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Chaotic characteristics and mixing performance of pseudoplastic fluids in a stirred tank

  • Xiang Zhang , Wen Si , Chengzhi Zhao and Deyu Luan EMAIL logo
Published/Copyright: July 24, 2023
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Open Physics
From the journal Open Physics Volume 21 Issue 1

Abstract

The key for improving the mixing efficiency of pseudoplastic fluids is to enhance the chaotic degree in the flow field. The xanthan gum solution was used to study the chaotic characteristics and mixing performance in a stirred tank with the impeller of perturbed six-bent-bladed turbine. Based on the velocity time series collected by the experiment of particle image velocimetry (PIV), the distributions of the largest Lyapunov exponent (LLE) and Kolmogorov entropy (K entropy) of the system were obtained through the programming calculation using the software MATLAB (R2016a) for characterizing the chaotic degree. The mixing performance of the fluid was numerically investigated using the Computational Fluid Dynamics package, and the velocity distributions were compared with the results obtained by the experiment of PIV. The relevance between the chaotic degree and the mixing performance was clarified. Results showed that the numerical results of velocity distributions agreed well with the experimental data which validated the Computational Fluid Dynamics model established. When the speed reached 600 rpm, the LLE and K entropy climbed the maximal values at the same time, which meant the greatest degree of chaos, and the mixing energy per unit volume was minimal at that moment, which was corresponding to the highest mixing efficiency. As the speed increased further, the LLE and K entropy decreased instead, which meant the chaos reduction, and the corresponding mixing energy per unit volume increased with the low mixing efficiency.

Keywords: pseudoplastic fluid; chaotic characteristics; mixing efficiency; largest Lyapunov exponent; Kolmogorov entropy

Nomenclature

b

impeller blade width (m)

C

off-bottom clearance (m)

D

impeller diameter (m)

d

shaft diameter (mm)

H

fluid height (m)

K

consistency index (Pa s n )

K entropy

Kolmogorov entropy

K s

constant of Metzner–Otto

LLE

largest Lyapunov exponent

M

torque (N m)

m

embedding dimension

N

impeller speed (rpm)

n

rheological index

PIV

particle image velocimetry

P

average period

P V

mixing power per unit volume (W m−3)

R

radial distance (m)

Re

Reynolds number

T

inner diameter (m)

V

volume (m3)

W V

mixing energy per unit volume (J)

w

flat baffles width (m)

w t

mass concentration (%)

z

axial height (m)

6PBT

perturbed six-bent-bladed turbine

γ

shear rate (s−1)

η

apparent viscosity (kg m−1 s−1)

θ

impeller backswept angle (°)

ρ

fluid density (kg m−3)

τ

time delay

1 Introduction

Pseudoplastic fluids play an important role in many industrial mixing operations, such as petrochemical, polymer engineering, and biopharmaceutical engineering [1,2]. For such pseudoplastic fluids with the shear-thinning properties, usually there are viscosity changes in different regions of the stirred tank, which will lead to an unique flow field characteristics [3,4,5], resulting in lower heat or mass transfer efficiency. Therefore, it is important to improve the mixing efficiency in the mixing of pseudoplastic fluids [6,7,8]. The mixing efficiency is closely related to the structure of the flow field. It has been found that the main way of improving mixing efficiency is to induce the chaotic flow and enhance chaotic degree in a stirred vessel [9,10,11,12,13]. According to the chaos theory, the characteristic parameters of the strange attractor, acting as the chaotic signal in the system, are usually used to reveal and characterize the degree of chaos. It mainly includes two key parameters: the largest Lyapunov exponent (LLE) and Kolmogorov entropy (K entropy) [14,15,16]. For instance, Liu et al. [17,18] analyzed the chaotic mixing characteristics in a water stirred tank with the rigid-flexible combination impeller. They found that the LLE and K entropy of the flow field produced by the combination impeller were obviously higher than those by the rigid impeller, which resulted in the higher mixing efficiency. Li [19] studied the chaotic characteristics of the power load time series by calculating the distribution of the LLE and K entropy in the system. Kashif et al. [20,21] studied the chaotic systems with hidden attractor and self-excited attractor. The numerical schemes of chaotic models were presented using the Adams–Bashforth–Moulton method. The main purpose of the agitation is to improve the mixing efficiency, and mixing time is a key index to evaluate the mixing performance. So the measurement of the mixing time is crucial for evaluating the mixing efficiency [22,23]. From the literature review, it has been found that most studies mainly focused on the chaotic characteristics and mixing performance of the flow field in Newtonian fluids [24,25]. There are relatively few studies on the chaotic mixing performances of the pseudoplastic fluid with the complex rheological properties, especially the correlation between the degree of chaos and the mixing efficiency [26,27].

