Fact-checked by Grok 2 weeks ago

Binodal

In and , a binodal (or binodal curve, also known as the coexistence curve) represents the boundary in a that separates a single-phase region from a two-phase region in multi-component systems, such as or mixtures, where it delineates the compositions and temperatures at which into coexisting stable phases becomes thermodynamically favorable. This curve is determined by the condition that the chemical potentials of each component are equal between phases, often visualized through the common construction on the versus composition plot, where the slope of the tangent equals the difference in chemical potentials of the components, marking the limits of complete . Binodals are fundamental for predicting phase equilibria in solutions, alloys, and polymers, influencing processes like , emulsification, and material design. The binodal is mathematically defined by the equality of chemical potentials for each component across the coexisting phases. In binary mixtures, it typically forms a lens-shaped region below the critical temperature, with the curve converging at the critical point where the distinction between phases vanishes. For regular solution models, the interaction parameter \chi governs the curve: phase separation occurs when \chi > 2, where A relates to mixing enthalpy. Distinct from the spinodal curve, which bounds the region of absolute instability where small fluctuations spontaneously grow via , the binodal encloses metastable zones requiring for . In systems, binodals project as curves from bitangent lines on the surface, forming tie-lines that connect conjugate phases and aiding in the computation of liquid-liquid equilibria for applications in and separations. These concepts underpin the analysis of complex behaviors in , enabling precise control over microstructure formation in materials like blends and colloids.

Definition and Basic Concepts

Definition

In , the binodal, also known as the coexistence or binodal , is a in the isobaric temperature-composition plane for a that defines the boundary separating the region of complete (single-phase ) from the region where two phases coexist in . This boundary marks the conditions under which single-phase transition to metastable or unstable states upon crossing it, with binodal compositions corresponding to pairs of points connected by common tangents to the of mixing . At these points, the chemical potentials of each component are equal between the coexisting phases, ensuring as per the criteria for in multi-component systems. Phase diagrams, in which the binodal appears, serve as graphical representations of the states of a as functions of thermodynamic variables such as , , and . These diagrams illustrate the conditions under which different are stable or coexist, providing a visual for predicting phase behavior without requiring detailed experimental data for every point. For multi-component mixtures, the binodal specifically delineates the onset of , distinguishing it from other boundaries like those involving solid-liquid transitions. The concept of the binodal evolved from the foundational work of J. Willard Gibbs on the equilibrium of heterogeneous substances and his , which established the in systems with multiple phases and components, initially applied to mixtures in the late .

Relation to Phase Diagrams

The binodal curve serves as a fundamental boundary in phase diagrams, delineating the transition from a single-phase region to a two-phase coexistence region in multicomponent systems. In mixtures, it is commonly represented in composition- diagrams at constant , where the curve encloses the immiscibility gap, indicating compositions and temperatures at which occurs. In ternary systems, the binodal is a curve in the two-dimensional composition space (such as a Gibbs triangle) at constant temperature and , while for higher-order systems, it appears as a defining the limits of the two-phase domain. Less frequently, binodal curves are plotted in composition- diagrams to illustrate pressure-dependent phase behavior, particularly in systems sensitive to effects. Visually, the binodal is typically a , continuous curve that converges at critical points, where it often displays a cusp or , marking the or condition at which the coexisting phases become indistinguishable. In or models, the binodal exhibits around the equimolar composition (50 mol%), as the interaction energies between like and unlike species are balanced, leading to mirrored phase boundaries on either side of the midpoint. Conversely, in non- mixtures, such as those involving polymers with unequal self-interaction parameters, the binodal becomes asymmetric, with the critical point displaced toward the component with stronger cohesive forces, resulting in unequal extents of the . The binodal differs from tie lines, which are horizontal segments connecting the equilibrium compositions of the two coexisting phases within the two-phase region and terminate at points on the binodal itself. While tie lines facilitate the application of the to determine phase fractions, the binodal exclusively represents the locus of those endpoints. Additionally, the binodal should not be confused with solvus lines, which specifically outline the boundaries in solid solutions—such as in solid-solid or solid-liquid diagrams—whereas the binodal applies more broadly to liquid-liquid, gas-liquid, or general separations.

