Magnetic characterisation of longitudinal thin film media

Dova, Paraskevi

January 1998

No description available.

530.41

Effect of Equal Channel Angular Extrusion on the Microstructure Evolution and Mechanical Properties of Al-15wt%Zn Alloy

Huang, Yi-Chia

01 August 2011

The deformation mechanism of an ultrafine grained (UFG) Al-Zn alloy has been studied. In this work, Al-15wt%Zn alloy was processed by equal channel angular extrusion (ECAE) route A at 100oC to achieve UFG structure. The deformation mechanism was studied by performing tensile test with various strain rates. Scanning electron microscopy and transmission electron microscopy were used to investigate the microstructure evolution in Al-15wt%Zn alloy with increasing ECAE passes. The observation indicated that the super saturated Al-Zn alloy would decompose and precipitate Zn particles during ECAE process. Increasing ECAE passes, the aluminum grain size was reduced, but the size of Zn particles was increased. However, the net effect of increasing ECAE passes is softening of this Al-Zn alloy. The tensile properties of the UFG Al-Zn alloy can be summarized as follows. (1)The UFG Al-Zn alloy possesses higher tensile strength and elongation as compared to commercial purity Al (AA1050). (2)The strain rate sensitivity of the UFG Al-Zn alloy increases significantly with increasing number of ECAE pass, which might be related to the refined aluminum grain size. After processed by 4-16 ECAE passes, the activation volume of the UFG Al-Zn alloy falls in the range of 25 b3~40 b3, which remains nearly constant value with increasing tensile strain. It is suggested that the controlling mechanism responsible for the tensile deformation of the UFG Al-Zn alloy might be related to a grain boundary mediated mechanism. (3)With increasing ECAE passes, the total tensile elongation of the UFG Al-Zn alloy increases but the uniform elongation show little change. This indicates that the increase in total elongation is mainly due to the contribution from an enhanced post-uniform elongation (PUE). It is suggested that the enhanced PUE might be related to the increase in strain rate sensitivity, which is resulted from the refinement of grain size. More detailed studies are needed to understand the deformation mechanism.

microstructure

strain rate sensitivity

activation volume

post-uniform elongation

equal channel angular extrusion

Al-Zn alloy

Effet de la composition et de la technique d'élaboration sur le comportement mécanique des verres metalliques base zirconium / Effect of composition and technique of production, on the mechanical behaviour of based-zirconium metallic glasses

Nowak, Sophie

02 November 2009

Les verres métalliques sont des matériaux récents (≈ 50 ans), obtenus par refroidissement rapide d'un alliage en fusion. La structure amorphe de ces matériaux leur confère des propriétés particulières : une très grande résistance mécanique (limite à la rupture de l'ordre de 1,7 GPa pour des alliages base Zr), une déformation élastique de l'ordre de 2% mais pas ou peu de ductilité. Les compositions pouvant être élaborées à l’état amorphe, et, sous forme massive, sont en nombre limité. Le travail présenté dans ce manuscrit démontre la possibilité de consolider par frittage SPS (Spark Plasma Sintering), des poudres amorphes obtenues par atomisation (Фmoy.≈70 μm), tout en conservant majoritairement le caractère amorphe. L’optimisation de ce protocole, avec la composition Zr57Cu20Al10Ni8Ti5, a permis de retrouver le même comportement mécanique qu’un verre massif monolithe. Une cristallisation partielle du matériau se produit cependant aux points de contact des particules, mais pourrait être réduite en poursuivant le modèle de frittage esquissé dans ce manuscrit. Aux vues de ces résultats, la conception de nouvelles compositions, et leur élaboration sous forme de rubans, ont été menées. La caractérisation par nano-indentation permet d’estimer de manière fiable les propriétés mécaniques de ces alliages. Enfin, une nouvelle méthode d’évaluation du volume d’activation, qui est le volume élémentaire cisaillé initiant la déformation plastique, est présentée. Il s’agit de l’analyse statistique d’essais de pseudo-fluage en nano-indentation, réalisés à température ambiante. En conclusion, ce travail propose de nouvelles perspectives d’élaboration de verre métalliques sous forme massive dans une gamme de composition bien plus large / The metallic glasses are relatively new materials (≈ 50 years), produced by quenching a molten alloy. The amorphous structure of these materials gives them unique properties: very high strength (fracture stress is about 1.7 GPa for Zr based alloys), an elastic deformation reaching 2%, but little or no ductility. The compositions, which could produce both amorphous and bulk samples, are limited. The work, detailed in this manuscript, shows the possibility of sintering using SPS (Spark Plasma Sintering) amorphous powders obtained by atomization (Фaverage ≈ 70 microns). The result is a fully densified and near fully amorphous sample. The optimization of this technique, with the composition Zr57Cu20Al10Ni8Ti5, gave samples for which mechanical behaviour is close to the bulk metallic glass behaviour. However, partial crystallization of the material occurs, localized at the contact points of particles, but could be reduced by deepening the sintering model outlined in this manuscript. In view of these results, new compositions are designed, and the production of ribbons was conducted. The characterization by nano-indentation estimates reliably the mechanical properties of these alloys. Finally, a new method, evaluating the activation volume, which is the elementary volume initiating plastic deformation, is presented. This technique is a statistical analysis of pseudo-creep tests performed by nano-indentation, at room temperature. In conclusion, this work opens new perspectives to develop bulk samples in broad range of compositions