The impeller of perturbed six-bent-bladed turbine (6PBT) can generate the asymmetric flow field structure and induce the chaotic flow in stirred tank, which is especially suitable for improving the mixing efficiency of the pseudoplastic fluids [28,29]. In this work, the xanthan gum solution is used to study the chaotic characteristics and mixing performance in stirred tank with the 6PBT impeller. Based on the velocity time series measured by particle image velocimetry (PIV) experiment, the distributions of LLE and K entropy of the flow field at different speeds are calculated by programming using the software MATLAB (R2016a). The mixing time is numerically calculated to obtain the mixing rate and mixing efficiency at different speeds. As a result, the relevance between the chaotic degree of flow field and the mixing performance is clarified. The research results provide a theoretical basis for improving the mixing efficiency of the pseudoplastic fluid.

2 Experimental setup and procedure

The experimental setup is shown in Figure 1. The mixing vessel was a flat-bottomed cylindrical tank with an inner diameter (T) of 210 mm fitted with four equally spaced flat baffles. The 6PBT impeller with a blade thickness of 2 mm and backswept angle θ = 30° was mounted on a centrally positioned shaft of diameter d = 16 mm. P1, P2, and P3 were three speed detecting points, their distances from the axis were all 70 mm, and the off-bottom clearance was 150, 100, and 40 mm, respectively. P0 was the initial tracer point, its location was 70 and 50 mm from the axis and the top, respectively. Further details of the geometrical characteristics of the stirred tank are shown in Figure 2.

Figure 1 Schematic of the stirred experimental apparatus: (a) PIV measurement, (b) System apparatus: 1. stirred equipment, 2. Encoder, 3. laser transmitter, 4. Synchronizer, 5. Computer, and 6. CCD camera, and (c) stirred equipment.
Figure 1

Schematic of the stirred experimental apparatus: (a) PIV measurement, (b) System apparatus: 1. stirred equipment, 2. Encoder, 3. laser transmitter, 4. Synchronizer, 5. Computer, and 6. CCD camera, and (c) stirred equipment.

Figure 2 Configuration of stirred tank and location of monitoring points. (a) Positions of tracer feeding and detecting, H = T, b = w = T/10, D = T/2, C = T/3, (b) 6PBT impeller, and (c) schematic of 6PBT impeller.
Figure 2

Configuration of stirred tank and location of monitoring points. (a) Positions of tracer feeding and detecting, H = T, b = w = T/10, D = T/2, C = T/3, (b) 6PBT impeller, and (c) schematic of 6PBT impeller.

The PIV system (Dantec Dynamics A/S company, Denmark) was used to measure the velocity profiles within the stirred tank by determining trajectory of the tracer particles (from which the laser is reflected) with two CCD cameras. The accuracy of the measurement depends on the following behavior of the tracer particles, i.e., the particle density should be closer to the fluid density and the particle diameter should be as small as possible in the case of ensuring imaging [30]. So the polystyrene microspheres of diameter equal to 1–5 μm and density 998 kg m−3 (approximating to the test fluid density) were selected as tracer particles in PIV measurement owing to its good imaging visibility and the behavior of not losing particle pairs between two exposure times. The CCD camera exposure time was set to 1.8 ms through calculation according to the biggest linear velocity of the blade tip. The sampling frequency was all set on 10 Hz at different collection conditions. The laser sheet thickness was adjusted to 1 mm. The experiment was carried out with the deionized water at a speed of 60 rpm (the Reynolds number Re = ρND 2/μ = 10,972), corresponding to the turbulent flow. The structure and size of the stirred apparatus used in the experiment are exactly the same as that of the calculation model. The velocity distributions obtained by PIV experiment were compared with the computational results to verify the simulated model.

