelling, medicine.symptom, 0210 nano-technology

Abstract

The solubility of various gases in several glassy polymers has been analyzed by the nonequilibrium thermodynamics for glassy polymers (NET-GP) framework, coupled with a lattice fluid equation of state model. Moreover, a simple rheological tool recently introduced for the a priori evaluation of the penetrant induced swelling is employed to predict the volumetric behavior of the solute/polymer mixture below T g . Such model accounts for an additional nonequilibrium parameter for the description of polymer phase that represents its pseudoequilibrium compressibility, and it can be retrieved from pure component pressure–volume–temperature data below T g . More in detail, the effect of polymer pretreatment and its prior history (e.g. annealing or conditioning by preswelling) on the resulting solubility behavior has been thoroughly analyzed and discussed, and the experimental data obtained for several penetrant/polymer couples have been well described by the present model.

Published

2017

13. Predictive calculations of gas solubility and permeability in glassy polymeric membranes: An overview

Author

Maria Grazia De Angelis, Matteo Minelli, Giulio Cesare Sarti, Minelli, Matteo, de Angelis, Maria Grazia, and Sarti, Giulio C

Subjects

Materials science, General Chemical Engineering, Oxide, Thermodynamics, 02 engineering and technology, 010402 general chemistry, Thermal diffusivity, 01 natural sciences, chemistry.chemical_compound, Penetrant (mechanical, electrical, or structural), Organic chemistry, Chemical Engineering (all), Solubility, glassy polymer, chemistry.chemical_classification, solubility, diffusion, Plasticizer, NELF model, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Permeability (earth sciences), chemistry, Polymeric membrane, permeability, 0210 nano-technology

Abstract

The possibility to evaluate in a predictive way the relevant transport properties of low molecular weight species, both gases and vapors, in glassy polymeric membranes is inspected in detail, with particular attention to the methods recently developed based on solid thermodynamic basis. The solubility of pure and mixed gases, diffusivity and permeability of single gases in polymer glasses are examined, considering in particular poly(2,6-dimethyl-1,4-phenylene oxide) as a relevant test case. The procedure clearly indicates what are the relevant physical properties of the polymer matrix and of the penetrants required by the calculations, which can be obtained experimentally through independent measurements. For gas and vapor solubility, the comparison with direct experimental data for mixed gases points out also the ability to account for the significant variations that solubility-selectivity experiences upon variations of pressure and/or feed composition. For gas and vapor permeability, the comparison with direct experimental data shows the possibility to account for the various different trends observed experimentally as penetrant pressure is increased, including the so-called plasticization behavior. The procedure followed for permeability calculations leads also to clear correlations between permeability and physical properties of both polymer and penetrant, based on which pure predictive calculations are reliably made. [Figure not available: see fulltext.]

Published

2017

14. Effect of block copolymer morphology on crystallization and water transport

Author

Chenhui Zhu, Alexander Hexemer, Eric Schaible, Matteo Minelli, Daniel T. Hallinan, Onyekachi Oparaji, Oparaji, Onyekachi, Minelli, Matteo, Zhu, Chenhui, Schaible, Eric, Hexemer, Alexander, and Hallinan, Daniel T.

Subjects

Materials science, Polymers and Plastics, Crystallization of polymers, 02 engineering and technology, Isothermal melting, 010402 general chemistry, 01 natural sciences, law.invention, Crystallinity, chemistry.chemical_compound, law, Phase (matter), Polymer chemistry, Materials Chemistry, Copolymer, Crystallization, Water transport, Aqueous solution, Organic Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Chemical engineering, chemistry, Block copolymer morphology, Polystyrene, Water clustering, 0210 nano-technology