Métal amorphe

Frittage SPS

Nano-indentation

Volume d’activation

Amorphous metal

SPS sintering

Nano-indentation

Activation volume

Effect of Equal Channel Angular Extrusion on the Microstructure Evolution and Mechanical Properties of Al-5wt%Zn Alloy

Liao, Hung-Ya

19 July 2012

In this work, ultrafine-grained (UFG) Al-5wt%Zn alloy was produced by equal channel angular extrusion (ECAE). The microstructure evolution during ECAE and the mechanical properties of the UFG Al-Zn alloy were investigated. In order to identify the effect of Zn in the Al-Zn alloy, pure aluminum (4N, 99.99%) was also studied for comparison. The grains of the Al-Zn alloy could be refined effectively by increasing the ECAE passes. However, as the ECAE passes increased, the microhardness increased initially but maintained constant after 4 ECAE passes. The dislocation density within grain interior was decreased gradually with increasing ECAE passes. After being processed to twelve ECAE passes, the UFG Al-Zn alloy exhibited 53.7% of the grain boundaries being high angle grain boundaries (HAGBs). The UFG Al-5wt%Zn alloy exhibits superior tensile strength and elongation as compared with pure aluminum fabricated by the same ECAE process. Experimental results indicated that adding Zn in aluminum alloy could provide solid-solution strengthening and considerable enhancement in tensile ductility which might be related to an improved post-uniform elongation (PUE). The strain rate sensitivity (SRS) of the UFG Al-Zn alloy also increased with increasing the ECAE passes, which might be related to the fine grain size and the contribution of grain boundary sliding. The activation volume of the UFG Al-Zn alloy was in the range of 32b3~76b3, and the pure aluminum was in the range of 57b3~122b3. Because of the small value of the activation volume, it is suggested that the controlling mechanism for dislocation glide in the UFG Al-Zn alloy might be related to the generation and absorption of dislocations in grain boundary, as well as the interaction between dislocations and solute Zn atoms in the grain boundary.

strain rate sensitivity

grain boundary sliding

activation volume

high angle grain boundaries

post-uniform elongation

equal channel angular extrusion

Al-Zn alloy

Stability of microbial transglutaminase and its reactions with individual caseins under atmospheric and high pressure / Stabilität der mikrobiellen Transglutaminase und ihre Reaktionen mit Caseinen unter atmosphärischem Druck und unter Hochdruck