3 Calculation method

3.1 Mesh formation of stirred tank

Gambit (Fluent Inc.) was used to discretize the computational domain with a tetrahedral mesh. The increased mesh density was used in order to have a very refined mesh near the impeller. Grid independence was confirmed by demonstrating that additional grid cells did not change the calculated velocity magnitude and power number by more than 3% [31], so 1,004,727 cells were employed in this study, as shown in Figure 3.

Figure 3 Computational grids of the stirred system.
Figure 3

Computational grids of the stirred system.

3.2 Numerical model

In this work, the Xanthan gum solution in water at 0.5% mass concentration was employed, and the rheological parameters were measured under a temperature of 30℃ with DV3T rheometer, as shown in Table 1.

Table 1

Rheological parameters of xanthan gum solutions

w t (%) K (Pa s n ) n ρ (kg m−3)
0.5 0.32 0.63 998

The continuity equation is expressed as follows:

(1) ρ t + ( ρ u i ) x i = 0 ,

The momentum equation is expressed as follows:

(2) ( ρ u i ) t + ( ρ u i u j ) x j + p x i = μ u i x i + τ i j x j .

The viscosity of xanthan gum solution can be described by power law model in turbulent flow. Its apparent viscosity η is defined as follows:

(3) η = K ( γ ) n 1 .

The average shear rate can be related to the rotation speed of the impeller according to the Metzner–Otto’s correlation [32,33] as follows:

(4) γ = K s N .

The shear rate constant can be defined as follows [34]:

(5) K s = B 3 n + 1 4 n [ n / ( n 1 ) ] ,

(6) B = 9.5 + 9 × T d 2 T d 2 1 .

Then, the apparent viscosity η is described as follows:

(7) η = K 3 n + 1 4 n n B n 1 N n 1 .

The apparent Reynolds number is defined as follows:

(8) Re = ρ N D 2 η .

The model of Detached eddy simulation (DES) is employed to calculate the turbulent flow field for accurately capturing the flow characteristics [35,36,37]. The method of dynamic mesh was adapted in the velocity field calculation, which is well suitable for dealing with unsteady flow problems [38]. The solutions were considered converged when the normalized residuals for each transport equation were below 1 × 10−5. Computations were carried out using Dell workstation with 3.2 GHz processor and 32 GB RAM and convergence was achieved after 96 h. When the flow behavior index n and consistency coefficient K are set to 1.0 and 0.001 Pa s n , respectively, in power law model, this means that the flow of Newtonian fluid (deionized water) can be calculated using the power law model [31] in order to compare the computed data with PIV experimental results.

4 Validation of calculation method

A comparison of the velocity data distribution from the PIV experiment at different heights of the longitudinal section with the computed velocities using the model of DES at N = 60 rpm is shown in Figure 4. It can be seen that the computed data agreed well with the measured results and the DES calculations accurately picked up the features of the flow field, which validated the model of DES.

Figure 4 The velocity variations from radial direction at different high levels.
Figure 4

The velocity variations from radial direction at different high levels.

5 Results and discussion

5.1 Velocity time series

The xanthan gum solution in water at 0.5% mass fraction was used to carry out the numerical calculation of the flow field. The radial velocities of the three monitoring points were collected over 200 s record, respectively. Owing to limited space, the time series of radial velocity at P1 point are shown only in Figure 5. It can be found that the fluctuation range of the velocity increases with the rotational speed, which shows the enhanced turbulent characteristics.

Figure 5 The velocity time series at different speeds. (a) N = 300 rpm, (b) N = 500 rpm, (c) N = 600 rpm, and (d) N = 800 rpm.
Figure 5

The velocity time series at different speeds. (a) N = 300 rpm, (b) N = 500 rpm, (c) N = 600 rpm, and (d) N = 800 rpm.

5.2 Chaotic characteristics

The chaos theory points out that the characteristic parameters of strange attractor in the system, as the chaotic signal, can be used to distinguish chaos and characterize the degree of chaos. The LLE and K entropy are two key parameters for determining the chaotic degree of the mixing system. If the values of LLE and K entropy of the system are all positive numbers, it indicates that the system is in a definitely chaotic motion. The bigger the values of LLE and K entropy, the higher the chaotic degree of the system.