Abstract

The effect of block copolymer morphology on polymer crystallization and water sorption was investigated using two amphiphilic block copolymers with minority hydrophilic phase. Such polymers have many potential membrane applications, including CO 2 capture and water purification. A model block copolymer chemistry comprising polystyrene and poly(ethylene oxide) (PEO) is used in this work. Both block copolymers have strongly phase-separated order, one with lamellar morphology and another with cylindrical morphology. In addition to the block copolymer structure, the PEO phase is semicrystalline at room temperature. The block copolymer structure has dramatic consequences for the degree of PEO crystallinity even in the absence of water. Furthermore, the crystallinity is affected by water sorption. PEO melting and degree of crystallinity were determined as a function of water content. Water solubility was measured between 35 and 75 °C. Interestingly, water sorption properties are dictated almost exclusively by the amorphous PEO volume fraction, being low in the semicrystalline state (below 55 °C) and higher in the amorphous state (above 55 °C). At 55 °C, crystallite dissolution is observed with increasing water solubility. Water diffusion coefficient was also measured; it decreases monotonically with increasing water content. This concentration dependence of diffusion is explained by water clustering, which increases with increasing water content. In addition to block copolymer morphology playing a major role in PEO crystallinity, it has a significant effect on water diffusion in the amorphous polymers and is of practical importance as investigations at elevated temperature are not possible with homopolymer PEO.

Published

2017

15. On the interpretation of cryogenic sorption isotherms in glassy polymers

Author

Matteo Minelli, Donald R Paul, Giulio Cesare Sarti, Minelli, Matteo, Paul, Donald R., and Sarti, Giulio C.

Subjects

Polymers with intrinsic microporosity, Materials science, Thermodynamics, Filtration and Separation, 02 engineering and technology, Gas solubility, 010402 general chemistry, 01 natural sciences, Biochemistry, Penetrant (mechanical, electrical, or structural), Desorption, Polymer chemistry, medicine, General Materials Science, Cryogenic sorption, Solubility, Physical and Theoretical Chemistry, Dissolution, chemistry.chemical_classification, Glassy polymer, Sorption, NELF model, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Condensed Matter::Soft Condensed Matter, chemistry, Materials Science (all), Swelling, medicine.symptom, 0210 nano-technology, BET theory

Abstract

Sorption data of nitrogen, argon and krypton in different glassy polymers at different cryogenic temperatures are analyzed, including hydrogen in PIM-1; conventional and high free volume glassy polymers are included. A consistent interpretation of experimental data is obtained by considering penetrant dissolution in a uniform dense glassy polymer, undergoing volume swelling with all penetrants but hydrogen. All the data are properly described by using the NELF model which is appropriate for the solubility in glassy polymers. Remarkably, in each polymer the sorption isotherms of different penetrants are described well by using the same initial polymer density, and the same swelling coefficient value allows satisfactory description of the sorption behavior of one penetrant at different temperatures. For PIM-1, NELF model and molecular dynamics give exactly the same swelling, and desorption after sorption or subsequent sorption-desorption cycles show hysteresis effects clearly associated to irreversible volume changes; in addition, hydrogen sorption in PIM-1 is fully predicted by the NELF model, simply based on nitrogen sorption, as opposed to BET theory. On the bases of the above results the conclusion is drown that BET theory is not applicable to the cryogenic sorption isotherms in glassy polymers.

Published

2017

16. Polymer-Grafted Nanoparticle Membranes with Controllable Free Volume

Author

Eileen Buenning, Yucheng Huang, Makoto Asai, Christopher J. Durning, Sanat K. Kumar, Matteo Minelli, Connor Bilchak, David W. Gidley, Shiwang Cheng, Brian C. Benicewicz, Kai Zhang, Ferruccio Doghieri, Alexei P. Sokolov, Bilchak, Connor R., Buenning, Eileen, Asai, Makoto, Zhang, Kai, Durning, Christopher J., Kumar, Sanat K., Huang, Yucheng, Benicewicz, Brian C., Gidley, David W., Cheng, Shiwang, Sokolov, Alexei P., Minelli, Matteo, and Doghieri, Ferruccio