Menéndez Aguirre, Orquídea de María Pastora

03 November 2006

Kinetic inactivation of factor XIIIa and MTG were performed in a pressure range from 0.1 to 400 MPa at 40°C within a time from 0 to 60 min in a TRIS-acetate buffer at pH 6.0. The inactivation of both enzymes at these conditions followed a first order reaction model. The high inactivation rate constant of 26.6 x10-3/min-1 for factor XIIIa at low pressure (50 MP) indicated that this enzyme is much easier to inactivate than MTG, which achieved an inactivation rate constant value of 9.7 x10-3/min at higher pressure (200 MPa). An inactivation volume of –10.17±0.5 cm3/mol confirmed that MTG is very stable under high pressure. The stability of MTG under high pressure and thermal treatment was related to its conformational changes. Enzyme inactivation was accompanied by secondary and tertiary structure changes until an irreversible protein precipitation is achieved. The tertiary structure, represented by circular dichroism spectra in the aromatic region showed differences among native and MTG samples treated under high pressure, as well as at elevated temperature. Tyrosine bands, indicating protein unfolding, increased proportionally with increasing pressure treatment above 400 MPa. Nevertheless, compared to pressure, a maximal enhancement could be observed after thermal treatment at 0.1 MPa at 80°C. That demonstrated the exposure of hydrophobic groups to the protein surface with a concomitant protein unfolding. The spectra in the far ultraviolet region showed that increasing high pressure and high temperature lead to alterations in the secondary structure. The mathematical algorithms CONTIN used to calculate secondary structures stated that the 24.5% of alpha-helix of native MTG decreased to 17.2% after a treatment at 400 MPa at 40°C for 60 min and to 6.5% after a treatment at 0.1 MPa at 80°C for 2 min. However, beta-strand structures remained relatively stable after these several treatments. MTG is arranged in a way that the active site is located between beta-strand domains that are surrounded by alpha-helices, the results of this investigation suggested that MTG activity is related with the relative stability of alpha-helix and the outstanding stability of the central beta-strand structure. The irreversible precipitated protein observed at 600 MPa at 40°C for 60 min and 0.1 MPa at 80°C for 2 min was caused principally by the formation of disulfides bonds, because high pressure and high thermal treatment lead to the exposition of the Cys64 residue towards the solvent with the subsequent ability to react with neighbouring cysteine residues. Furthermore, the reaction between protein and reducing sugars resulted in the formation of Maillard products. Furosine, as an indicator of the early stages of Maillard reaction was measured. Concentration values of 261.0 mg/g protein from samples treated at 600 MPa and 40°C and 238.5 mg/g protein from samples treated at and 0.1 MPa and 80°C for 2 min were obtained. Pentosidine a subsequent product observed in the advanced Maillard reaction was also present. Concentrations of 13.7 and 6.7 mg/g protein were obtained in the samples treated at 600 MPa and 40°C for 60 min and 0.1 MPa and 80°C for 2 min, respectively. Kinetic inactivation studies of MTG in a pressure range from 0.1 to 600 MPa at 10, 30, 40, and 50°C within a long time range from 0 to 140 h were performed in order to study MTG stability under the simultaneous effect of pressure and temperature. The inactivation kinetic showed a first and very fast step and a second very slow step suggesting irreversible inactivation behaviour. Activation energy and entropy difference decreased with increasing pressure. Thereby, the inactivation rate constants of enzyme were less temperature dependent at high pressure. The effect of pressure and temperature on MTG inactivation had a synergistic behaviour. At temperatures of 10, 30, and 40°C, increasing pressure leads to increasing inactivation rate constants. However at 50°C a tendency change occurred. Negative activation volumes of –16.2±0.5, -13.6±0.1, -11.2±0.3 cm3/mol were obtained for 10, 30 and 40°C respectively and for treatment at 50°C a positive value of about +3.0±2.0 cm3/mol in a pressure range from 0.1 to 300 and a negative volume of –11.0±0.4 cm3/mol MPa from 300 to 600 MPa were calculated. A pressure/temperature diagram from inactivation rate constants was performed to represent MTG stability. The diagram shows that in a pressure and temperature range from 0.1 to 550 MPa and 10 to 40°C, pressure induces MTG stabilization against heat denaturation. At 50°C in range from 0.1 to 300 MPa, pressure induces also enzyme stabilization again heat denaturation, but at the same temperature and above 300 MPa the enzyme was inactivated. After MTG stability analysis, reaction kinetics from MTG with individual caseins in a TRIS-acetate buffer pH 6.0 were performed under atmospheric pressure (0.1 MPa) and high pressure (400 MPa) at 40°C. The reaction was monitored by gel permeation chromatography under in three assumptions: 1) The initial velocity kinetics was obtained from a non-progressive enzymatic reactions with the products. 