A View on the Future of Applied Thermodynamics

Hemptinne, Jean-Charles de; Kontogeorgis, Georgios M.; Dohrn, Ralf; Economou, Ioannis G.; Kate, Antoon ten; Kuitunen, Susanna; Žilnik, Ljudmila Fele; Angelis, Maria Grazia De; Vesovic, Velisa

doi:10.1021/acs.iecr.2c01906

Cited by 34 publications

(27 citation statements)

References 88 publications

(166 reference statements)

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“…Creative GDE designs will be of paramount importance to overcome the flooding problem. , Multiscale/multiphysics modeling: CO2R at the electrode is a complex phenomenon that involves multiple phases (gas/liquid/solid) and reactions (homogeneous and heterogeneous), which are affected by the presence of electrolytes and electric field. Advanced modeling of the near-electrode and membrane environment will provide useful insights into the carbonation phenomena that is affected by mass transport, electrochemical and homogeneous reactions, and thermal effects. − Moreover, advanced thermodynamic modeling using electrolyte equations of state and molecular simulation are essential for predicting the key thermodynamic, transport, and structural properties of the relevant liquid systems. − Such properties are the mutual solubilities (e.g., gases in the aqueous electrolyte phase), transport coefficients (i.e., Maxwell-Stefan and self-diffusivities, ionic conductivities, viscosity), and partial molar properties. − Electrolyte-free electrolysis: The presence of electrolytes in CO 2 electrolyzers has several disadvantages. First, liquid products are contaminated with the electrolytes, which complicate the downstream process.…”

Section: Discussionmentioning

confidence: 99%

Carbonation in Low-Temperature CO₂ Electrolyzers: Causes, Consequences, and Solutions

Ramdin

Moultos

Broeke

et al. 2023

Ind. Eng. Chem. Res.

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Electrochemical reduction of carbon dioxide (CO2) to useful products is an emerging power-to-X concept, which aims to produce chemicals and fuels with renewable electricity instead of fossil fuels. Depending on the catalyst, a range of chemicals can be produced from CO2 electrolysis at industrial-scale current densities, high Faraday efficiencies, and relatively low cell voltages. One of the main challenges for up-scaling the process is related to (bi)carbonate formation (carbonation), which is a consequence of performing the reaction in alkaline media to suppress the competing hydrogen evolution reaction. The parasitic reactions of CO2 with the alkaline electrolytes result in (bi)carbonate precipitation and flooding in gas diffusion electrodes, CO2 crossover to the anode, low carbon utilization efficiencies, electrolyte carbonation, pH-drift in time, and additional cost for CO2 and electrolyte recycling. We present a critical review of the causes, consequences, and possible solutions for the carbonation effect in CO2 electrolyzers. The mechanism of (bi)carbonate crossover in different cell configurations, its effect on the overall process design, and the economics of CO2 and electrolyte recovery are presented. The aim is to provide a better understanding of the (bi)carbonate problem and guide research directions to overcome the challenges related to low-temperature CO2 electrolysis in alkaline media.

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Section: Discussionmentioning

confidence: 99%

Carbonation in Low-Temperature CO₂ Electrolyzers: Causes, Consequences, and Solutions

Ramdin

Moultos

Broeke

et al. 2023

Ind. Eng. Chem. Res.

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“…A short review of dissolution thermodynamics provides information on crystal morphologies and structures [20]. Collaboration between different organizations will foster new developments in applied thermodynamics [21].…”

Section: Discussionmentioning

confidence: 99%

Transition Energy, Orientation Force and Work Done in Transitional Behavior Atoms: Formulating New Principles in Thermodynamics