Thermodynamic Foundations

Free Energy and Phase Equilibrium

The binodal curve represents the locus of compositions in a where two phases coexist in , arising from the minimization of the system's total at constant and . The G is the appropriate for such conditions, as its natural variables are T, P, and the amounts of each component \{n_i\}. For a heterogeneous , stable occurs when the overall G is lower for a of two phases than for a single homogeneous phase, leading to the binodal as the boundary of this two-phase region. The fundamental condition for phase equilibrium between two phases \alpha and \beta is the equality of chemical potentials for each component i: \mu_i^\alpha = \mu_i^\beta. This ensures that there is no driving force for across the phase boundary, maintaining compositional stability. The \mu_i is rigorously defined as the partial molar derivative of the : \mu_i = \left( \frac{\partial G}{\partial n_i} \right)_{T,P,\{n_{j \neq i}\}}. In practice, for a of components 1 and 2, this condition applies to both, yielding two equations that determine the coexisting compositions on the binodal. Geometrically, the binodal is identified via the double tangent construction on the plot of molar g versus composition x (where x = x_1, the of component 1, and g = G/n with total moles n). The common line touches the g(x) at points x^\alpha and x^\beta, corresponding to the compositions, and the slope of this line equals the common value of \mu_1 - \mu_2. This slope condition follows from the relations \mu_1 = g + (1 - x) \frac{\partial g}{\partial x} and \mu_2 = g - x \frac{\partial g}{\partial x}, ensuring tangency at both points. Mathematically, the double tangent satisfies: \frac{g^\beta - g^\alpha}{x^\beta - x^\alpha} = \left. \frac{\partial g}{\partial x} \right|^\alpha = \left. \frac{\partial g}{\partial x} \right|^\beta = \mu_1 - \mu_2 The area beneath this tangent represents the minimized free energy of the two-phase mixture, with phase fractions given by the lever rule. For multicomponent systems, the construction generalizes to bitangent planes in higher-dimensional g(\mathbf{x}) space, projecting to the binodal hypersurface.

Spinodal Curve and Critical Points

The spinodal curve delineates the limit of local thermodynamic within the two-phase of a , serving as the inner boundary where small fluctuations become unstable. It is mathematically defined by the condition where the second derivative of the of mixing with respect to vanishes, \frac{\partial^2 [G](/page/G)}{\partial x^2} = 0. This criterion arises from the analysis of in multicomponent systems, indicating the point at which the homogeneous phase loses resistance to perturbations in . Beyond the spinodal—into the of negative curvature—the system undergoes spontaneous via , a diffusion-driven without an energy barrier. The critical point represents a special extremum on the spinodal curve where it intersects the binodal, marking the boundary between metastable and unstable phase behaviors. At this point, not only does \frac{\partial^2 G}{\partial x^2} = 0, but the third derivative also vanishes, \frac{\partial^3 G}{\partial x^3} = 0, ensuring an in the curve with zero slope in both the second and third derivatives. This coincidence eliminates any distinction between the binodal (equilibrium coexistence) and spinodal (stability limit), resulting in a point of maximum or minimum immiscibility. In binary mixtures, such critical points often manifest as the (UCST), where occurs upon cooling, or the (LCST), observed in systems like solutions due to entropy-driven effects. The relationship between the binodal and spinodal underscores the hierarchical nature of phase instability: the binodal encloses a broader two-phase region defined by global equilibrium via the double-tangent construction on the free energy surface, while the spinodal lies entirely within this region, bounding the subset where local instabilities dominate. Quenching a composition into the area between the binodal and spinodal leads to nucleation and growth mechanisms, whereas crossing the spinodal triggers the barrierless spinodal decomposition, highlighting the binodal's role in overall phase coexistence despite the spinodal's control over kinetic pathways.

Binary Systems

Construction in Binary Phase Diagrams

In binary phase diagrams for a mixture of two components, A and B, the binodal curve is plotted in a -composition space, where the composition axis represents the of one component (typically B) and the vertical axis denotes . This curve delineates the boundary between single-phase and two-phase regions, with points on the binodal corresponding to the compositions of the coexisting phases in at a given . The binodal is determined by solving the condition of equality for both components across the two phases at fixed , ensuring . Theoretically, the binodal can be constructed using the of mixing, G_m(x), as a function of composition x at constant temperature and pressure. For phase separation, the stable compositions are those where the free energy curve exhibits two minima, and the binodal points are identified by drawing common tangent lines to G_m(x), connecting the compositions of the coexisting phases; these tangents represent the minimum free energy path for the . This iterative involves selecting where the slopes (partial molar Gibbs energies, or chemical potentials) match, forming the locus of binodal compositions as temperature varies. The resulting two-phase region appears lens-shaped, bounded by the binodal curve, with tie lines indicating the equilibrium compositions within it. Experimentally, the binodal is mapped through measurements, where a homogeneous mixture is gradually cooled or heated until the first signs of (cloudiness) appear, indicating the binodal boundary for that . This method involves preparing samples of varying compositions and observing the onset of visually or optically. Light scattering techniques complement this by detecting changes due to emerging phase domains, providing precise binodal points, especially for solutions or near-critical regions. These approaches yield data points that are connected to form the binodal curve, often revealing behaviors such as upper or lower consolute solution temperatures.