Subjects

chemistry.chemical_classification, Materials Chemistry2506 Metals and Alloys, Materials science, Polymers and Plastic, Polymers and Plastics, Organic Chemistry, Nanoparticle, Nanotechnology, Polymer free, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Inorganic Chemistry, Chain length, Membrane, chemistry, Volume (thermodynamics), Materials Chemistry, Gas separation, 0210 nano-technology, Layer (electronics)

Abstract

Polymer-based membranes play a key role in several industrially important gas separation technologies, e.g., removing CO2 from natural gas, with enormous economic and environmental impact. Here, we develop a novel hybrid membrane construct comprised entirely of nanoparticles grafted with polymers. These membranes are shown to have broadly tunable separation performance through variations in graft density and chain length. Computer simulations show that the optimal NP packing forces the grafted polymer layer to distort, yielding regions of measurably lower polymer density. Multiple experimental probes confirm that these materials have the predicted increase in “polymer free volume”, which explains their improved separation performance. These polymer-grafted NP materials thus represent a new template for rationally designing membranes with desirable separation abilities coupled with improved aging characteristics in the glassy state and enhanced mechanical behavior.

Published

2017

17. Analysis of a Polystyrene-Toluene System through 'dynamic' Sorption Tests: Glass Transitions and Retrograde Vitrification

Author

Giuseppe Scherillo, Valerio Loianno, Ferruccio Doghieri, Giuseppe Mensitieri, Matteo Minelli, Francesco Bonavolonta, Davide Pierleoni, Pierleoni, Davide, Minelli, Matteo, Scherillo, Giuseppe, Mensitieri, Giuseppe, Loianno, Valerio, Bonavolontã , Francesco, Doghieri, Ferruccio, and Bonavolontà, Francesco

Subjects

Materials Chemistry2506 Metals and Alloys, Materials science, Surfaces, Coatings and Film, 02 engineering and technology, 010402 general chemistry, complex mixtures, 01 natural sciences, Polystyrene, Toluene, Retrograde vitrification, Glass Transition, chemistry.chemical_compound, Penetrant (mechanical, electrical, or structural), Materials Chemistry, Organic chemistry, Vitrification, Physical and Theoretical Chemistry, chemistry.chemical_classification, Plasticizer, Sorption, Polymer, 021001 nanoscience & nanotechnology, Toluene, 0104 chemical sciences, Surfaces, Coatings and Films, Condensed Matter::Soft Condensed Matter, chemistry, Chemical engineering, Polystyrene, 0210 nano-technology, Glass transition

Abstract

Exposing a glassy polymer to a fluid phase (in gaseous or liquid state) containing a low molecular weight compound results in the sorption of the latter within the polymer, inducing, among other effects, the plasticization of the material which also promotes a change in the glass transition temperature. The amount of sorbed penetrant is often related in a complex fashion to the temperature and pressure of the fluid, thus determining that the locus of glass transition, when represented in pressure−temperature coordinates, may display as well rather complex patterns. This is an issue of particular importance in several applications of glassy polymers. In particular, we investigated the behavior of polystyrene in contact with toluene vapor by performing several modes of dynamic sorption experiments, in which the rate of change of the temperature of the system and/or of the pressure of the vapor phase are controlled with high accuracy, with the aim of creating a map of rubbery and glassy states of the polymer as a function of temperature and pressure of the toluene vapor. Isothermal tests were performed by changing the pressure at a controlled rate, isobaric tests were performed by changing the temperature at a controlled rate, and isoactivity tests were performed by concurrently changing, in a proper way, both temperature and pressure. A relevant feature resulting from these experiments is the presence of a discontinuity in the slope of the mass of toluene sorbed within polystyrene reported as a function of temperature and/or pressure. This discontinuity has been interpreted as the indication of the occurrence of a glass transition. The elaboration of the experimental results allowed identification of the pressure/temperature conditions at which rubbery or glassy states of the polymer mixture are established. Quite interestingly, the system displays the so- called “retrograde vitrification” phenomenon, which consists of the occurrence of a rubbery-to-glassy state transition as the temperature increases at a fixed pressure. The whole set of results has been successfully interpreted on the basis of thermodynamics of II order transitions accounting for the fact that experimental evidence of such transitions is significantly affected by the kinetics of polymer relaxation.