2) The substrate concentration exceeded enzyme concentration. 3) The sum of the individual catalytic constants of the reactive glutamine residues inside caseins are represented by a single MTG-monomeric casein complex. Enzyme reaction kinetics of MTG with the individual caseins carried out at 0.1 MPa at 40°C showed Michaelis-Menten-Henri behaviour with maximal velocities of 2.7 x 10-3, 0.8 x 10-3, and 1.3 x 10-3 mmol/L∙min and Km values of 59 x 10-3, 64 x 10-3 and 50 x 10-3 mmol/L of beta-, alpha-s1-, and whole-casein, respectively. This suggested that MTG achieved a maximal velocity with ß-casein, but had the best affinity with acid casein followed by beta- casein and finally alpha-s1-casein. Enzyme reaction kinetics of beta-casein carried out at 400 MPa and 40°C also showed a Michaelis-Menten-Henri behaviour with a similar maximal velocity of 2.6 x 10-3 mmol/L×min, but the Km value of 144 x 10-3 mmol/L showing kinetical similarity to a non-competitive inhibition. The reaction of MTG with alpha-s1-casein under high pressure did not fit in to Henri-Michaelis-Menten kinetics. Kinetic parameters showed that the affinity of MTG to beta- and alpha-s1-casein under atmospheric pressure is higher than the affinity of MTG to these caseins under high pressure. This loss of affinity can be explained by a constant number of reactive glutamine residues of casein, although the protein is unfolding at high pressure, a decrease of enzyme activity of MTG to 74% after treatment at 400 MPa at 40°C for 15 min and self association of casein under thermal and high pressure treatment. Fur technological application, the formation of acid milk gels was studied under the influence of MTG within its range of pH stability. Simultaneous addition of MTG and different concentrations of glucono-delta-lactone (Gdl) to casein solutions (5% w/v) at 40°C was analysed. Gels firmness was accessed by oscillation rheometry and gel permeation chromatography. Oscillation rheometry data showed that the time of gelation decreased with an increasing Gdl concentration added to the system, however higher concentrations of Gdl caused the formation of weaker gels. Addition of 1 g Gdl/g protein without MTG caused gelation within 5 min and a storage module value G´ of 48.9 Pa. With the simultaneous addition of 1 g Gdl/g protein and 6 U MTG/ g protein the gelation time was 4 min and the reached storage modulus was 63.7 Pa. However, the addition of 0.21 g Gdl/g protein and 6 U/g protein MTG increase the gelation time to about 69 min, but, a higher module value G´ of 111.0 Pa was achieved. Addition of high Gdl concentration caused a rapid drop of pH below 5 leading to a fast enzyme inactivation. However addition of very low Gdl concentrations was also not optimal. The simultaneous influence of MTG and Gdl concentration on the gelation time and elastic properties was evaluated by a central composite rotatable design (CCRD). The resulting quadratic storage modulus model showed that, MTG concentration had a significant influence on storage modulus G´ and, that the firmness of the gels increase in direct proportion with MTG activity with the existence of a optimum Gdl concentration, whereas the resulting linear model of the gelation time stated that Gdl concentration has a significant influence on the gelation time, while it is independent of the MTG activity. A maximal firmness of 136 ± 2 Pa was reached between a range of 0.24 - 0.27 g Gdl/g protein and 5.8 U MTG/g within a time from 49 to 59 min. Gel permeation chromatography analysis demonstrated that acid gels induced by Gdl were formed by reversible cross-linking like electrostatic interactions and hydrogen bonds as well as disulfide bonds caused by temperature treatment. Whereas, the addition of MTG proved the formation of non-reversible cross-linking like oligomers based on Ne-(g-glutamyl)- lysine, which gave more firmness and stabilization on the casein gel network.