Upper and Lower Consolute Temperatures

In binary mixtures exhibiting partial , the (UCST) represents the highest temperature at which occurs along the binodal curve, above which the components become fully miscible for all compositions due to the dominance of entropic contributions to the of mixing. This behavior is typical in non-polar systems where unfavorable enthalpic interactions, such as forces, drive demixing at lower temperatures, while thermal motion overcomes these interactions at higher temperatures. A classic example is the polystyrene-methylcyclohexane system, where the UCST is approximately 35°C, leading to complete above this point; such systems are common in solutions and blends, enabling applications in material processing like phase inversion for porous structures. Conversely, the lower critical solution temperature (LCST) marks the lowest temperature of the two-phase region, below which the mixture is fully miscible, as specific interactions like hydrogen bonding stabilize the homogeneous phase at low temperatures by reducing configurational entropy. Above the LCST, these interactions weaken with increasing thermal energy, promoting phase separation into compositionally distinct phases. This phenomenon is prevalent in aqueous solutions involving hydrogen-bonding solutes, such as poly(N-isopropylacrylamide) in water, where the LCST around 32°C facilitates thermoresponsive behaviors in hydrogels and drug delivery systems. In the nicotine-water binary mixture, for instance, the LCST is near 60°C, resulting in immiscibility above this temperature due to disrupted hydrogen bonds. Certain binary systems display both UCST and LCST behaviors, forming closed-loop binodals that resemble an hourglass shape in temperature-composition phase diagrams, with phase separation confined between the two consolute temperatures and full miscibility outside this loop. This closed-loop topology arises from competing enthalpic and entropic effects, often involving hydrogen bonding at low temperatures and volume expansion or specific attractions at intermediate ones; low-molecular-weight in exemplifies this, with an LCST around 95°C and a higher UCST, where increasing chain length shifts the LCST downward and enlarges the loop. influences these consolute points significantly: in blends like deuterated /poly(n-pentyl methacrylate), elevated decreases the UCST (by about -540°C/k) while increasing the LCST (by about 560°C/k), shrinking the closed loop until it vanishes above 200 , enhancing overall miscibility through reduced free volume differences.

Multicomponent Systems

Ternary Phase Diagrams

In ternary phase diagrams, the binodal curve delineates the boundary between single-phase and two-phase regions for systems comprising three components, typically represented on an where the vertices correspond to the pure components and the positions of points within the triangle indicate compositions that sum to unity. The interior of the binodal often forms a lens-shaped two-phase region, where tie lines connect the compositions of the coexisting s in , allowing determination of phase fractions via the . This triangular representation extends the binodal concept from systems by accommodating the additional degree of compositional freedom. The construction of the binodal in ternary diagrams involves solving the equalities of chemical potentials for each component across the coexisting phases, ensuring under specified temperature and pressure conditions. Experimentally, this is often achieved through methods, where mixtures are prepared until is observed, plotting the that encloses areas of immiscibility. The typically features plait points, where the two branches of the binodal meet, marking critical compositions at which the distinction between phases vanishes and a single homogeneous phase forms. A distinctive aspect of ternary binodals is the potential for adjacent three-phase regions, arising from Gibbs' phase rule, where an additional immiscible phase coexists with the two separated by the binodal, often forming a "fish-tail" structure in the diagram. For instance, in oil-water-surfactant systems, the binodal encloses two-phase regions of oil-rich and water-rich phases at low surfactant concentrations, while increasing surfactant leads to a three-phase region with a middle-phase microemulsion bridging the immiscible oil and . This configuration is critical in applications like , where the plait point influences microemulsion stability.

