Low-Temperature Heat Capacity, Glass-Transition Cooperativity, and Glass-Structure Vault Breakdown in a Series of Poly(n-alkyl methacrylate)s

Abstract: Heat capacity in the 1 K range and close to Tg was studied in a series of poly(n-alkyl methacrylate)s, PnAMA, including some random copolymers. We report on two findings: (i) The glass transition temperature Tg and the cooperativity of the R process that freezes-in at Tg, NR(Tg), decrease smoothly between methyl (PMMA) and hexyl member (PnHMA); the cooperativity from NR(Tg) ) 35 to NR(Tg) ≈ 1. (ii) The tunnel density measured in the 1 K range as c1 constant of the heat capacity function increases between PMMA … Show more

“…[91] The discussed results of the 3 x method measurements in a wide frequency range are independently confirmed by an analysis of conventional DSC data for different poly(alkyl methacrylate)s using a modified [92,93] Narayanaswamy Moynihan (MNM) model and temperaturemodulated DSC measurements ( Figure 8). [92,94] A systematic compilation of the cooperativity at T g is presented in the literature [94] (Figure 9 a and Table 1). Cooperativity is large (N a L 40) for PMMA, having the shortest sidechain and the largest T on -T g difference.…”

“…[92,94] The reasons for this systematic differences are mainly the strong temperature dependence of cooperativity and the temperature differences between DSC and dynamic glass transition temperature, T g -T x , of the order of a few kelvin (see Table 1). However, for both DSC and TMDSC data, cooperativity depends on the side-chain length (C number) in a similar way.…”

“…DSC cooling curves (dT/dt = -10 K/min, thin solid line) and real and imaginary parts of dynamic heat capacity (9) from temperature modulated DSC (t p = 60 s) for (a) PEMA and (b) PPeMA. [94] The methods to determine Dc p from a tangent construction and dT and T x from a fit to the c99 p (T) data with a Gaussian function are indicated.…”

“…(a) Square root of cooperativity versus side-chain length (C number) as calculated from conventional DSC at T g (0) and temperature-modulated DSC at T x (9) using the fluctuation formula (Equation (1)). [94] The calorimetric parameters (T g ; Dc p ; dT) were determined applying a modified Narayanaswamy Moynihan model in the case of DSC data and according to the procedure shown in Figure 8 in the case of TMDSC. The difference between N a from DSC and TMDSC is mainly due to the differences in the (effective) measurement frequency, i. e. the T g À T x difference of a few K. The a and a ranges are indicated by labels.…”

“…(b) Fragility m for the a and a processes from dielectric (g) and shear (F) data as a function of the number of C atoms in the alkyl part of the side-chain. [33,94] The relaxation temperature for a frequency x = 0.01 rad/s (s = 100 s) is used as T g in Equation (4) in the case of dielectric data. Analogously, the relaxation temperature for x = 10 rad/s was used formally as T g in the case of shear data.…”

Relaxation in Poly(alkyl methacrylate)s: Crossover Region and Nanophase Separation

“…[91] The discussed results of the 3 x method measurements in a wide frequency range are independently confirmed by an analysis of conventional DSC data for different poly(alkyl methacrylate)s using a modified [92,93] Narayanaswamy Moynihan (MNM) model and temperaturemodulated DSC measurements ( Figure 8). [92,94] A systematic compilation of the cooperativity at T g is presented in the literature [94] (Figure 9 a and Table 1). Cooperativity is large (N a L 40) for PMMA, having the shortest sidechain and the largest T on -T g difference.…”

“…[92,94] The reasons for this systematic differences are mainly the strong temperature dependence of cooperativity and the temperature differences between DSC and dynamic glass transition temperature, T g -T x , of the order of a few kelvin (see Table 1). However, for both DSC and TMDSC data, cooperativity depends on the side-chain length (C number) in a similar way.…”

“…DSC cooling curves (dT/dt = -10 K/min, thin solid line) and real and imaginary parts of dynamic heat capacity (9) from temperature modulated DSC (t p = 60 s) for (a) PEMA and (b) PPeMA. [94] The methods to determine Dc p from a tangent construction and dT and T x from a fit to the c99 p (T) data with a Gaussian function are indicated.…”

“…(a) Square root of cooperativity versus side-chain length (C number) as calculated from conventional DSC at T g (0) and temperature-modulated DSC at T x (9) using the fluctuation formula (Equation (1)). [94] The calorimetric parameters (T g ; Dc p ; dT) were determined applying a modified Narayanaswamy Moynihan model in the case of DSC data and according to the procedure shown in Figure 8 in the case of TMDSC. The difference between N a from DSC and TMDSC is mainly due to the differences in the (effective) measurement frequency, i. e. the T g À T x difference of a few K. The a and a ranges are indicated by labels.…”

“…(b) Fragility m for the a and a processes from dielectric (g) and shear (F) data as a function of the number of C atoms in the alkyl part of the side-chain. [33,94] The relaxation temperature for a frequency x = 0.01 rad/s (s = 100 s) is used as T g in Equation (4) in the case of dielectric data. Analogously, the relaxation temperature for x = 10 rad/s was used formally as T g in the case of shear data.…”

Relaxation in Poly(alkyl methacrylate)s: Crossover Region and Nanophase Separation

Trend report macromolecular chemistry 2001

Thermal properties and side chain crystallinity of styrene and n‐alkyl methacrylate terpolymers