Published

2017

18. Elementary prediction of gas permeability in glassy polymers

Author

Giulio Cesare Sarti, Matteo Minelli, Minelli, Matteo, and Sarti, Giulio C

Subjects

Materials science, Non-equilibrium thermodynamics, Thermodynamics, Filtration and Separation, 02 engineering and technology, 010402 general chemistry, Thermal diffusivity, 01 natural sciences, Biochemistry, Permeability, Diffusion, Penetrant (mechanical, electrical, or structural), medicine, General Materials Science, Physical and Theoretical Chemistry, Characteristic energy, chemistry.chemical_classification, Glassy polymer, NELF model, Polymer, 021001 nanoscience & nanotechnology, Thermodynamic model, 0104 chemical sciences, Dilution, Condensed Matter::Soft Condensed Matter, Membrane, chemistry, Materials Science (all), Swelling, medicine.symptom, 0210 nano-technology

Abstract

The transport model proposed by Minelli and Sarti for the representation of gas and vapor permeability in glassy polymers has been extensively applied to various systems, and the model results are thoroughly analyzed. The approach is based on fundamental theory for the diffusion of low penetrant species in polymers, in which the diffusivity is considered as the product of the molecular mobility, and a thermodynamic coefficient, accounting for the concentration dependence of the chemical potential. The model relies on the thermodynamic description of the penetrant/polymer systems provided by the NonEquilibrium Thermodynamics for Glassy Polymers (NET-GP) approach. The penetrant mobility is assumed to depend exponentially on penetrant concentration, and the model contains two parameters only: mobility coefficient at infinite dilution and plasticization factor. The model parameters obtained from the analysis of the permeability behaviors of various systems have been examined and general correlations are derived. The mobility coefficient is indeed correlated to the properties of the pure penetrants (penetrant molecular size) and pure polymer (fractional free volume and characteristic energy). This allows the derivation of a simple and general expression for the prediction of the permeability of any penetrant species in glassy polymers in the range of low penetrant pressures, as well as the selectivity of any gas pair. Remarkably, the model predictions are able to represent quite accurately the experimental data available in the literature. Furthermore, the plasticization factor is correlated to the swelling produced by the penetrant into the glassy polymer matrix, obtaining thus a reliable tool for the estimation of the pressure dependence of gas permeability on upstream pressure.

Published

2017

19. Water sorption in microfibrillated cellulose (MFC): The effect of temperature and pretreatment

Author

Matteo Minelli, Tom Lindström, Caglar Mericer, Marco Giacinti Baschetti, Meriçer, Çağlar, Minelli, Matteo, Giacinti Baschetti, Marco, and Lindström, Tom

Subjects

Materials Chemistry2506 Metals and Alloys, Polymers and Plastics, Solubility isotherm, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Endothermic process, Nanocellulose, chemistry.chemical_compound, Materials Chemistry, Sorption modeling, Cellulose, Solubility, Composite material, Aqueous solution, Polymers and Plastic, Organic Chemistry, Sorption, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Cellulose fiber, chemistry, Chemical engineering, Water sorption, 0210 nano-technology, Dispersion (chemistry)