Extensions to Higher-Order Systems

In n-component systems, the binodal generalizes to a within the (n-1)-dimensional composition space at fixed and , delineating the boundary between single-phase and multiphase regions where the chemical potentials of each component are equal across coexisting phases. This arises from the minimization of the , ensuring for phase separations involving multiple components. The primary challenges in handling binodals for higher-order systems stem from their increased dimensionality, which complicates both and computational determination. Direct representation in high-dimensional space is impractical, often requiring approximations such as pseudo-binary or pseudo-ternary slices that reduce the problem to lower-dimensional cross-sections while preserving key features like gaps. Numerical methods, including iterative solutions to equalities, are essential for mapping these hypersurfaces accurately, particularly when interaction parameters vary across components. Examples of such binodals appear in quaternary alloys, such as Bi-containing III-V semiconductors like In_{1-y}Ga_yAs_{1-x}Bi_x, where the defines phase stability under epitaxial , influencing miscibility gaps and spinodal regions through considerations. In complex polymer blends, quaternary systems modeled by Flory-Huggins exhibit binodals that predict multi-phase separations, with hypersurfaces forming within the composition to guide blend design for enhanced material properties. , often with five or more components, further illustrate this, as their binodals determine resistance to phase decomposition, visualized via 2D compositional sections to assess stability in applications like structural materials.

Mathematical Modeling

Analytical Equations

In regular solution theory, the binodal curve for a is determined by equating the chemical potentials of each component in the coexisting phases, using derived from the Hildebrand-Scatchard equation. The for component 1 is given by \ln \gamma_1 = \beta (1 - x_1)^2, where \beta = \frac{V (\delta_1 - \delta_2)^2}{RT} incorporates the V and solubility parameters \delta_1, \delta_2 of the components, while x_1 is the of component 1. For the two coexisting phases \alpha and \beta, the binodal condition simplifies to x_1^\alpha \exp[\beta (1 - x_1^\alpha)^2] = x_1^\beta \exp[\beta (1 - x_1^\beta)^2], with the second component's equation following from (x_2 = 1 - x_1). This lacks a closed-form solution but defines the analytical boundary for in symmetric, non-ideal mixtures where enthalpic interactions dominate. The Flory-Huggins model extends regular solution theory to solutions and blends by accounting for entropic asymmetry due to differing chain lengths. The molar of mixing is expressed as \frac{\Delta G_m}{RT} = \frac{\phi_1}{N_1} \ln \phi_1 + \frac{\phi_2}{N_2} \ln \phi_2 + \chi \phi_1 \phi_2, where \phi_1, \phi_2 are volume fractions, N_1, N_2 are the degrees of (with N_1 = [1](/page/1) for and N_2 \gg 1 for ), and \chi is the Flory interaction parameter. The binodal arises from equality of chemical potentials in the coexisting phases. For a - system (N_1 = [1](/page/1), N = N_2), the conditions are \ln \left( \frac{\phi_1^\alpha}{\phi_1^\beta} \right) + \left(1 - \frac{1}{N}\right) (\phi_2^\alpha - \phi_2^\beta) + \chi [(\phi_2^\alpha)^2 - (\phi_2^\beta)^2] = 0, \ln \left( \frac{\phi_2^\alpha}{\phi_2^\beta} \right) + \left(1 - \frac{1}{N}\right) (\phi_1^\alpha - \phi_1^\beta) + \chi [(\phi_1^\alpha)^2 - (\phi_1^\beta)^2] = 0. For the symmetric case (N_1 = N_2 = [1](/page/1)), an exact implicit analytical solution for the binodal compositions exists, parameterizing the via \phi_1^\alpha = \phi, \phi_1^\beta = 1 - \phi, and solving for \chi(\phi). Outside the spinodal (where \partial^2 \Delta G_m / \partial \phi^2 > 0), this delineates metastable regions in phase diagrams. For more general non-ideal binary mixtures, the Margules equations provide flexible models to compute binodal curves, particularly when asymmetry requires multiple parameters. The one-parameter (two-suffix) Margules form is \ln \gamma_1 = A (1 - x_1)^2, \ln \gamma_2 = A x_1^2, mirroring regular solution theory with A as the interaction constant; the binodal is then found by solving x_1^\alpha \gamma_1(x_1^\alpha) = x_1^\beta \gamma_1(x_1^\beta). The two-parameter (three-suffix) extension is \ln \gamma_1 = x_2^2 [A_{12} + 2 (A_{21} - A_{12}) x_1], \ln \gamma_2 = x_1^2 [A_{21} + 2 (A_{12} - A_{21}) x_2], allowing fitting to experimental asymmetries; equilibrium follows the same equality, often yielding analytical expressions near the critical point via . These models are fitted to limited data to predict full binodals in contexts. The van Laar equations offer an alternative for binaries with strong composition dependence, suitable for liquid-liquid equilibria in systems like alcohol-water. The two-suffix form is \ln \gamma_1 = A_{12} \left( \frac{x_2}{x_1 + \frac{A_{12}}{A_{21}} x_2} \right)^2, \quad \ln \gamma_2 = A_{21} \left( \frac{x_1}{x_2 + \frac{A_{21}}{A_{12}} x_1} \right)^2, where A_{12}, A_{21} are constants. The binodal curve is obtained by solving the isothermal balance x_1^\alpha \gamma_1^\alpha = x_1^\beta \gamma_1^\beta, which emphasizes infinite dilution behavior and is analytically tractable for parameter estimation from tie-line data. Three-suffix extensions incorporate a third parameter for better predictions but retain solvability via numerical root-finding on the equilibrium conditions.

