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Apparent viscosity

Apparent viscosity is a rheological property defined as the ratio of shear stress to shear rate for a fluid under specific flow conditions, serving as an effective measure of flow resistance in non-Newtonian fluids where true viscosity is not constant. Unlike Newtonian fluids, such as water or air, where viscosity remains independent of shear rate, apparent viscosity varies with the applied shear, reflecting the fluid's nonlinear response to deformation. This concept is mathematically expressed as \mu_{app} = \frac{\tau}{\dot{\gamma}}, where \tau is the shear stress and \dot{\gamma} is the shear rate, allowing it to capture instantaneous flow behavior. In non-Newtonian fluids, apparent viscosity can decrease with increasing in shear-thinning (pseudoplastic) materials, such as paints, , or solutions, facilitating easier under stress like during application or circulation. Conversely, in shear-thickening () fluids, such as certain suspensions or cornstarch mixtures, it increases with , providing protective thickening under high impact. These behaviors are often modeled using the power-law equation \tau = K \dot{\gamma}^n, where K is the consistency index and n is the behavior index (n < 1 for shear-thinning, n > 1 for shear-thickening), enabling prediction of in engineering contexts. Apparent viscosity is crucial in fields like , , and , where it influences design of pipelines, systems, and product formulations by accounting for real-world flow variations rather than idealized constant . Measurement typically involves rheometers that apply controlled rates to plot curves, revealing the fluid's response across conditions. Understanding this property helps mitigate issues like pumping inefficiencies or inconsistent in industrial applications.

Fundamentals

Definition

Apparent viscosity, denoted as \eta_a, is defined as the ratio of \tau to \dot{\gamma} at a specific flow condition. This measure treats the as if it were Newtonian for analytical purposes, even though the exhibits non-Newtonian . The basic equation for apparent viscosity is given by \eta_a = \frac{\tau}{\dot{\gamma}}, where it represents an instantaneous value that varies with the applied , providing a practical effective for complex fluids. This shear-rate-dependent quantity simplifies the analysis of non-Newtonian fluids, such as melts or suspensions, by allowing to approximate flow resistance under defined conditions without needing full rheological models. The term apparent viscosity emerged in early 20th-century studies, with significant developments by Eugene C. Bingham in the 1920s, who linked it to non-linear flow behaviors observed in yield stress materials like kaolin suspensions. In Newtonian fluids, apparent viscosity remains constant and equals the true , serving as a baseline for comparison.

Relation to and Rate

Shear stress, denoted as \tau, represents the tangential per area applied to a , driving its deformation and in a specific . This arises from interactions between layers sliding one another, such as in the within a velocity gradient. Shear rate, symbolized as \dot{\gamma}, quantifies the rate of this deformation and is defined as the velocity gradient perpendicular to the , typically expressed in s of s⁻¹. It measures how rapidly adjacent layers move relative to each other, influencing the fluid's resistance to . In non-Newtonian fluids, the relationship between and deviates from the linear proportionality observed in Newtonian fluids, where is directly proportional to with a constant . Instead, this relationship is nonlinear, leading to variable flow resistance that depends on the imposed deformation. Apparent viscosity emerges as the ratio \eta = \tau / \dot{\gamma}, providing an effective measure of at any given , though it is not constant across conditions. Flow curves, which plot against , illustrate these deviations vividly, often presented on a log-log to highlight the nonlinear behavior and power-law-like trends over wide ranges of deformation. On such log-log plots of \tau versus \dot{\gamma}, Newtonian fluids appear as straight lines with a of 1, whereas non-Newtonian fluids show curving or sloped lines indicating changing resistance. Apparent viscosity is determined as the secant from the to a specific point on the flow curve, i.e., the \tau / \dot{\gamma}, quantifying the fluid's effective Newtonian-like response under those conditions. Pseudoplastic fluids, also known as shear-thinning materials, exhibit a decrease in apparent viscosity as increases, resulting in easier flow under higher deformation rates. Common examples include solutions and paints, where structural alignments or breakdowns reduce internal . In a log-log of apparent viscosity versus shear rate, this behavior manifests as a downward-sloping line, with viscosity dropping sharply at moderate to high \dot{\gamma} values before potentially plateauing. Conversely, dilatant fluids, or shear-thickening ones, display an increase in apparent viscosity with rising shear rate, as particle interactions or alignments stiffen the material. Such fluids, like certain suspensions of cornstarch in , show an upward-sloping line on the viscosity profile, where flow becomes more resistant under intense shearing. This concept of apparent viscosity serves as a foundational prerequisite for rheological modeling, as it captures the local, effective from the mimicking Newtonian on the nonlinear , enabling analysis of complex without assuming constancy.

