Glass transition temperature and thermal decomposition of cellulose powder

Szcześniak, Ł.; Rachocki, Adam; Tritt‐Goc, Jadwiga

doi:10.1007/s10570-007-9192-2

Cited by 278 publications

(188 citation statements)

References 8 publications

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“…However, the shift in the glass transition temperature of the wet resin system shows a confinement effect as discussed by Arndt et al 47 for salol relaxation dynamics in nanometer size pores; the relaxation rate of the confined material increased compared to bulk material. Some other examples of observed low T g with moisture/ water content can be found in the literature, 10,11,48 where change in the glass temperature was reported for inulin, epoxy resins and cellulose. The epoxy system studied 11 showed that the glass transition estimated from the mechanical modulus shifted to lower temperatures with different moisture treatment with shift related to the moisture weight gain, which we have not included in this work.…”

Section: Dielectric Relaxation Mapmentioning

confidence: 84%

“…6 The presence of water and its influence in the dielectric response were previously studied in various polymeric systems. [7][8][9][10][11] Here, we concentrate on the change in the dielectric properties of highly filled composites in the presence of water, and report on the dielectric relaxation of moisture-absorbed and dry samples.…”

Section: Introductionmentioning

confidence: 99%

“…The method has been applied to various different material systems. [7][8][9][10][11][20][21][22] Electrical properties of materials can be determined from the impedance measurements by performing current measurements with applied voltage and using the geometrical capacitance C 0 , the geometry of the sample. For example, for the complex permittivity, " Ã is estimated from the current measurement as a complex capacitance C Ã for a given geometrical shape of the measurement electrodes, which determine the geometrical capacitance C 0 , Here, the angular frequency, !, independent material properties are of relative permittivity at high frequencies, " 1 , and Ohmic (direct-current) conductivity, 0 ; ı ¼ ffiffiffiffiffiffi ffi À1 p .…”

Section: Introductionmentioning

confidence: 99%

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Change in dielectric relaxation with the presence of water in highly filled composites

Tuncer

2017

J. Adv. Dielect.

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It is important to determine the dielectric characteristics of semiconductor encapsulation materials based on epoxy resins. We employed the dielectric spectroscopy technique to investigate the dielectric relaxation in the presence of water and how it changes the relaxation. It was observed that the dielectric relaxation of the material was significantly influenced by absorbed water, the local segmental motion (also known as Johari-Goldstein ( ) relaxation) was influenced most by the presence of the water, it was modified by the wet sample compared to dry one, and required high activation energy. The relaxation related to the glass transition was contributed by the cooperative motion (the -relaxation) of the epoxy resin system. The -relaxation was shifted to a low temperature in the wet sample compared to dry one. The relaxation was modeled with a clear Vogel-Fulcher-Tammann-Hesse (VFTH) behavior; the Vogel temperature of the wet sample was 8 K lower than the dry sample. The presence of water acts as a plasticizer for the molecular relaxation, and speed-up the cooperative process. The measured data were also used to estimate the electrical properties of the resin system by employing an effective-medium model together with a porous media continuum model by taking into account the physical properties of the system. It is already known that the influence of water in semiconductor packaging is important in sensitive applications. The presented measurements and the analysis method would be appreciated within the semiconductor packaging community to improve material selection and performance evaluation efforts.

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Section: Dielectric Relaxation Mapmentioning

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Change in dielectric relaxation with the presence of water in highly filled composites

Tuncer

2017

J. Adv. Dielect.

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“…Thermal stability has been characterized by thermogravimetry analysis (TGA) [10] and physical structure by differential scanning calorimetry (DSC) [11]. In the literature, thermogravimetry analyses of cellulose point out two weight losses; the first one in the range of 40 to 80°C attributed to the water evaporation [11][12][13] and the second one in the temperature range of 200 to 400°C, to polymer degradation.…”

Section: Introductionmentioning

confidence: 99%

“…In the literature, thermogravimetry analyses of cellulose point out two weight losses; the first one in the range of 40 to 80°C attributed to the water evaporation [11][12][13] and the second one in the temperature range of 200 to 400°C, to polymer degradation. During this decomposition, the principal products are water and carbon dioxide [5,11,12,14,15].…”

Section: Introductionmentioning

confidence: 99%

Influence of hydrogen bonds on glass transition and dielectric relaxations of cellulose

Roig¹,

Dantras²,

Dandurand³

et al. 2011

J. Phys. D: Appl. Phys.

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The molecular dynamic in hydrated cellulose has been investigated by a combination of thermal analyses and dielectric spectroscopy. Differential Scanning Calorimetry (DSC) shows the dependence upon hydration of the glass transition temperature T g . A physical ageing phenomenon has been observed. At the molecular scale, bound water is hydrogen bonded to polar sites of cellulose macromolecules. At the macroscopic scale, water molecules play the role of a plasticizer for cellulose lowering its T g . Dynamic Dielectric Spectroscopy (DDS) combined with Thermostimulated Currents (TSC) have allowed us to follow more localized molecular mobility. The β relaxation mode is characterized by activation entropies that vanish for higher water contents indicating molecular mobility localization. It is plasticized by water like the glass transition. This analogy is explained by a common origin of both mechanisms: the mobility of the cellulose backbone. The evolution of the γ mode upon hydration follows an anti-compensation law. Water acts as an anti-plasticizer in a hydrogen bonded network.

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All‐Cellulose Composites

Staiger

Huber

2012

Wiley Encyclopedia of Composites

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Composite materials comprising a mixture of shellac resin as the matrix and cellulose as the reinforcement were developed. The influence of the reinforcement content and the concentration of additives on the mechanical performance and processing were investigated. A high content of cellulose and low concentrations of ethanol and polyethylene glycol produced biocomposites with high stress resistance and a high Young's modulus, whereas a low content of cellulose and a high concentration of additives gave samples a low Young's modulus and high elasticity. Two types of cellulose-based reinforcements with different polarity, namely, mechanically refined wood pulp and cellulose acetate butyrate particles, were compared. The efficiency of the composite over the two model reinforcements, i.e., hydrophilic and hydrophobic components, respectively, was also studied. Although particle reinforcement was easier to process and evenly dispersed into the matrix, its mechanical performance was lower compared with refined fibres. Scanning electron microscopy showed that the matrix better coated the fibres than the particles, resulting in better adhesion and mechanical performance. The morphology of reinforcement played a key role; long fibres oriented in the pulling direction ensured a better mechanical resistance than particle fillers.

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Glass transition temperature and thermal decomposition of cellulose powder

Cited by 278 publications

References 8 publications

Change in dielectric relaxation with the presence of water in highly filled composites

Change in dielectric relaxation with the presence of water in highly filled composites

Influence of hydrogen bonds on glass transition and dielectric relaxations of cellulose

All‐Cellulose Composites

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