The embedding dimension m and time delay τ may be solved by the programming calculation using the software MATLAB (R2016a) based on the velocity time series of the detecting point. The calculation process is as follows:

The velocity time series should be divided into t different sub-sequences, each sub-sequence S ( m , r , t ) may be described as follows:

(9) S ( m , r , t ) = 1 t s = 1 t [ C s ( m , r , t ) C s m ( 1 , r , t ) ] ,

(10) Δ S ( m , t ) = max { S ( m , r j , t ) } min { S ( m , r j , t ) } ,

where r is the range radius of the time series, t is the time interval, and C is the relevant integral function of time series for reconstructing the phase space.

According to the study by Brock et al. [39], the following three sequences can be solved out by the programming calculation using the software MATLAB.

(11) S ¯ ( t ) = 1 16 m = 2 5 j = 1 4 S ( m , r j , t ) ,

(12) Δ S ¯ ( t ) = 1 4 m = 2 5 Δ S ( m , t ) ,

(13) S cor ( t ) = S ̅ ( t ) + | S ̅ ( t ) | ,

where S cor is the statistical variable used to calculate the time window τ w by the C–C method.

Taking N = 300 rpm as an example, the variations in Δ and S cor with t are shown in Figure 6. The C–C method is usually used to determine the width of the embedding window and the best time delay, and finally obtain the embedding dimension through the embedding window width. According to the C–C method, the corresponding t value at the position of the first minimum value in the curve graph is the time delay, i.e., τ = 17, and the corresponding t value at the position of the minimum value in the S cor curve graph is the time window, i.e., τ w = 91. So the embedding dimension m can be obtained according to τ w = (m − 1)τ, i.e., m = 6.

Figure 6 The variations in ΔS̅ and S cor curve with t by C–C method.
Figure 6

The variations in Δ and S cor curve with t by C–C method.

The maximum likelihood algorithm not only solves time delay τ and embedding dimension m, but also needs the average period P [35]. The velocity time series are conducted at different speeds through the fast FFT transform for acquisition of the average period P. The embedding dimension m, time delay, and average period P of the velocity time series at different speeds are shown in Table 2.

Table 2

Embedding dimension m, time delay τ, and average period P of velocity time series at different speeds

Speed N (rpm) Time delay τ Time window τ w Embedding dimension m Average period P
300 17 91 6 61
400 15 110 8 68
500 19 150 9 87
600 21 120 7 67
700 15 85 7 89
800 16 140 10 92

These data are reconstructed in the phase space according to the time series. At last, LLE and K entropy of the system can be solved out using the C–C method and maximum likelihood algorithm, respectively, as shown in Figure 7.

Figure 7 The distribution of LLE and K entropy of flow field at different speeds.
Figure 7

The distribution of LLE and K entropy of flow field at different speeds.

It can be seen that both the LLE and K entropy increase with the speed at the beginning. When the speed reaches 600 rpm, the LLE and K entropy of the system are at the maximum values simultaneously, corresponding to 0.61 and 0.94, respectively, which indicates that the chaotic degree of the flow field reaches the highest level. However, as the speed further increases, the LLE and K entropy decreases instead, which leads to the reduction in the chaotic degree. This is because the highly regular and repetitive coherent structures (such as cylindrical reflux, etc.) appear in the flow field.

5.3 Mixing performance

5.3.1 Mixing time

The numerical simulations of the mixing procession are conducted through detecting the tracer concentration (taking water as a tracer in this work). The mixing time can be obtained based on the 95% principle [40]. Taking N = 600 rpm as an example, the tracer concentration response curve at three monitoring points are shown in Figure 8.

Figure 8 Concentration response curve at different detecting points.
Figure 8

Concentration response curve at different detecting points.

It can be seen that the concentration response curve of tracer fluctuates greatly at the beginning. It rises sharply, then descents rapidly, and finally it tends to be a straight line which means the completion of the mixing process. The value at P3 point is adopted as the final mixing time i.e., t 95 = 1.48 s.