Microbial transglutaminase

MTG

High pressure

Activation volume

pressure/temperature Diagram

Casein

Acid gel

Glucano-delta-lactona (Gdl)

mikobielle Transglutaminase

MTG

Hochdruck

Aktivierungsvolumen

Druck/Temperatur Diagramm

Casein

Säuregel

glucono-delta-lacton (Gdl)

ddc:540

rvk:WD 5050

MTG-Verfahren

Hochdruck

Aktivierungsvolumen

Casein

Relaxationen in komplexen Fluiden / Relaxations of complex fluids

Schwabe, Moritz

02 November 2010

No description available.

530 Physik

Physics

Metallisches Glas

Relaxationsprozesse

Glasübergangstemperatur

potentielle Energielandschaft

Spannungsabhängigkeit

Aktivierungsvolumen

Block-Copolymere

Chemical Confinement

Wasserstoffbrücken

metallic glass

relaxation processes

glass transition temperature

potential energy landscape

stress dependence

activation volume

block-copolymers

chemical confinement

hydrogen bonds

33.66 Amorpher Zustand

Gläser

RVI 000 Nichtkristalline Festkörper

Stability of microbial transglutaminase and its reactions with individual caseins under atmospheric and high pressure

Menéndez Aguirre, Orquídea de María Pastora

14 September 2006

Kinetic inactivation of factor XIIIa and MTG were performed in a pressure range from 0.1 to 400 MPa at 40°C within a time from 0 to 60 min in a TRIS-acetate buffer at pH 6.0. The inactivation of both enzymes at these conditions followed a first order reaction model. The high inactivation rate constant of 26.6 x10-3/min-1 for factor XIIIa at low pressure (50 MP) indicated that this enzyme is much easier to inactivate than MTG, which achieved an inactivation rate constant value of 9.7 x10-3/min at higher pressure (200 MPa). An inactivation volume of –10.17±0.5 cm3/mol confirmed that MTG is very stable under high pressure. The stability of MTG under high pressure and thermal treatment was related to its conformational changes. Enzyme inactivation was accompanied by secondary and tertiary structure changes until an irreversible protein precipitation is achieved. The tertiary structure, represented by circular dichroism spectra in the aromatic region showed differences among native and MTG samples treated under high pressure, as well as at elevated temperature. Tyrosine bands, indicating protein unfolding, increased proportionally with increasing pressure treatment above 400 MPa. Nevertheless, compared to pressure, a maximal enhancement could be observed after thermal treatment at 0.1 MPa at 80°C. That demonstrated the exposure of hydrophobic groups to the protein surface with a concomitant protein unfolding. The spectra in the far ultraviolet region showed that increasing high pressure and high temperature lead to alterations in the secondary structure. The mathematical algorithms CONTIN used to calculate secondary structures stated that the 24.5% of alpha-helix of native MTG decreased to 17.2% after a treatment at 400 MPa at 40°C for 60 min and to 6.5% after a treatment at 0.1 MPa at 80°C for 2 min. However, beta-strand structures remained relatively stable after these several treatments. MTG is arranged in a way that the active site is located between beta-strand domains that are surrounded by alpha-helices, the results of this investigation suggested that MTG activity is related with the relative stability of alpha-helix and the outstanding stability of the central beta-strand structure. The irreversible precipitated protein observed at 600 MPa at 40°C for 60 min and 0.1 MPa at 80°C for 2 min was caused principally by the formation of disulfides bonds, because high pressure and high thermal treatment lead to the exposition of the Cys64 residue towards the solvent with the subsequent ability to react with neighbouring cysteine residues. Furthermore, the reaction between protein and reducing sugars resulted in the formation of Maillard products. Furosine, as an indicator of the early stages of Maillard reaction was measured. Concentration values of 261.0 mg/g protein from samples treated at 600 MPa and 40°C and 238.5 mg/g protein from samples treated at and 0.1 MPa and 80°C for 2 min were obtained. Pentosidine a subsequent product observed in the advanced Maillard reaction was also present. Concentrations of 13.7 and 6.7 mg/g protein were obtained in the samples treated at 600 MPa and 40°C for 60 min and 0.1 MPa and 80°C for 2 min, respectively. Kinetic inactivation studies of MTG in a pressure range from 0.1 to 600 MPa at 10, 30, 40, and 50°C within a long time range from 0 to 140 h were performed in order to study MTG stability under the simultaneous effect of pressure and temperature. The inactivation kinetic showed a first and very fast step and a second very slow step suggesting irreversible inactivation behaviour. Activation energy and entropy difference decreased with increasing pressure. Thereby, the inactivation rate constants of enzyme were less temperature dependent at high pressure. The effect of pressure and temperature on MTG inactivation had a synergistic behaviour. At temperatures of 10, 30, and 40°C, increasing pressure leads to increasing inactivation rate constants. However at 50°C a tendency change