Abstract

Water sorption behavior of two different microfibrillated cellulose (MFC) films, produced by delamination of cellulose pulp after different pretreatment methods, is examined at various temperatures (16–65°C) and up to 70% RH. The effect of drying temperature of MFC films on the water uptake is also investigated. The obtained solubility isotherms showed the typical downward curvature at moderate RH, while no upturn is observed at higher RH; the uptakes are in line with characteristic values for cellulose fibers. Enzymatically pretreated MFC dispersion showed lower solubility than carboxymethylated MFC, likely due to the different material structure, which results from the different preparation methods The experimental results are analyzed by Park and GAB models, which proved suitable to describe the observed behaviors. Interestingly, while no significant thermal effect is detected on water solubility above 35°C, the uptake at 16 and 25°C, at a given RH, is substantially lower than that at higher temperature, indicating that, in such range, sorption process is endothermic. Such unusual behavior for a cellulose-based system seems to be related mainly to the structural characteristics of MFC films, and to relaxation phenomena taking place upon water sorption. The diffusion kinetics, indeed, showed a clear Fickian behavior at low temperature and RH, whereas a secondary process seems to occur at high temperature and higher RH, leading to anomalous diffusion behaviors.

Published

2017

20. Geopolymers as solid adsorbent for CO2 capture

Author

Elettra Papa, Valentina Medri, Ferruccio Doghieri, Francesco Miccio, Elena Landi, Matteo Minelli, Minelli, Matteo, Medri, Valentina, Papa, Elettra, Miccio, Francesco, Landi, Elena, and Doghieri, Ferruccio

Subjects

Materials science, General Chemical Engineering, 02 engineering and technology, [object Object], Solid adsorbent, 010402 general chemistry, Geopolymer, 01 natural sciences, Industrial and Manufacturing Engineering, Adsorption, Aluminosilicate, Ceramic materials, Chemical Engineering (all), Monolith, Porosity, geography, geography.geographical_feature_category, Aqueous solution, Applied Mathematics, Chemistry (all), General Chemistry, Ceramic material, 021001 nanoscience & nanotechnology, CO2 capture, 0104 chemical sciences, Gas adsorption, Chemical engineering, 0210 nano-technology, Mesoporous material, BET theory

Abstract

Geopolymer materials, a new class of alkali-bonded ceramics, have been prepared in monolith porous form, in order to investigate the adsorptive performances of CO 2 and light gases (CH 4 and N 2 ) by means of a volumetric method in the sub-atmospheric pressure range. The samples have been produced by reacting an aluminosilicate powder with an aqueous alkali silicate solution, in different dilution proportions, achieving very high geopolymerization conversion (higher than 97%). The monoliths microstructural and textural properties have been first characterized by SEM and porosimetric measurements, which revealed the structure of the geopolymer as mainly consisting of nanoprecipitates and mesopores, with overall porosity from 30% up to 60%, and BET surface area up to 50 m 2 /g. The analysis of the gas adsorption properties showed a quite good capacity for CO 2 in the geopolymer monoliths, remarkably higher than those of CH 4 and N 2 , pointing out the significant ability in the selective capture of CO 2 of these geopolymers. The values of selectivity in capacity obtained from the adsorption measurements, up to 200 and 100 for CO 2 /N 2 and CO 2 /CH 4 separation, respectively, are considerably higher than those of most of the adsorbent materials commonly accounted for in such applications.

Published

2016

21. Atmospheric plasma assisted PLA/microfibrillated cellulose (MFC) multilayer biocomposite for sustainable barrier application

Author

Peter Szabo, Vittorio Colombo, Romolo Laurita, Tom Lindström, Marco Giacinti Baschetti, Maria Grazia De Angelis, Augusto Stancampiano, Matteo Gherardi, Caglar Mericer, Jon Trifol, Matteo Minelli, Meriçer, Çağlar, Minelli, Matteo, De Angelis, Maria G., Giacinti Baschetti, Marco, Stancampiano, Augusto, Laurita, Romolo, Gherardi, Matteo, Colombo, Vittorio, Trifol, Jon, Szabo, Peter, and Lindström, Tom