Rheological Models

Power-Law Fluids

The power-law model, also known as the Ostwald-de Waele relationship, provides a foundational framework for describing the rheological of certain non-Newtonian fluids where the \tau relates nonlinearly to the \dot{\gamma}. In this model, the relationship is expressed as \tau = K \dot{\gamma}^n, where K is the consistency index (with units of Pa·s^n) that characterizes the fluid's viscous properties, and n is the dimensionless flow behavior index that determines the type of non-Newtonian response. For Newtonian fluids, n = 1, reducing the model to \tau = K \dot{\gamma} with constant viscosity. Values of n < 1 indicate shear-thinning (pseudoplastic) behavior, where viscosity decreases with increasing shear rate, while n > 1 denotes shear-thickening (dilatant) behavior, where viscosity increases. The apparent viscosity \eta_a for power-law fluids is derived directly from the definition \eta_a = \tau / \dot{\gamma}, yielding \eta_a = K \dot{\gamma}^{n-1}. This equation explicitly demonstrates the -rate dependence of , central to apparent viscosity in non-Newtonian contexts: for shear-thinning fluids (n < 1), \eta_a decreases as \dot{\gamma} increases (since n-1 < 0), facilitating easier flow under stress; conversely, for shear-thickening fluids (n > 1), \eta_a rises with \dot{\gamma}, enhancing resistance. This dependence arises from the power-law assumption applied to the general stress-rate relation, making it a simple yet effective approximation for intermediate regimes. Representative examples illustrate the model's utility. Paints often exhibit shear-thinning behavior with n \approx 0.5, allowing high viscosity at low shear rates (e.g., \dot{\gamma} = 0.1 s^{-1}) for drip resistance, where \eta_a might be around 32 Pa·s assuming K = 10 Pa·s^n, but dropping to 1 Pa·s at high shear (e.g., \dot{\gamma} = 100 s^{-1}) for smooth application. In contrast, cornstarch-water suspensions (typically 50-55 wt.% solids) display shear-thickening behavior, enabling phenomena like "walking on water" under impact. Despite its simplicity, the power-law model serves as an approximation with notable limitations, particularly at extreme rates. For shear-thinning fluids (n < 1), it predicts infinite \eta_a as \dot{\gamma} \to 0 and zero \eta_a as \dot{\gamma} \to \infty, which contradicts real fluids that approach finite Newtonian plateaus; thus, it is unreliable outside intermediate shear ranges where experimental data align with the power-law fit.