Numerical and Computational Approaches

Numerical methods become essential for computing binodal curves in systems where analytical solutions are intractable, such as multicomponent mixtures with nonlinear thermodynamic models or near-critical conditions. These approaches typically involve solving the isothermal condition of equal chemical potentials across coexisting phases, \mu_i^\alpha = \mu_i^\beta for each component i, or minimizing the total subject to constraints. Iterative deterministic methods, particularly the Newton-Raphson algorithm, are widely applied to solve the of chemical potential equalities iteratively, using the of partial derivatives to update phase compositions until convergence. This method efficiently traces the binodal by parameterizing along temperature or overall composition, starting from initial guesses derived from simpler models. For stochastic alternatives, Gibbs ensemble simulations determine binodal points by independently sampling two subvolumes representing coexisting phases, with moves that exchange particles and volumes to enforce and pressure equality, thereby tracing the coexistence curve through ensemble averaging. The original formulation of this technique has been extended to complex fluids, providing statistically robust results for phase boundaries in systems intractable to deterministic solvers. Commercial software like Aspen Plus supports binodal computation within phase envelope calculations via successive flash algorithms and thermodynamic property packages, enabling rapid prediction of liquid-liquid equilibria for applications. Custom implementations in often employ discretizations to approximate and minimize functionals, such as those from , yielding binodal loci through numerical optimization of phase compositions. These tools integrate seamlessly for hybrid workflows, where Aspen handles process-scale simulations and refines microscopic details. Convergence challenges in iterative methods like Newton-Raphson are prominent near critical points, where the becomes singular due to vanishing composition differences, leading to slow or failed and requiring factors, arc-length , or alternative initializations from reduced variables. Validation of computed binodals routinely involves direct comparison with experimental tie-line data, quantifying discrepancies via metrics like in phase compositions to assess model fidelity. Such numerical strategies extend analytical frameworks like Flory-Huggins to higher dimensions without explicit derivations.

Applications and Examples

In Polymer Blends and Solutions

In polymer blends, binodal curves delineate the boundary between miscible and immiscible regions in phase diagrams, enabling prediction of behaviors critical for tailoring material properties such as mechanical strength and transparency. The position of the binodal is primarily governed by the Flory-Huggins interaction parameter χ, which quantifies the enthalpic incompatibility between components; values of χ greater than the critical value of approximately 2/N (where N is the ) lead to at . This parameter, derived from the Flory-Huggins theory, incorporates both enthalpic and entropic contributions, with higher χ values shifting the binodal toward lower concentrations and promoting demixing. A representative example is found in polyethylene-polypropylene blends, which typically exhibit (UCST) binodals, where the polymers are miscible at high temperatures and phase separate upon cooling due to dominant enthalpic interactions. In such systems, the binodal curve allows engineers to control morphology by adjusting processing temperatures, resulting in co-continuous structures that enhance impact resistance in automotive components. To extend windows, compatibilizers like block copolymers are added, which localize at interfaces and reduce the effective χ, thereby shifting the binodal outward and stabilizing finer domain sizes. Experimentally, binodals in polymer blends are mapped using (), a technique that probes concentration fluctuations through scattering intensity profiles, from which χ and phase boundaries are extracted via the . is particularly advantageous for deuterated samples, providing contrast to resolve nanoscale phase evolution near the binodal without disrupting the system.