5.3.2 Mixing efficiency

The mixing efficiency is usually characterized by mixing energy per unit volume. The smaller the mixing energy per unit volume, the higher the mixing efficiency, its expression is as follows:

(14) W V = P V t 95 .

The expression of the stirring power per unit volume is as follows:

(15) P V = 2 π N M / V .

The torque values (M) of stirring shaft and impeller can be obtained by numerical simulation. The computational fluid dynamics results of power consumption and mixing energy per unit volume at different speeds are shown in Table 3.

Table 3

Calculation results of mixing power per unit volume and mixing energy per unit volume at different speeds

N (rpm) Mixing time (s) M (N m) P V (W m−3) W V (J)
300 4.89 0.0042 18.14 88.71
400 3.17 0.0046 26.52 84.07
500 1.99 0.0051 36.72 73.07
600 1.48 0.0056 48.37 71.59
700 1.32 0.0068 68.53 90.46
800 1.18 0.0079 90.99 107.37

It can be observed that the variation trend of mixing energy per unit volume is consistent with that of LLE and K entropy at different speeds. At the speed of N = 600 rpm, the mixing energy per unit volume is the smallest (W V = 71.59 J), at the time, corresponding to the maximum value of LLE and K entropy, which means the highest mixing efficiency and the greatest degree of chaos. At other speeds, the mixing efficiency will decline with the decrease in the chaotic degree. Therefore, the mixing efficiency is determined by the chaotic degree of the flow field, and the chaotic characteristics of the flow field are directly correlated with the mixing performance of the fluid.

6 Conclusion

In this work, the chaotic characteristics and mixing performance of pseudoplastic fluid in a stirred tank with 6PBT impeller are studied. The relevance between the chaotic degree and the mixing efficiency is analyzed. The conclusions are as follows:

  1. Both the LLE and K entropy increase with the increase in the speed at the beginning. When the speed increases to 600 rpm, the LLE and K entropy of the system are at the maximal value, corresponding to 0.61 and 0.94, respectively, which indicates the greatest degree of chaos at this time. As the speed increases further, both the LLE and K entropy tend to decline instead with the decreasing degree of chaos.

  2. The mixing rate is proportional to the speed, but the mixing efficiency has a maximal value at N = 600 rpm. As the speed increases further, the mixing efficiency will decrease instead.

  3. The variation in mixing efficiency is consistent with that of LLE and K entropy at different speeds. The highest mixing efficiency corresponds to the greatest degree of chaos. When the chaotic degree decreases, the mixing efficiency also declines correspondingly. Therefore, the chaotic degree of the flow field determines the mixing efficiency and there is a direct relevance between them.

Acknowledgments

The authors are grateful for the reviewers’ valuable comments that improved the manuscript.

  1. Funding information: This work was supported by National Natural Science Foundation of China (Grant No. 52176040).

  2. Author contributions: All authors have accepted responsibility for the entire content of this manuscript and approved its submission.

  3. Conflict of interest: The authors state no conflict of interest.

  4. Data availability statement: The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.

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Received: 2023-02-14
Revised: 2023-06-05
Accepted: 2023-06-09
Published Online: 2023-07-24

© 2023 the author(s), published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