Cross and Carreau Models

The and Carreau models represent empirical rheological frameworks designed to describe the apparent viscosity of shear-thinning fluids that exhibit Newtonian plateaus at both low and high rates, extending beyond simpler unbounded models by incorporating asymptotic behaviors. These models are particularly valuable for fluids where transitions smoothly from a zero- value to an infinite- limit, enabling more accurate predictions across wide ranges encountered in practical flows. The Cross model, proposed by Malcolm M. Cross in , expresses the apparent viscosity \eta_a as a of \dot{\gamma} through the equation: \eta_a = \eta_\infty + \frac{\eta_0 - \eta_\infty}{1 + ([\lambda](/page/Lambda) \dot{\gamma})^m} Here, \eta_0 denotes the zero- , representing the Newtonian plateau at low s; \eta_\infty is the infinite- , the lower at high ; [\lambda](/page/Lambda) is a related to the onset of ; and m (typically between 0 and 1) controls the sharpness of the transition. This four-parameter form allows fitting to experimental data via nonlinear least-squares optimization on logarithmic plots of versus , often yielding [\lambda](/page/Lambda) values on the order of 0.1–10 s for systems and m around 0.5–0.8 to capture moderate transitions. The Carreau model, developed by Pierre J. Carreau in 1972, provides a similar but analytically smoother description, emphasizing molecular network theories for viscoelastic fluids: \eta_a = \eta_\infty + (\eta_0 - \eta_\infty) [1 + (\lambda \dot{\gamma})^2]^{(n-1)/2} In this equation, the parameters mirror those of the Cross model, with \eta_0 and \eta_\infty as the viscosity limits, \lambda as the relaxation time, and n (0 < n < 1) as the power-law exponent influencing the thinning slope in the intermediate regime. Parameter estimation follows a comparable nonlinear regression approach, frequently applied to capillary rheometer data, where n values near 0.6–0.9 fit shear-thinning polymers, and \lambda scales with molecular weight. These models find application in modeling solutions, where the Cross equation effectively captures the -dependent of concentrated melts like , enabling predictions of flow in processes by fitting parameters to rotational measurements. In blood , the Carreau model simulates the non-Newtonian behavior of , accounting for aggregation at low (high \eta_0) and alignment at high (low \eta_\infty), with typical showing \eta_0 \approx 0.056 Pa·s, \eta_\infty \approx 0.0035 Pa·s, \lambda \approx 3.313 s, and n \approx 0.3568 for physiological conditions. Such outperform unbounded alternatives in extremes, as power-law approximations hold only in intermediate regimes without capturing the plateaus. A key advantage of the Cross and Carreau models over the power-law is their incorporation of bounded Newtonian limits, preventing unphysical divergences at low shear (where power-law predicts infinite viscosity) and ensuring finite high-shear values, thus improving accuracy for broad-range simulations in processing and hemodynamic flows. This asymptotic fidelity enhances predictive reliability when extrapolating beyond measured data, as validated in fits to diverse experimental datasets.

Measurement Techniques

Viscometry Methods

Viscometry methods provide essential laboratory techniques for quantifying apparent (η_a) in non-Newtonian fluids by imposing controlled shear flows and measuring the ratio of (τ) to (γ̇), where η_a represents an effective at specific conditions. These approaches allow construction of flow curves—plots of τ versus γ̇ or η_a versus γ̇—to characterize shear-dependent behavior across a range of rates. Capillary viscometry adapts Poiseuille's law for non-Newtonian flows by forcing the fluid through a cylindrical tube of radius R and length L, using the ΔP and Q to compute wall and apparent . The wall is given by τ_w = (ΔP R) / (2 L), independent of fluid , while the apparent at the wall is γ̇_a = 4 Q / (π R^3); thus, η_a = τ_w / γ̇_a yields the apparent viscosity at this nominal rate. For non-Newtonian fluids, the velocity profile deviates from parabolic, requiring the Rabinowitsch correction to obtain the true wall : \dot{\gamma}_w = \dot{\gamma}_a \left( \frac{3}{4} + \frac{1}{4} \frac{d \ln \dot{\gamma}_a}{d \ln \tau_w} \right) This correction, derived from integrating the momentum balance, accounts for the non-uniform shear across the radius and enhances accuracy for pseudoplastic or dilatant behaviors. Rotational viscometers employ geometries like Couette (concentric cylinders) or cone-plate to generate simple shear, measuring torque as a function of angular velocity to derive η_a. In a narrow-gap Couette setup, the inner cylinder rotates at angular velocity Ω while the outer remains stationary; the nominal shear rate is γ̇ ≈ (R_i Ω) / (R_o - R_i), where R_i and R_o are inner and outer radii, and shear stress τ = M / (2 π R_i^2 h) with torque M and gap height h, allowing η_a = τ / γ̇. Cone-plate geometry maintains constant γ̇ = Ω / α throughout the small cone angle α, minimizing edge effects and providing uniform stress distribution, which is particularly suitable for low-viscosity or shear-thinning non-Newtonian fluids. Standard procedures involve steady-state measurements, where the system equilibrates at constant applied stress or rate until torque or pressure stabilizes, typically over several minutes per point, across a decade or more of γ̇ values to generate comprehensive flow curves. Common error sources include wall slip, where the fluid detaches from the surface due to weak adhesion in suspensions or polymers, artificially lowering measured τ and η_a; this is mitigated by using roughened walls or multiple capillary diameters to extrapolate true values. The evolution of these methods traces to Eugene C. Bingham's 1916 capillary experiments on yield-stress materials like paints, adapting Poiseuille's framework to non-Newtonian "plastic" flow despite initial assumptions of Newtonian-like profiles. Refinements, such as the Rabinowitsch correction, addressed profile distortions, paving the way for modern automated capillary rheometers that integrate precise drives, transducers, and software for real-time corrections and .