occurred. Negative activation volumes of –16.2±0.5, -13.6±0.1, -11.2±0.3 cm3/mol were obtained for 10, 30 and 40°C respectively and for treatment at 50°C a positive value of about +3.0±2.0 cm3/mol in a pressure range from 0.1 to 300 and a negative volume of –11.0±0.4 cm3/mol MPa from 300 to 600 MPa were calculated. A pressure/temperature diagram from inactivation rate constants was performed to represent MTG stability. The diagram shows that in a pressure and temperature range from 0.1 to 550 MPa and 10 to 40°C, pressure induces MTG stabilization against heat denaturation. At 50°C in range from 0.1 to 300 MPa, pressure induces also enzyme stabilization again heat denaturation, but at the same temperature and above 300 MPa the enzyme was inactivated. After MTG stability analysis, reaction kinetics from MTG with individual caseins in a TRIS-acetate buffer pH 6.0 were performed under atmospheric pressure (0.1 MPa) and high pressure (400 MPa) at 40°C. The reaction was monitored by gel permeation chromatography under in three assumptions: 1) The initial velocity kinetics was obtained from a non-progressive enzymatic reactions with the products. 2) The substrate concentration exceeded enzyme concentration. 3) The sum of the individual catalytic constants of the reactive glutamine residues inside caseins are represented by a single MTG-monomeric casein complex. Enzyme reaction kinetics of MTG with the individual caseins carried out at 0.1 MPa at 40°C showed Michaelis-Menten-Henri behaviour with maximal velocities of 2.7 x 10-3, 0.8 x 10-3, and 1.3 x 10-3 mmol/L∙min and Km values of 59 x 10-3, 64 x 10-3 and 50 x 10-3 mmol/L of beta-, alpha-s1-, and whole-casein, respectively. This suggested that MTG achieved a maximal velocity with ß-casein, but had the best affinity with acid casein followed by beta- casein and finally alpha-s1-casein. Enzyme reaction kinetics of beta-casein carried out at 400 MPa and 40°C also showed a Michaelis-Menten-Henri behaviour with a similar maximal velocity of 2.6 x 10-3 mmol/L×min, but the Km value of 144 x 10-3 mmol/L showing kinetical similarity to a non-competitive inhibition. The reaction of MTG with alpha-s1-casein under high pressure did not fit in to Henri-Michaelis-Menten kinetics. Kinetic parameters showed that the affinity of MTG to beta- and alpha-s1-casein under atmospheric pressure is higher than the affinity of MTG to these caseins under high pressure. This loss of affinity can be explained by a constant number of reactive glutamine residues of casein, although the protein is unfolding at high pressure, a decrease of enzyme activity of MTG to 74% after treatment at 400 MPa at 40°C for 15 min and self association of casein under thermal and high pressure treatment. Fur technological application, the formation of acid milk gels was studied under the influence of MTG within its range of pH stability. Simultaneous addition of MTG and different concentrations of glucono-delta-lactone (Gdl) to casein solutions (5% w/v) at 40°C was analysed. Gels firmness was accessed by oscillation rheometry and gel permeation chromatography. Oscillation rheometry data showed that the time of gelation decreased with an increasing Gdl concentration added to the system, however higher concentrations of Gdl caused the formation of weaker gels. Addition of 1 g Gdl/g protein without MTG caused gelation within 5 min and a storage module value G´ of 48.9 Pa. With the simultaneous addition of 1 g Gdl/g protein and 6 U MTG/ g protein the gelation time was 4 min and the reached storage modulus was 63.7 Pa. However, the addition of 0.21 g Gdl/g protein and 6 U/g protein MTG increase the gelation time to about 69 min, but, a higher module value G´ of 111.0 Pa was achieved. Addition of high Gdl concentration caused a rapid drop of pH below 5 leading to a fast enzyme inactivation. However addition of very low Gdl concentrations was also not optimal. The simultaneous influence of MTG and Gdl concentration on the gelation time and elastic properties was evaluated by a central composite rotatable design (CCRD). The resulting quadratic storage modulus model showed that, MTG concentration had a significant influence on storage modulus G´ and, that the firmness of the gels increase in direct proportion with MTG activity with the existence of a optimum Gdl concentration, whereas the resulting linear model of the gelation time stated that Gdl concentration has a significant influence on the gelation time, while it is independent of the MTG activity. A maximal firmness of 136 ± 2 Pa was reached between a range of 0.24 - 0.27 g Gdl/g protein and 5.8 U MTG/g within a time from 49 to 59 min. Gel permeation chromatography analysis demonstrated that acid gels induced by Gdl were formed by reversible cross-linking like electrostatic interactions and hydrogen bonds as well as disulfide bonds caused by temperature treatment. Whereas, the addition of MTG proved the formation of non-reversible cross-linking like oligomers based on Ne-(g-glutamyl)- lysine, which gave more firmness and stabilization on the casein gel network.

info:eu-repo/classification/ddc/540

ddc:540