Thermal properties glass transition temperature

Interesting comparisons have been made 17 between dendritic and the hyperbranched structures the thermal properties (glass transition temperature and thermogravimetric analysis) were independent of architecture and their solubilities were comparable, but greater than that shown for linear counterparts. 

Thermal properties Glass-transition temperature (Tg), °C Melting temperature (Tm), °C Heat-deflection temperature (HDT) at 0.45 or 1.8 MPa, °C D648 75... 

The method of irradiation and the dose can influence several properties such as thermal properties (glass transition temperature decomposition temperature T(jeo crystallization temperature Tc, and melting temperature T ) and mechanical properties (tensile strength, modulus at 50% elongation, gel... 

Good thermo-mechanical properties. Glass transition temperatures range from 300 to 340 °C. Thermal stability is good up to 400 °C. Elongation to break is typically 20%. On wafer stress is 18 MPa, less than half that found for typical polyimides. 

Other polymer properties that are often measured are whiteness, color, thermal stability, glass transition temperature (wet and dry), melting point (wet and dry), dope viscosity, and gelation characteristics. Techniques used for characterizing acrylic textile polymers are summarized in Table 12.30. 

The glass-transition temperature, T, of dry polyester is approximately 70°C and is slightly reduced ia water. The glass-transitioa temperatures of copolyesters are affected by both the amouat and chemical nature of the comonomer (32,47). Other thermal properties, including heat capacity and thermal conductivity, depend on the state of the polymer and are summarized ia Table 2. 

Relatively few processible polyimides, particularly at a reasonable cost and iu rehable supply, are available commercially. Users of polyimides may have to produce iutractable polyimides by themselves in situ according to methods discussed earlier, or synthesize polyimides of unique compositions iu order to meet property requirements such as thermal and thermoxidative stabilities, mechanical and electrical properties, physical properties such as glass-transition temperature, crystalline melting temperature, density, solubility, optical properties, etc. It is, therefore, essential to thoroughly understand the stmcture—property relationships of polyimide systems, and excellent review articles are available (1—5,92). 

Thermal Properties. Spider dragline silk was thermally stable to about 230°C based on thermal gravimetric analysis (tga) (33). Two thermal transitions were observed by dynamic mechanical analysis (dma), one at —75° C, presumed to represent localized mobiUty in the noncrystalline regions of the silk fiber, and the other at 210°C, indicative of a partial melt or a glass transition. Data from thermal studies on B. mori silkworm cocoon silk indicate a glass-transition temperature, T, of 175°C and stability to around 250°C (37). The T for wild silkworm cocoon silks were slightly higher, from 160 to 210°C. 

T and are the glass-transition temperatures in K of the homopolymers and are the weight fractions of the comonomers (49). Because the glass-transition temperature is directly related to many other material properties, changes in T by copolymerization cause changes in other properties too. Polymer properties that depend on the glass-transition temperature include physical state, rate of thermal expansion, thermal properties, torsional modulus, refractive index, dissipation factor, brittle impact resistance, flow and heat distortion properties, and minimum film-forming temperature of polymer latex... 

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