Rheometer Applications

Rheometers enable precise measurement of apparent viscosity (η_a) in settings by operating in two primary modes: controlled- and controlled-rate. In controlled- mode, a constant or varying is applied to the sample, allowing the to measure the resulting or , which is particularly useful for probing low- behaviors and in fluids where η_a may vary nonlinearly with deformation. Conversely, controlled-rate mode imposes a specified or , measuring the corresponding response, which facilitates direct calculation of η_a = τ / γ̇ for steady flows and is ideal for high- regimes encountered in melts or suspensions. These modes can be applied under both steady and oscillatory conditions, with oscillatory tests providing dynamic moduli (G' and G'') from which the |η*| is derived, offering insights into viscoelastic contributions to apparent viscosity without inducing structural breakdown. Advanced protocols such as creep recovery and stress relaxation further refine the profiling of time-dependent apparent viscosity in non-Newtonian materials. Creep recovery involves applying a constant stress to induce deformation ( phase), followed by stress removal to observe (recovery phase), allowing researchers to quantify recoverable and viscous dissipation, which inform the time-dependent evolution of η_a in thixotropic or viscoelastic fluids. , by contrast, applies a fixed and monitors the decay in over time, revealing relaxation times that characterize how η_a approaches zero-shear limits in entangled systems like solutions. These techniques are essential for inferring η_a in scenarios where steady-state assumptions fail, such as in yield- fluids, by separating elastic and viscous components through compliance functions J(t). Data processing in rheometry often employs master curves and the Cox-Merz rule to correlate steady and dynamic measurements, enhancing the predictive power for apparent across wide ranges. Master curves are constructed via time-temperature superposition, shifting isothermal data to a reference to generate a broad-spectrum profile, which captures η_a over inaccessible experimental timescales in materials like amorphous . The Cox-Merz rule empirically links the steady-shear apparent η(γ̇) to the magnitude of the complex |η*(ω)| by equating them when ω replaces γ̇, enabling estimation of nonlinear steady-shear data from linear oscillatory tests—a validation observed in numerous monodisperse systems. This superposition facilitates model fitting for rheological constitutions without exhaustive experimentation. In the 2020s, microfluidic rheometers have advanced apparent viscosity measurements for minuscule samples, particularly in fluids like nanofluids and suspensions, requiring volumes as low as microliters. These devices integrate microchannels with pressure-driven flows to achieve high shear rates (up to 10^6 s^-1) while minimizing sample use, ideal for scarce where traditional rheometers demand milliliters. For instance, in dispersions, microfluidic setups reveal shear-thinning η_a profiles influenced by particle , aiding optimization of enhancements in nanofluids. Such innovations, often combining optical or electrical detection, extend rheometric precision to emerging fields like nano-enhanced lubricants, where apparent viscosity dictates flow stability at microscales.

