Novel Biobased Polyamide Thermoplastic Elastomer with Medium Hardness

Abstract: Thermoplastic elastomers (TPEs) are useful in various engineering and healthcare applications. A new fully biobased polyamide TPE (PA36,9) with medium hardness is reported. The elastomer is synthesized using a fatty dimer amine and azelaic acid, via one-pot melt condensation polymerization. The resulting elastomer shows a melting temperature of 83.6 °C, a medium hardness (Shore A/Shore D = 90/35), a large elongation at break (1220%), good resilience, and impact resistance, while maintaining high tensile streng… Show more

“…The hysteresis ratio ( h r ) is calculated by the ratio of the energy dissipation ( e d ) to the energy absorption (i.e., the area below the loading curve, e a ), i.e., Equation () [ 43 ] $$\begin{equation}{h_{\rm{r}}} = \frac{{{e_{\rm{d}}}}}{{{e_{\rm{a}}}}}\end{equation}$$…”

“…[37,41] A higher energy dissipation is beneficial for these elastomer nanocomposites to be used in shock absorption applications. [42] The hysteresis ratio (h r ) is calculated by the ratio of the energy dissipation (e d ) to the energy absorption (i.e., the area below the loading curve, e a ), i.e., Equation (1) [43]…”

Wholly Biobased Polyamide Thermoplastic Elastomer‐Cellulose Nanocomposites

“…The hysteresis ratio ( h r ) is calculated by the ratio of the energy dissipation ( e d ) to the energy absorption (i.e., the area below the loading curve, e a ), i.e., Equation () [ 43 ] $$\begin{equation}{h_{\rm{r}}} = \frac{{{e_{\rm{d}}}}}{{{e_{\rm{a}}}}}\end{equation}$$…”

“…[37,41] A higher energy dissipation is beneficial for these elastomer nanocomposites to be used in shock absorption applications. [42] The hysteresis ratio (h r ) is calculated by the ratio of the energy dissipation (e d ) to the energy absorption (i.e., the area below the loading curve, e a ), i.e., Equation (1) [43]…”

Wholly Biobased Polyamide Thermoplastic Elastomer‐Cellulose Nanocomposites

“…[42] The hysteresis ratio (hr) is calculated by the ratio of the energy dissipation (ed) to the energy absorption (i.e. the area below the loading curve, ea), i.e., equation (1) [43] .…”

Wholly Biobased Polyamide Thermoplastic Elastomer‐Cellulose Nanocomposites

“…Recently, we prepared a couple of novel wholly biobased polyamide elastomers, PA36,36 [ 7 ] and PA36,9 [ 8 ] PA36,36 is an amorphous elastomer that shows excellent hydrophobicity, super stretchability (up to 2300%), a high toughness (17.3 MJ m −3 ), low hardness (Shore A/Shore D = 16/6), low glass transition temperature ( T g = 3.3 °C), and remarkable autonomous self‐healing efficiency. [ 7 ] PA36,9 is a semi‐crystalline elastomer that has a high tensile strength (31.8 MPa), large elongation at break (1220%), medium hardness (Shore A/Shore D = 90/35), T g of 17.6 °C, and a melting temperature ( T m ) of 83.6 °C, while maintaining high hydrophobicity.…”

“…[ 7 ] PA36,9 is a semi‐crystalline elastomer that has a high tensile strength (31.8 MPa), large elongation at break (1220%), medium hardness (Shore A/Shore D = 90/35), T g of 17.6 °C, and a melting temperature ( T m ) of 83.6 °C, while maintaining high hydrophobicity. [ 8 ] Despite excellent properties, these polyamide elastomers have been reinforced with cellulose nanocrystals (CNCs) to broaden their applications. [ 9 ] CNCs have a high aspect ratio (length 50–500 nm and diameter 3–5 nm), and high crystallinity (54–88%).…”

Biobased Polyamide 4,36 Thermoplastic Elastomer and its Cellulose Nanocomposites