In Alloy and Chemical Process Design

In binary eutectic alloy systems, the binodal curves—manifested as the lines—bound the solid-liquid two-phase region in temperature-composition phase diagrams, dictating the progression of solidification and the resulting microstructure. These boundaries separate the fully liquid region above the liquidus from the fully solid region below the solidus, with compositions within the binodal defining or freezing paths that control formation and . For example, in the Al-Cu , the binodal curves () outline the coexistence of liquid and the aluminum-rich solid (α phase) during cooling through the two-phase region, with the copper-rich solid (θ phase, CuAl₂) forming via the eutectic reaction at 548 °C, enabling the design of precipitation-hardened s with tailored strength for structural applications in components. In , binodal curves play a critical role in liquid-liquid extraction processes by demarcating the boundary between single-phase miscible solutions and two-phase immiscible regions, guiding the selection of systems and the sizing of separation vessels. The curve's shape influences the volume fractions of the extract and phases, which must be optimized to prevent and ensure efficient disengagement in like mixer-settlers or centrifugal extractors. Tie-lines connecting points across the binodal provide compositions, allowing engineers to compute the minimum -to-feed ratio and the required extractor height based on rates, as demonstrated in the recovery of acetic acid from aqueous solutions using . The , applied across binodals to quantify phase fractions, has been integral to since the early 20th century, originating from interpretations of Gibbs' in metallic equilibria. Developed through the experimental constructions by H.W. Bakhuis Roozeboom around 1901, the rule calculates the proportion of each phase as the inverse ratio of the segment lengths from the overall composition to the binodal endpoints on an isothermal tie-line, facilitating predictions of solid fraction during to minimize defects like . This method underpins schedules for alloys, ensuring controlled phase transformations for desired mechanical properties.