Practical Applications

Industrial Processes

In industrial pumping and piping systems, apparent viscosity plays a critical role in handling shear-thinning non-Newtonian fluids, such as melts during processes. Shear-thinning behavior, where apparent viscosity decreases with increasing , allows for reduced pressure drops and lower in pumping operations by facilitating easier at higher velocities typical of industrial pipelines. For instance, in , this property minimizes power requirements, as higher screw speeds induce greater s that lower the effective viscosity, thereby enhancing throughput while reducing operational costs. To predict regimes in such systems, engineers employ a generalized adapted for non-Newtonian fluids, which incorporates apparent viscosity derived from models like the Herschel-Bulkley extended form to account for yield stress and shear-dependent effects, enabling accurate design of laminar-to-turbulent transitions in networks. In , apparent viscosity governs the efficiency of mixing and for complex fluids like sauces and , which often exhibit shear-thinning characteristics. For sauces, such as tomato-based formulations, higher apparent viscosity at low shear rates ensures stability during storage and prevents , while shear-thinning during mixing reduces energy input and improves homogeneity by allowing easier incorporation of ingredients under agitation. In dough , ingredients like or oils influence apparent viscosity, directly impacting extrusion rates; for example, stable viscosity profiles under high-shear conditions in twin-screw extruders promote uniform product expansion and consistent output, optimizing production lines for baked goods or . These properties are often approximated using the power-law model for rapid process adjustments. In the oil and gas sector, specialized shear-thickening additives, such as deformable particles or certain polymers, are incorporated into otherwise shear-thinning drilling fluids to exhibit dilatant behavior under high shear, increasing viscosity to form a robust seal and prevent lost circulation into fractured formations. These additives trigger rapid viscosity buildup at the bit or loss zones, bridging fractures and minimizing fluid invasion while maintaining pumpability at lower shears during circulation. This approach enhances drilling safety and efficiency without compromising overall fluid rheology. Optimization strategies in leverage tailored apparent viscosity profiles to boost throughput and product quality, as seen in formulation case studies. By adjusting rheology modifiers to achieve desired -thinning or yield stress characteristics, formulators ensure paints flow easily during high- application (e.g., spraying) while resisting sagging at low , thereby increasing application and reducing waste. Such targeted apparent viscosity engineering, often informed by , minimizes energy use in mixing and while maximizing output in coatings .

Biomedical Uses

In biomedical contexts, apparent viscosity plays a crucial role in the of , a whose apparent viscosity decreases with increasing due to the deformation and alignment of red blood cells (RBCs), which reduces internal friction and enhances flow efficiency. This shear-thinning behavior is particularly evident in the , where the Fåhræus-Lindqvist effect further lowers apparent viscosity in small vessels (diameters below 300 μm) as RBCs migrate axially, forming a cell-free marginal layer that minimizes wall interactions and apparent resistance to flow. The Cross model effectively captures this transition, describing blood's apparent viscosity as approaching a Newtonian at high shear rates above approximately 100 s⁻¹, where RBC alignment dominates over aggregation. Apparent viscosity is leveraged in drug delivery systems through shear-thinning hydrogels, which exhibit high viscosity at rest to form stable depots in tissues but reduce apparent viscosity dramatically under the high shear of injection needles, enabling minimally invasive administration. For instance, hyaluronic acid-based gels demonstrate this property, with apparent viscosity dropping by orders of magnitude at shear rates exceeding 100 s⁻¹ during extrusion, allowing easy flow through 25-gauge needles while rapidly recovering post-injection to encapsulate therapeutics like chemotherapeutics or biologics over weeks. This design improves patient compliance and targeted release, as seen in formulations for ocular or subcutaneous delivery where sustained viscosity post-injection prevents premature diffusion. In , apparent viscosity of is modeled to develop biomimetic lubricants that replicate its shear-thinning characteristics, ensuring low during motion while providing load-bearing support at rest. 's apparent viscosity, primarily from high-molecular-weight hyaluronan and lubricin, decreases under rates typical of walking (10-100 s⁻¹), facilitating of surfaces and reducing in engineered constructs. Researchers engineer scaffolds with tunable apparent viscosity, such as hyaluronan composites, to mimic this for treatments, where viscosupplementation restores and promotes tissue regeneration without inflammation. Recent 2020s research highlights how alters respiratory apparent viscosity, increasing it through hypersecretion and , which impairs ciliary clearance and airflow in airways. Studies from 2021-2024 show that infected patients' exhibits elevated apparent viscosity (up to 10-100 times normal at low shear rates below 1 s⁻¹), forming plugs that elevate and reduce expiratory flow rates by 50% or more, contributing to ventilation-perfusion mismatches and severe . This viscoelastic stiffening, driven by MUC5AC overproduction, links directly to prolonged needs, prompting therapies like mucolytics to restore shear-dependent flow.