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  107. Special Issue on Advanced Topics on the Modelling and Assessment of Complicated Physical Phenomena - Part III
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https://doi.org/10.1515/phys-2022-0268
Keywords for this article
pseudoplastic fluid; chaotic characteristics; mixing efficiency; largest Lyapunov exponent; Kolmogorov entropy
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  1. Regular Articles
  2. Dynamic properties of the attachment oscillator arising in the nanophysics
  3. Parametric simulation of stagnation point flow of motile microorganism hybrid nanofluid across a circular cylinder with sinusoidal radius
  4. Fractal-fractional advection–diffusion–reaction equations by Ritz approximation approach
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  6. Ammonia gas-sensing behavior of uniform nanostructured PPy film prepared by simple-straightforward in situ chemical vapor oxidation
  7. Analysis of the working mechanism and detection sensitivity of a flash detector
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  12. Study on the impulse mechanism of optical films formed by laser plasma shock waves
  13. Analysis of sweeping jet and film composite cooling using the decoupled model
  14. Research on the influence of trapezoidal magnetization of bonded magnetic ring on cogging torque
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  16. Compounded Bell-G class of statistical models with applications to COVID-19 and actuarial data
  17. Degradation of Vibrio cholerae from drinking water by the underwater capillary discharge
  18. Multiple Lie symmetry solutions for effects of viscous on magnetohydrodynamic flow and heat transfer in non-Newtonian thin film
  19. Thermal characterization of heat source (sink) on hybridized (Cu–Ag/EG) nanofluid flow via solid stretchable sheet
  20. Optimizing condition monitoring of ball bearings: An integrated approach using decision tree and extreme learning machine for effective decision-making
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  25. Significance of heat and mass transport in peristaltic flow of Jeffrey material subject to chemical reaction and radiation phenomenon through a tapered channel
  26. Complex dynamics of a sub-quadratic Lorenz-like system
  27. Stability control in a helicoidal spin–orbit-coupled open Bose–Bose mixture
  28. Research on WPD and DBSCAN-L-ISOMAP for circuit fault feature extraction
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  30. A modified power-law model: Properties, estimation, and applications
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  36. Vibration sensitivity minimization of an ultra-stable optical reference cavity based on orthogonal experimental design
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  40. Tangential electrostatic field at metal surfaces
  41. Bioconvective gyrotactic microorganisms in third-grade nanofluid flow over a Riga surface with stratification: An approach to entropy minimization
  42. Infrared spectroscopy for ageing assessment of insulating oils via dielectric loss factor and interfacial tension
  43. Influence of cationic surfactants on the growth of gypsum crystals
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  46. A novel compact highly sensitive non-invasive microwave antenna sensor for blood glucose monitoring
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  48. Conserved vectors and solutions of the two-dimensional potential KP equation
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  50. Optimal interatomic potentials using modified method of least squares: Optimal form of interatomic potentials
  51. The soliton solutions for stochastic Calogero–Bogoyavlenskii Schiff equation in plasma physics/fluid mechanics
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  53. Analysis of Cu and Zn contents in aluminum alloys by femtosecond laser-ablation spark-induced breakdown spectroscopy
  54. Nonsequential double ionization channels control of CO2 molecules with counter-rotating two-color circularly polarized laser field by laser wavelength
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  61. Numerical study of static pressure on the sonochemistry characteristics of the gas bubble under acoustic excitation
  62. Optimal auxiliary function method for analyzing nonlinear system of coupled Schrödinger–KdV equation with Caputo operator
  63. Analysis of magnetized micropolar fluid subjected to generalized heat-mass transfer theories
  64. Does the Mott problem extend to Geiger counters?
  65. Stability analysis, phase plane analysis, and isolated soliton solution to the LGH equation in mathematical physics
  66. Effects of Joule heating and reaction mechanisms on couple stress fluid flow with peristalsis in the presence of a porous material through an inclined channel
  67. Bayesian and E-Bayesian estimation based on constant-stress partially accelerated life testing for inverted Topp–Leone distribution
  68. Dynamical and physical characteristics of soliton solutions to the (2+1)-dimensional Konopelchenko–Dubrovsky system
  69. Study of fractional variable order COVID-19 environmental transformation model
  70. Sisko nanofluid flow through exponential stretching sheet with swimming of motile gyrotactic microorganisms: An application to nanoengineering
  71. Influence of the regularization scheme in the QCD phase diagram in the PNJL model