References

  1. [1]
    Chapter 4: Phase Diagrams - Engineering LibreTexts
    Nov 14, 2023 · The spinodal points will define the spinodal boundary and the binodal points will define the boundaries of the 2-phase regions. Systems that ...
  2. [2]
    [PDF] Phase Diagrams and Phase Separation
    construction reduces to the condition. df/dc = 0 (i.e. horizontal tangent) This equation defines the binodal or coexistence curve.
  3. [3]
    Using the Intrinsic Geometry of Binodal Curves to Simplify ... - MDPI
    Sep 13, 2023 · Indeed, the binodal curves result from the projections of the one-parametric families of bitangent lines to the surface, while the spinodal ...<|control11|><|separator|>
  4. [4]
    https://doi.org/10.1351/goldbook.12240
  5. [5]
    Equilibrium Phase Diagram - an overview | ScienceDirect Topics
    An equilibrium phase diagram is defined as a graphical representation showing the stable regions of substances or solutions within a chemical system as a ...
  6. [6]
    Phase Diagrams for Real Systems (Chapter 9) - Thermodynamics
    In this chapter we describe the kinds of phase behavior that are commonly observed in pure fluids, binary mixtures, and some ternary mixtures. The descriptions ...
  7. [7]
    A Thorny Problem? Spinodal Decomposition in Polymer Blends
    Jun 9, 2020 · The origins of the term “spinodal” take us to 19th century thermodynamics in The Netherlands (11) and the van der Waals equation of state of ...
  8. [8]
    Page not found | ScienceDirect
    **Summary:**
  9. [9]
    Phase-Separating Binary Polymer Mixtures: The Degeneracy ... - NIH
    Typically, B11 and B22 differ substantially (B11 ≪ B22 or B11 ≫ B22) and the binodal becomes asymmetric. Even though each point on the binodal can be ...
  10. [10]
    Binary Phase Equilibria Tutorial - CalTech GPS
    At constant pressure and entropy, equilibrium is found at the minimum in enthalpy H = E + PV. For a phase, the Gibbs free energy is a function of P, T, and ...
  11. [11]
    [PDF] APPLICATION OF THE DOUBLE-TANGENT CONSTRUCTION OF ...
    This paper shows how the molar Gibbs energy change on mixing (gm) can be used to easily perform the double-tangent construction of coexisting phases for binary.Missing: binodal | Show results with:binodal
  12. [12]
    On spinodal decomposition - ScienceDirect
    On spinodal decompositionSur la decomposition spinodaleÜber die umsetzung an der spinodalen ... 6. J.W. Cahn, J.E. Hilliard. J. Chem. Phys., 31 (1959), p ...
  13. [13]
    [PDF] 11.28.05 Spinodals and Binodals; Continuous Phase Transitions
    Nov 28, 2005 · The functional form of free energies/chemical potentials, entropies, and enthalpies is not predicted by classical thermodynamics, because these ...<|separator|>
  14. [14]
    4/27/98 3 Deformation Morphologies and Toughening of Polymer ...
    A single phase present in the spinodal regime is unstable to small concentration fluctuations. A single phase present in the binodal (NG) regime is meta-stable ...
  15. [15]
    [PDF] Thermodynamics of mixing
    The binodal for binary mixtures coincides with the coexistence curve, since for a given temperature (or Nx) with overall composition in the two-phase region ...
  16. [16]
    Thermodynamic stability and critical points in multicomponent ... - NIH
    ... spinodal lies within the binodal, the region of global thermodynamic stability. Points where the spinodal and binodal make contact are critical points (cp's).
  17. [17]
    [PDF] Lecture 22: Spinodal Decomposition: Part 1
    Binodal Curve or Coexistence Curve: It is a curve (like the bell-like one shown above) defining the region of composition and temperature in a phase diagram ...
  18. [18]
    Binodal curve measurements for (water + propionic acid + ...
    The binodal curve results were determined by cloud point measurements method. ... To verify this prediction, the light scattering experiments were performed.
  19. [19]
    Measurement of cloud point temperature in polymer solutions
    Jul 30, 2013 · Usually, it is assumed that the cloud point curve coincides with the binodal curve,29 i.e., the locus of the phase separation boundary couples ...
  20. [20]
    Phase separation in aqueous solutions of lens y-crystallins - PNAS
    solutions (7, 10, 18). The experimental methods used to obtain cloud-point curves and binodal curves have been described in detail.
  21. [21]
    https://www.damtp.cam.ac.uk/user/gold/pdfs/JChemPhys_78_1492.pdf
  22. [22]
    [PDF] Theory of multiple phase separations in binary mixtures
    Jan 1, 2011 · This model predicts that the phase separation per- sists for all temperatures lower than the upper critical solution temperature (UCST). It will ...
  23. [23]
    https://www.ncnr.nist.gov/programs/sans/pdf/publications/0367.pdf
  24. [24]
    Ternary Systems | PNG 520: Phase Behavior of Natural Gas and ...
    The binodal curve is the boundary between the 2-phase condition and the single-phase condition.Missing: definition | Show results with:definition
  25. [25]
    [PDF] Ternary phase diagrams 1 Introduction
    Phase curves (so-called binodal curves) separating the one- and two-phase systems are presented in triangular phase diagrams.
  26. [26]
    https://www.ncnr.nist.gov/summerschool/ss08/pdf/SANS1.pdf
  27. [27]
    [PDF] 1 PHASE TRANSITIONS IN POLYMERIC AND MICELLAR ...
    The phase diagram of a ternary micellar system (Kahlweit and Strey, 1985) is represented by a triangle (A: water, B: oil and C: surfactant). The three binary ...
  28. [28]
    Formulation of Polymer-Augmented Surfactant-Based Oil–Water ...
    It is crucial to develop ternary phase diagrams in order to identify systems that provide the concentration range where microemulsion production occurs. From an ...
  29. [29]
    Phase diagrams calculated for quaternary polymer blends
    Sep 1, 1995 · A method is presented that allows the calculation of phase diagrams (spinodal, binodal, and tie lines) of quaternary mixtures on the basis ...
  30. [30]
    Accelerating multicomponent phase-coexistence calculations with ...