References

  1. [1]
    Fundamental Properties of Fluids – Introduction to Aerospace Flight ...
    Notice from the figure above that the apparent viscosity may increase or decrease with an increasing strain rate, depending on the nature of the fluid. For ...
  2. [2]
    Apparent Viscosity - an overview | ScienceDirect Topics
    Apparent viscosity is defined as the measure of viscosity experienced under specific circumstances, which may differ from true viscosity due to factors such as ...
  3. [3]
    What is rheology? - PMC - PubMed Central - NIH
    Dec 22, 2017 · Both materials are non-Newtonian and the apparent viscosity will depend on the shear rate: to compare the spreads we need to know the shear ...<|control11|><|separator|>
  4. [4]
    [PDF] Bingham's heritage - HAL ENPC
    May 3, 2018 · Thus the Bingham approach is the basic concept, but a refinement is needed in order to describe this specific type of behavior: the apparent ...
  5. [5]
    https://www.wiley.com/en-us/Transport+Phenomena%2C+2nd+Edition-p-9780471410775
  6. [6]
    Basics of rheology | Anton Paar Wiki
    Definition of terms: Shear stress, shear rate, law of viscosity, kinematic viscosity. The two-plates model is used to define the rheological parameters needed ...Missing: apparent | Show results with:apparent
  7. [7]
    None
    ### Summary of Non-Newtonian Flows Content
  8. [8]
    [PDF] Non Newtonian Fluid Dynamics - PDH Online
    The value of shear stress can be calculated by multiplying the apparent viscosity times the shear rate. The shear rate should be the corrected shear rate per ...
  9. [9]
    [PDF] Chapter 7: Generalized Newtonian fluids
    Mar 21, 2018 · n = power-law index (n = 1 for Newtonian). © Faith A. Morrison ... EXAMPLE: Pressure-driven flow of a Power-Law. GNF between infinite ...
  10. [10]
    Quantifying Shear Thickening Behavior Using the Power-Law Model ...
    Conclusion. The corn starch-water mixture tested, exhibited strong shear-thickening behaviour above 8 s-1 as confirmed by the power law index ...
  11. [11]
    Effect of rheological models on the hemodynamics within human aorta
    The main advantage of the Carreau-type rheological models over the Casson-type models is that their behaviors are like a Newtonian fluid with the viscosity ...
  12. [12]
    Full article: Parameter determination for the Cross rheology equation ...
    The current study aims at facilitating a rheology model, i.e., the Cross rheology equation, into the WC-MPS model to capture the viscosity changes of the ...
  13. [13]
    Rheological Equations from Molecular Network Theories
    Transactions of The Society of Rheology 16, 99–127 (1972). https://doi.org/10.1122/1.549276 · The Society of Rheology Logo. Journal of Rheology.
  14. [14]
    Modeling flow of Carreau fluids in porous media | Phys. Rev. E
    Dec 11, 2023 · This work provides the missing components needed to predict Carreau GNF macroscale flow with only rheological information for the fluid and analysis of the ...Missing: original | Show results with:original
  15. [15]
    The relaxation of concentrated polymer solutions | Rheologica Acta
    The focus of this paper is on the viscoelastic properties of concentrated polymer solutions and polymer melts. Dynamic mechanical measurements were perform.
  16. [16]
    The Rheology of Blood Flow in a Branched Arterial System - PMC
    Aug 23, 2006 · The power law, Casson and Carreau models are popular non-Newtonian models and affect hemodynamics quantities under many conditions. In this ...
  17. [17]
    [PDF] On the application of simplified rheological models of fluid in ... - arXiv
    Jul 8, 2020 · In this way, the truncated power-law model can reproduce correctly the limiting behaviour of the Carreau or Cross fluid with the interim power- ...