Subjects

Materials science, Thin layers, Composite number, Nanotechnology, 02 engineering and technology, Multilayer film, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Barrier propertie, Polylactic acid, 0104 chemical sciences, Nanocellulose, chemistry.chemical_compound, chemistry, Chemical engineering, Ultimate tensile strength, Atmospheric plasma, Cellulose, Biocomposite, 0210 nano-technology, Layer (electronics), Agronomy and Crop Science

Abstract

Fully bio-based and biodegradable materials, such as polylactic acid (PLA) and microfibrillated cellulose (MFC), are considered in order to produce a completely renewable packaging solution for oxygen barrier applications, even at medium-high relative humidity (R.H.). Thin layers of MFC were coated on different PLA substrates by activating film surface with an atmospheric plasma treatment, leading to the fabrication of robust and transparent multilayer composite films, which were then characterized by different experimental techniques. UV transmission measurements confirmed the transparency of multilayer films (60% of UV transmission rate), while SEM micrographs showed the presence of a continuous, dense and defect free layer of MFC on PLA surface. Concerning the mechanical behavior of the samples, tensile tests revealed that the multilayer films significantly improved the stress at break value of neat PLA. Moreover, the oxygen barrier properties of the multilayer films were improved more than one order of magnitude compared to neat PLA film at 35 °C and 0% R.H. and the permeability values were maintained up to 60% R.H. The obtained materials therefore showed interesting properties for their possible use in barrier packaging applications as fully biodegradable solution, coupling two primarily incompatible matrices in a multilayer film with no need of any solvent or chemical.

Published

2016

22. Gas Transport in Glassy Polymers: Prediction of Diffusional Time Lag

Author

Matteo Minelli, Giulio Cesare Sarti, Minelli, Matteo, and Sarti, Giulio C.

Subjects

Materials science, glassy polymers, Non-equilibrium thermodynamics, Thermodynamics, Filtration and Separation, 02 engineering and technology, lcsh:Chemical technology, 010402 general chemistry, Thermal diffusivity, 01 natural sciences, Article, thermodynamics, Thermodynamic, Penetrant (mechanical, electrical, or structural), Potential gradient, Chemical Engineering (miscellaneous), lcsh:TP1-1185, lcsh:Chemical engineering, chemistry.chemical_classification, Process Chemistry and Technology, Glassy polymer, diffusion, gas permeability, NELF model, lcsh:TP155-156, Sorption, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Exponential function, Dilution, chemistry, Materials Science (all), 0210 nano-technology

Abstract

The transport of gases in glassy polymeric membranes has been analyzed by means of a fundamental approach based on the nonequilibrium thermodynamic model for glassy polymers (NET-GP) that considers the penetrant chemical potential gradient as the actual driving force of the diffusional process. The diffusivity of a penetrant is thus described as the product of a purely kinetic quantity, the penetrant mobility, and a thermodynamic factor, accounting for the chemical potential dependence on its concentration in the polymer. The NET-GP approach, and the nonequilibrium lattice fluid (NELF) model in particular, describes the thermodynamic behavior of penetrant/polymer mixtures in the glassy state, at each pressure or composition. Moreover, the mobility is considered to follow a simple exponential dependence on penetrant concentration, as typically observed experimentally, using only two adjustable parameters, the infinite dilution penetrant mobility L10 and the plasticization factor β, both determined from the analysis of the dependence of steady state permeability on upstream pressure. The available literature data of diffusional time lag as a function of penetrant upstream pressure has been reviewed and compared with model predictions, obtained after the values of the two model parameters (L10 and β), have been conveniently determined from steady state permeability data. The model is shown to be able to describe very accurately the experimental time lag behaviors for all penetrant/polymer pairs inspected, including those presenting an increasing permeability with increasing upstream pressure. The model is thus more appropriate than the one based on Dual Mode Sorption, which usually provides an unsatisfactory description of time lag and required an ad hoc modification.

Published

2018