Ali

2022

Preprint

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Studying basic parameters of heat and thermodynamics may explore new principles in science. Gaseous and solid atoms under transitional behaviors can explore remarkable advances in chemical and physical sciences. An anomaly in the first law of thermodynamics can be recognized explicitly when the transitional behaviors of atoms are in the study. By gaining transition energy, gaseous atoms undertake a transition state. Hence, the work performs by the gaseous atoms. Symbolically, a plus sign requires for it. But the transitions in solid atoms occur because of the absorbing transition energy. So, the work performance is in the minus sign. A different force exerts on the electron of a gaseous atom and a solid atom, where transition energy changes the potential energy of the electron, thus controlling the orientation force. An anomaly resolves by changing the equations of internal energy. Gaseous and solid atoms introduce cooling and heat effects in elastically driven electronic states till the mid-states. A mid-state of a transition state falls between re-crystallization and liquid states. In generating cooling or heating energy, an electron executes dynamics by remaining within the occupied energy knot. Thus, constantly driven electronic states of atoms cause disorder and irreversible cycles.

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“…Thermodynamic equations of state (EoS) are fundamental tools in thermal and chemical engineering − They enable calculating properties of multicomponent systems as a function of experimentally accessible quantities such as temperature, pressure, and composition. Equations of state differ in the breadth of their applicability and complexity, and depending on the field of application, there are requirements on functionality, robustness, precision, and computational speed.…”

Section: Introductionmentioning

confidence: 99%

FeO_s: An Open-Source Framework for Equations of State and Classical Density Functional Theory

Rehner

Bauer

Groß

2023

Ind. Eng. Chem. Res.

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In this work, we present an open-source software package, referred to as FeOsFramework for Equations of State and Classical Density Functional Theory. FeOs is a collection of interfaces and data types that can be used (1) to implement thermodynamic equations of state and Helmholtz energy functionals for classical density functional theory, and (2) to compute thermodynamic properties of pure substances and mixtures, phase equilibria, and interfacial properties such as surface tensions and adsorption isotherms. The framework is written in the Rust programming language with a complete Python interface and is designed with a focus on usability and extensibility. It is openly available on GitHub (). Equations of state can be implemented in Rust, yielding performant code, or as a Python class, which is useful for prototyping and with less emphasis on execution speed. In both cases, the user has to implement a single function: the Helmholtz energy. FeOs then uses generalized (hyper-) dual numbers to evaluate the Helmholtz energy as well as the required exact partial (higher-order) derivatives. Using this type of automatic differentiation delivers performance without the need for implementing any analytical derivatives. The performance is further enhanced by a caching mechanism that avoids duplicate model evaluations. Together with the core interfaces and functionalities for equations of state and classical density functional theory, we provide implementations for multiple models such as the PC-SAFT equation of state (with homo- and heterosegmented group contribution methods) and Helmholtz energy functionals (including segment-based functionals). To showcase a selection of FeOs’ features, an example study of the adsorption of biogas in porous media using the PC-SAFT functional is provided.

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A View on the Future of Applied Thermodynamics

Cited by 34 publications

References 88 publications

Carbonation in Low-Temperature CO₂ Electrolyzers: Causes, Consequences, and Solutions

Carbonation in Low-Temperature CO₂ Electrolyzers: Causes, Consequences, and Solutions

Transition Energy, Orientation Force and Work Done in Transitional Behavior Atoms: Formulating New Principles in Thermodynamics

FeO_s: An Open-Source Framework for Equations of State and Classical Density Functional Theory

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A View on the Future of Applied Thermodynamics

Cited by 34 publications

References 88 publications

Carbonation in Low-Temperature CO2 Electrolyzers: Causes, Consequences, and Solutions

Carbonation in Low-Temperature CO2 Electrolyzers: Causes, Consequences, and Solutions

Transition Energy, Orientation Force and Work Done in Transitional Behavior Atoms: Formulating New Principles in Thermodynamics

FeOs: An Open-Source Framework for Equations of State and Classical Density Functional Theory

Contact Info

Product

Resources

About

Carbonation in Low-Temperature CO₂ Electrolyzers: Causes, Consequences, and Solutions

Carbonation in Low-Temperature CO₂ Electrolyzers: Causes, Consequences, and Solutions

FeO_s: An Open-Source Framework for Equations of State and Classical Density Functional Theory