  18. [18]
    https://arxiv.org/pdf/2007.04240
  19. [19]
    [PDF] Rheology: An Introduction - TA Instruments
    Apr 2, 2019 · 40-mm 2-degree is the most common cone geometry. This is often used to verify an instrument with a viscosity standard. ▫8-mm plates are often ...
  20. [20]
    [PDF] Practical Rheology Section 3 - Dynisco
    If the shear stress at a particular shear rate is known for a plastic melt, then the ratio shear stress/shear rate is called the apparent viscosity. The ...
  21. [21]
    Rabinowitsch Correction - NETZSCH Analyzing & Testing
    The Rabinowitsch (or Weissenberg-Rabinowitsch) correction is applied to get more accurate shear rate values from Non-Newtonian.
  22. [22]
    Comprehensive Rheometry Guide - BYK Instruments
    Couette viscometers are defined by the rotation of the measurement vessel while the body stays static. This method does not produce Taylor vortices but needs to ...Missing: apparent | Show results with:apparent
  23. [23]
    Core Rheometry: Yield Stress, Time-dependency, and Rheometry Tips
    It is important to note that for every non-Newtonian fluid, the corresponding flow curve should be unique to that fluid. This can only be achieved if all data ...
  24. [24]
    Quantification of shear viscosity and wall slip velocity of highly ...
    Jun 30, 2021 · Quantification of shear viscosity and wall slip velocity of highly concentrated suspensions with non-Newtonian matrices in pressure driven flows.
  25. [25]
    [PDF] A Basic Introduction to Rheology - NETZSCH Analyzing & Testing
    Three of the most common models for fitting flow curves are the Cross, Power-law and Sisko models. The most applicable model largely depends on the range of the.
  26. [26]
    [PDF] Determination of Nanomaterial Viscosity and Rheology Properties ...
    Apr 1, 2022 · Rheometers are operated in both controlled stress and controlled shear rate (which provides a more general capability for rheological evaluation.
  27. [27]
    Rheological experiments at constant stress as efficient method to ...
    May 1, 2014 · In creep and a subsequent recovery, the time scales can be extended into the stationary regime in the linear range of deformation, and therefore ...Missing: techniques apparent
  28. [28]
    [PDF] Understanding Rheology of Structured Fluids - TA Instruments
    Bingham Flow. Eugene Bingham, a colloid chemist, first coined the term. “Rheology.” He also showed that for many real fluids a critical level of stress must ...
  29. [29]
    A Review of the Rheological Consistency of Materials - MDPI
    Jun 28, 2024 · Creep is where the material strains while being held at constant stress, while relaxation is a decrease in stress as the material is held at ...<|control11|><|separator|>
  30. [30]
    Measuring and Modeling of Melt Viscosity for Drug Polymer Mixtures
    Feb 21, 2024 · The concept of shifting the viscosity to a master curve is used to determine the parameters of this equation. Initially, the viscosity curves ( ...<|control11|><|separator|>
  31. [31]
    [PDF] principles and applications of the cox-merz rule, rn-14 - TA Instruments
    The so-called Cox-Merz "rule" is empirical relationship which has been found to be of great use in rheology. It was observed by Cox and Merz [1] that for ...
  32. [32]
    A reexamination of the Cox–Merz rule through the lens of recovery ...
    Apr 1, 2024 · In this work, we revisit the Cox–Merz rule using recovery rheology, which decomposes the strain into recoverable and unrecoverable components.
  33. [33]
    A novel microfluidic viscometer for measuring viscosity of ultrasmall ...
    May 7, 2025 · We present a novel microfluidic viscometer platform capable of measuring the viscosity of ultra-small volumes (ie ∼10 μl) of Newtonian and non-Newtonian fluids.
