Neural network modelling of adsorption isotherms

Morse, Graham E.; Jones, R. A.; Thibault, Jules; Tezel, F. Handan

doi:10.1007/s10450-010-9287-1

Cited by 37 publications

(13 citation statements)

References 20 publications

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“…As expected, the Levenberg-Marquardt algorithm combined with Bayesian regularization technique was able to avoid overfitting problems even for an excessive number of neurons. These results are in accordance with that presented by Morse et al (2011).…”

Section: Including the Effect Of Temperaturesupporting

confidence: 96%

“…A successful training can result in ANNs that can perform tasks such as predicting an output value, classifying an object, a function approaching, and recognizing a pattern in multivariate data (Dayhoff and DeLeo 2001). Morse et al (2011) indicated the use of neural networks for modeling adsorption isotherms due to the inherent complexities of adsorption process, in which the adsorbentadsorbate interaction may depend on several conditions like temperature, pH, compositions and/or the nature of adsorbent material. As confirmed by De Laurentiis and Ravdin (1994), ANNs are able to deal with these kinds of complex interactions, such as protein adsorption.…”

Section: Introductionmentioning

confidence: 99%

“…In the last years, artificial neural networks (ANN) proved to be an efficient alternative, since they are computational methodologies that perform multivariate analysis (Yetilmezsoy and Demirel 2008;Morse et al 2011;Ç elekli et al 2013;Dutta and Basu 2013). ANNs have been developed to mimic, mathematically, networks of biological neurons.…”

Section: Introductionmentioning

confidence: 99%

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Prediction of the isotherms of human IgG adsorption on Ni(II)-IDA-PEVA membrane using artificial neural networks

Schmitz

Bresolin

2014

Adsorption

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The use of artificial neural networks (ANNs) to predict the adsorption isotherms of human immunoglobulin G on immobilized Ni(II) affinity hollow fiber membranes was studied. Neural networks were trained using the Levenberg-Marquardt algorithm combined with Bayesian regularization technique and experimental data from different temperatures. The resulting neural network demonstrated to be able to interpolate the behavior of the maximum adsorption capacity and equilibrium concentration in the temperature range (4, 37°C) with correlation coefficients higher than 0.96. Results demonstrated to be very similar to those achieved with traditionally Langmuir model adjustment. The advantage of interpolation ability of ANNs was also showed.

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Section: Including the Effect Of Temperaturesupporting

confidence: 96%

Section: Introductionmentioning

confidence: 99%

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Prediction of the isotherms of human IgG adsorption on Ni(II)-IDA-PEVA membrane using artificial neural networks

Schmitz

Bresolin

2014

Adsorption

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“…Alireza Rahnama et al used the open dataset to train different machine learning models to predict the hydrogen weight percent and classify metal hydrides . By setting different adsorption isotherm (Langmuir, Freundlich, Sips, Toth, and TD Toth) models parameters, Morse et al trained the neural network model by generating data from the adsorption isotherm model formulas . By using Latin hypercube sampling (LHS) with a genetic algorithm to generate data, Anna et al used a multi‐objective optimization to optimize N 2 purity and recovery by an artificial neural network (ANN)…”

Section: Introductionmentioning

confidence: 99%

Machine learning–based optimization for hydrogen purification performance of layered bed pressure swing adsorption

Xiao

Fang

et al. 2020

Int J Energy Res

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Summary An adsorption, heat and mass transfer model for the five‐component gas from coal gas (H2/CO2/CH4/CO/N2 = 38/50/1/1/10 vol%) in a layered bed packed with activated carbon and zeolite was established by Aspen Adsorption software. Compared with published experimental results, the hydrogen purification performance by pressure swing adsorption (PSA) in a layered bed was numerically studied. The results show that there is a contradiction between the hydrogen purity and recovery, so the multi‐objective optimization algorithms are needed to optimize the PSA process. Machine learning methods can be used for data analysis and prediction; the polynomial regression (PNR) and artificial neural network (ANN) were used to predict the purification performance of two‐bed six‐step process. Finally, two ANN models combined with sequence quadratic program (SQP) algorithm were used to achieve multi‐objective optimization of hydrogen purification performance. According to the analysis of the optimization results, the ANN models are more suitable for optimizing the purification performance of hydrogen than the PNR model.

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“…The standard and empirical models cannot adjust for compositional varietal differences, as modeling methods are based only on physical parameters. This shortcoming can be overcome by general class nonlinear models of artificial neural network (ANN) (Morse, Jones, Thibault, & Tezel, ; Myhara & Sablani, ). These heuristic models are recognized as good tools for dynamic modeling and are a useful tool for nonparametric regression.…”

Section: Introductionmentioning

confidence: 99%

Sorption isotherms of ready‐to‐puff preconditioned brown rice: Development of classical models and artificial neural network approach

Mahanti

Chakraborty

Babu

2019

J Food Process Engineering

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Moisture sorption isotherm data of ready‐to‐puff preconditioned brown rice shall enable in finding solutions for prolonging the period between preconditioning and puffing. Designed full factorial experiments were conducted with ready‐to‐puff preconditioned brown rice at five different salt concentrations (SC) ranging 0–4%, varying temperature (T), 20–30°C within eight levels of moisture content (MC), and 3–25% to obtain sorption isotherms. Preconditioning was carried out at 75(±3)°C using a fluidized bed dryer to attain a final MC of 11%, optimum for puffing. Water activity (aw) of the sample increased with increasing T and decreased with increasing SC. The individual and interaction effects of T, SC, and MC on aw are highly significant (p < .001). The experimental sorption data at each SC were fitted with the traditional model at a given temperature. All the models were statistically (p < .001) significant. A feedforward artificial neural network model was developed with three input variables T, SC, and MC as the input layer and aw as the output layer. Inter‐relationship among the process variables is explained better by artificial neural network (R2 = 0.991) and second‐order model (R2 = 0.973) as compared with traditional models, which are limited in their ability to express the relationship among the variables. Practical Applications The key to quality puffed rice is the preconditioning process during its manufacture. During preconditioning, salts and moisture penetrate the rice matrix to give a desirable product. The preconditioned rice should be immediately processed, else absorption or desorption of moisture from the atmospheric air takes place. This leads to finished puffed rice with compromised quality. Liberty of using the preconditioned rice for further processing will wrest upon the processor if suitable packaging is provided to this rice. Extensive knowledge of moisture sorption isotherms is required for designing such packaging material and conditions. The present study is carried out to study the sorption isotherm of ready‐to‐puff preconditioned brown rice. The information available in the present study is useful for food industries to develop a suitable packaging material for time‐independent use of preconditioned rice.

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Neural network modelling of adsorption isotherms

Cited by 37 publications

References 20 publications

Prediction of the isotherms of human IgG adsorption on Ni(II)-IDA-PEVA membrane using artificial neural networks

Prediction of the isotherms of human IgG adsorption on Ni(II)-IDA-PEVA membrane using artificial neural networks

Machine learning–based optimization for hydrogen purification performance of layered bed pressure swing adsorption

Sorption isotherms of ready‐to‐puff preconditioned brown rice: Development of classical models and artificial neural network approach

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