    Dec 24, 2024 · where the summations exclude the species for which the chemical potential ... binodal curves originating from a critical point. Otherwise, the ...2 Methods · 2.3 Machine Learning Details · 3 Results
  31. [31]
    Phase behavior in multicomponent mixtures - Frontiers
    In this article, we study the phase behavior of two polydisperse hydrocolloids: dextran and polyethylene oxide.Missing: hypersurface | Show results with:hypersurface
  32. [32]
    Stability of High Entropy Alloys to Spinodal Decomposition
    Aug 16, 2021 · Beneath the miscibility gap is a spinodal hypersurface above which HEAs are stable to a continuous change of phase via spinodal decomposition.
  33. [33]
    Predicting phase behavior in multicomponent mixtures
    Jul 10, 2013 · The analog of a binodal in a one-component fluid is thus an (n + ... Lattice model. Assigning each component a chemical potential μi, we ...Ii. Theory · Iv. Methods: Monte Carlo... · V. Results
  34. [34]
    Thermodynamic stability analysis of Bi-containing III-V quaternary ...
    Binodal and spinodal isotherm contours are presented for Bi-based quaternary systems as a function of strain state. •. Incorporation of an anion element with a ...
  35. [35]
    Analytical Solution to the Flory–Huggins Model - ACS Publications
    Aug 17, 2022 · A self-consistent analytical solution for binodal concentrations of the two-component Flory–Huggins phase separation model is derived.Supporting Information · Author Information · Acknowledgments · References
  36. [36]
    Revising Concepts on Liquid–Liquid Extraction: Data Treatment and ...
    Dec 30, 2021 · Distinction is made between solubility curve and binodal curve, setting the stability limit which is defined by the spinodal curve. In addition, ...<|separator|>
  37. [37]
    Ternary liquid—liquid equilibria: the van laar equation - ScienceDirect
    The capabilities of the three suffix van Laar equations in predicting the more complex types of ternary liquid—liquid phase diagrams have been examined.
  38. [38]
    Accurate determination of binodal, spinodal, and plait points using ...
    The binodal curve, spinodal curve, and plait point are key features of liquid–liquid equilibrium (LLE) phase diagrams, essential for understanding and ...Missing: definition | Show results with:definition
  39. [39]
    Direct determination of phase coexistence properties of fluids by ...
    A methodology is presented for Monte Carlo simulation of fluids in a new ensemble that can be used to obtain phase coexistence properties of multicomponent ...
  40. [40]
    [PDF] LIQUID-LIQUID EQUILIBRIUM FOR THE DESIGN OF EXTRACTION ...
    The number of theoretical stages is calculated using ASPEN. PLUS SOFT WARE. Keywords: Liquid-Liquid Extraction. The tie –line. binodal curves. INTRODUCTION.
  41. [41]
    A Machine Learning Approach for Phase-Split Calculations in n ...
    Apr 6, 2022 · ... Newton's method fails to converge near the critical point and phase boundaries. Thus, good initial guesses are required for the phase ...
  42. [42]
    Calculation of ternary liquid-liquid equilibrium data using arc-length ...
    Sep 7, 2020 · This condition represents the transition border of the binodal curve from type II to type I. Figure 13 depicts this behavior in comparison ...
  43. [43]
    https://ocw.mit.edu/courses/3-063-polymer-physics-spring-2007/7b9983cf44b82a340025a37a074f8709_lec3_07.pdf
  44. [44]
    [PDF] Mean Field Flory Huggins Lattice Theory
    Binodal curve is given by finding common tangent to ΔG m. (φ) curve for each φ, T combination. Note with lattice model (x. 1. = x. 2. ) (can use volume fraction ...
  45. [45]
    Phase behavior of semicrystalline polymer blends - ScienceDirect.com
    The phase behavior of the semicrystalline polymer blend composed of isotactic polypropylene (iPP) and linear low density polyethylene (PE) was studied
  46. [46]
    Multiblock Copolymers as Next-Generation Compatibilizers | JACS Au
    Jan 31, 2022 · We lay out recent advances in synthesis and understanding for two types of multiblock copolymers currently being developed as blend compatibilizers: linear and ...Introduction · Linear Multiblock Copolymer... · Grafted Multiblock Copolymer...
  47. [47]
    [PDF] 1 a tutorial on small-angle neutron scattering from polymers
    Small-angle neutron scattering (SANS) is a well-established characterization method for ... How to determine the spinodal line in incompressible polymer blends? 5 ...
  48. [48]
    Concentration fluctuation in binary polymer blends: χ parameter ...
    Jul 1, 2002 · The measured quantity in small-angle neutron scattering (SANS) experiments is an apparent χ a that includes long wavelength critical and ...
  49. [49]
    [PDF] Lecture 19: 11.23.05 Binary phase diagrams
    These binary systems, with unlimited liquid state miscibility and low or negligible solid state miscibility, are referred to as eutectic systems. X. B. ➞. T. L.
  50. [50]
    [PDF] Experimental Description of the Al-Cu Binary Phase Diagram
    May 21, 2019 · The Al-Cu system, being the key binary system for many Al-based, Cu-based, and dural alloys, has been investigated intensively over recent.
  51. [51]
    Revising Concepts on Liquid–Liquid Extraction: Data Treatment and ...
    Dec 30, 2021 · The binodal curve must be determined using a precise analysis of the separated equilibrium phases. The spinodal curve can be obtained using ...
  52. [52]
    Liquid–Liquid Phase Separation of Two Non-Dissolving ... - MDPI
    This point occurs on the binodal curve when both liquid phases reach the same composition. Figure 1d shows a triangular phase diagram for type II systems.2. Thermodynamic Basis · 2.2. Phase Diagrams · 3.3. Centrifugal Separators
  53. [53]
    Historic Note No. 1: Gibbs' Phase Rule - Thermo-Calc Software
    But that changed in 1901 when Bakhuis Roozeboom in Holland finally started exploring the usefulness of Gibbs' phase rule.
  54. [54]
    (PDF) Hendrik-Willem Bakhuis Roozeboom: Equilibrium and Phase ...
    Aug 6, 2025 · Hendrik-Willem Bakhuis Roozeboom (1854–1907) is well known for his applications of the phase rule to the study of heterogeneous equilibrium.