  34. [34]
    Microfluidic Rheology: An Innovative Method for Viscosity ... - MDPI
    Based on its operation, the microfluidic rheometer is suitable for measuring biological samples, examining various liquid or even semisolid pharmaceutical forms ...
  35. [35]
    Micro-rheometry | NIST
    Polymer microfluidics: We developed a multi-sample capillary rheometer that is based on a traditional rheometer but uses approximately 1000 times less material.Missing: 2020s | Show results with:2020s
  36. [36]
    https://doi.org/10.3390/pharmaceutics17030353
  37. [37]
    https://onepetro.org/JPT/article-pdf/2243062/spe-12122-pa.pdf
  38. [38]
    https://www.tainstruments.com/rheology-of-paints-and-coatings-blog/
  39. [39]
    Blood Rheology: Key Parameters, Impact on Blood Flow, Role ... - NIH
    Blood viscosity is an important determinant of local flow characteristics, which exhibits shear thinning behavior: it decreases exponentially with increasing ...
  40. [40]
    Rheology of the microcirculation - PubMed - NIH
    Apparent viscosity declines with decreasing diameter (the Fahraeus-Lindqvist effect) and is minimal at diameters of about 5-7 micrometers due to the optimal ...
  41. [41]
    The Rheological Behavior of Human Blood—Comparison of Two ...
    Apr 11, 2016 · ・ aggregation of red blood cells at low shear rate, leading to high viscosity values. ・ deformation and orientation of the red cells at ...
  42. [42]
    Injectable solid hydrogel: mechanism of shear-thinning and ...
    The shear-thinning property enables the preformed, solid gel to be injected as a low viscosity, flowing material. Once injection shear is removed, restoration ...Missing: apparent | Show results with:apparent
  43. [43]
    Methods To Assess Shear-Thinning Hydrogels for Application As ...
    From rheology we know that the 7.5 wt % hydrogel has a higher viscosity and a higher storage and loss modulus than the 5 wt % hydrogel, both of which contribute ...
  44. [44]
    Injectable, shear-thinning, photocrosslinkable, and tissue-adhesive ...
    Jan 8, 2024 · The ability to reduce viscosity in high shear rate regions reduces pressure drops and markedly improves injectability. Both features have proven ...Missing: apparent | Show results with:apparent
  45. [45]
    The role of lubricin in the mechanical behavior of synovial fluid - PNAS
    Apr 10, 2007 · We conclude that lubricin provides synovial fluid with an ability to dissipate strain energy induced by mammalian locomotion.
  46. [46]
    Scale‐Dependent Rheology of Synovial Fluid Lubricating ...
    Dec 31, 2023 · Synovial fluid (SF) is the complex biofluid that facilitates the exceptional lubrication of articular cartilage in joints.
  47. [47]
    Viscosupplementation and Synovial Fluid Rheology: A Hidden Risk ...
    Mar 21, 2025 · Synovial fluid (SF) plays a critical role in joint lubrication, load distribution, and maintaining homeostasis within the synovial cavity.
  48. [48]
    Stanford scientists decipher the danger of gummy phlegm in severe ...
    Jun 22, 2022 · Their study was the first to analyze in depth the makeup, viscosity and immunological characteristics of sputum from the lungs of patients with ...Missing: flow 2020s<|control11|><|separator|>
  49. [49]
    Biochemical and Biophysical Characterization of Respiratory ...
    Aug 19, 2021 · We characterized the composition and rheological properties (ie resistance to flow) of respiratory secretions collected from intubated COVID-19 patients.Missing: 2020s | Show results with:2020s
  50. [50]
    Prevalence and Mechanisms of Mucus Accumulation in COVID-19 ...
    Multiple clinical studies have reported increased mucus production in severe COVID-19 lung disease, including 1) increased MUC1 and MUC5AC concentrations in ...Missing: flow 2020s