  72. Fixed-point theory and numerical analysis of an epidemic model with fractional calculus: Exploring dynamical behavior
  73. Computational analysis of reconstructing current and sag of three-phase overhead line based on the TMR sensor array
  74. Investigation of tripled sine-Gordon equation: Localized modes in multi-stacked long Josephson junctions
  75. High-sensitivity on-chip temperature sensor based on cascaded microring resonators
  76. Pathological study on uncertain numbers and proposed solutions for discrete fuzzy fractional order calculus
  77. Bifurcation, chaotic behavior, and traveling wave solution of stochastic coupled Konno–Oono equation with multiplicative noise in the Stratonovich sense
  78. Thermal radiation and heat generation on three-dimensional Casson fluid motion via porous stretching surface with variable thermal conductivity
  79. Numerical simulation and analysis of Airy's-type equation
  80. A homotopy perturbation method with Elzaki transformation for solving the fractional Biswas–Milovic model
  81. Heat transfer performance of magnetohydrodynamic multiphase nanofluid flow of Cu–Al2O3/H2O over a stretching cylinder
  82. ΛCDM and the principle of equivalence
  83. Axisymmetric stagnation-point flow of non-Newtonian nanomaterial and heat transport over a lubricated surface: Hybrid homotopy analysis method simulations
  84. HAM simulation for bioconvective magnetohydrodynamic flow of Walters-B fluid containing nanoparticles and microorganisms past a stretching sheet with velocity slip and convective conditions
  85. Coupled heat and mass transfer mathematical study for lubricated non-Newtonian nanomaterial conveying oblique stagnation point flow: A comparison of viscous and viscoelastic nanofluid model
  86. Power Topp–Leone exponential negative family of distributions with numerical illustrations to engineering and biological data
  87. Extracting solitary solutions of the nonlinear Kaup–Kupershmidt (KK) equation by analytical method
  88. A case study on the environmental and economic impact of photovoltaic systems in wastewater treatment plants
  89. Application of IoT network for marine wildlife surveillance
  90. Non-similar modeling and numerical simulations of microploar hybrid nanofluid adjacent to isothermal sphere
  91. Joint optimization of two-dimensional warranty period and maintenance strategy considering availability and cost constraints
  92. Numerical investigation of the flow characteristics involving dissipation and slip effects in a convectively nanofluid within a porous medium
  93. Spectral uncertainty analysis of grassland and its camouflage materials based on land-based hyperspectral images
  94. Application of low-altitude wind shear recognition algorithm and laser wind radar in aviation meteorological services
  95. Investigation of different structures of screw extruders on the flow in direct ink writing SiC slurry based on LBM
  96. Harmonic current suppression method of virtual DC motor based on fuzzy sliding mode
  97. Micropolar flow and heat transfer within a permeable channel using the successive linearization method
  98. Different lump k-soliton solutions to (2+1)-dimensional KdV system using Hirota binary Bell polynomials
  99. Investigation of nanomaterials in flow of non-Newtonian liquid toward a stretchable surface
  100. Weak beat frequency extraction method for photon Doppler signal with low signal-to-noise ratio
  101. Electrokinetic energy conversion of nanofluids in porous microtubes with Green’s function
  102. Examining the role of activation energy and convective boundary conditions in nanofluid behavior of Couette-Poiseuille flow
  103. Review Article
  104. Effects of stretching on phase transformation of PVDF and its copolymers: A review
  105. Special Issue on Transport phenomena and thermal analysis in micro/nano-scale structure surfaces - Part IV
  106. Prediction and monitoring model for farmland environmental system using soil sensor and neural network algorithm
  107. Special Issue on Advanced Topics on the Modelling and Assessment of Complicated Physical Phenomena - Part III
  108. Some standard and nonstandard finite difference schemes for a reaction–diffusion–chemotaxis model
  109. Special Issue on Advanced Energy Materials - Part II
  110. Rapid productivity prediction method for frac hits affected wells based on gas reservoir numerical simulation and probability method
  111. Special Issue on Novel Numerical and Analytical Techniques for Fractional Nonlinear Schrodinger Type - Part III
  112. Adomian decomposition method for solution of fourteenth order boundary value problems
  113. New soliton solutions of modified (3+1)-D Wazwaz–Benjamin–Bona–Mahony and (2+1)-D cubic Klein–Gordon equations using first integral method
  114. On traveling wave solutions to Manakov model with variable coefficients
  115. Rational approximation for solving Fredholm integro-differential equations by new algorithm
  116. Special Issue on Predicting pattern alterations in nature - Part I
  117. Modeling the monkeypox infection using the Mittag–Leffler kernel
  118. Spectral analysis of variable-order multi-terms fractional differential equations
  119. Special Issue on Nanomaterial utilization and structural optimization - Part I
  120. Heat treatment and tensile test of 3D-printed parts manufactured at different build orientations
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