SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2151208855> ?p ?o ?g. }

Showing items 1 to 100 of ±152 with 100 items per page.

W2151208855 endingPage "287" @default.
W2151208855 startingPage "278" @default.
W2151208855 abstract "The melting temperature depression of three different biodegradable polyesters, poly(ɛ-caprolactone) (PCL), poly(3-hydroxybutyrate) (PHB) and poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) in the presence of CO2 have been investigated by optical measurements using a variable-volume high-pressure view-cell. A pressure range up to 35 MPa was investigated. It is shown that melting temperature of PCL initially increases from 64 °C to 67 °C then decreases and passes through a minimum at around 10 MPa before leveling off at about 44 °C with increasing CO2 pressure. The melting temperatures of PHB and PHBV decrease essentially linearly up to 24 MPa, the change being from 178 °C to 152 °C in PHB and from 171 °C to 142 °C in PHBV. The melting temperatures for these polymers continue to decrease but at a lower rate up to 35 MPa with the lowest melting temperatures of 151 °C and 137 °C being reached by about 35 MPa, respectively. Molecular weight determinations by GPC on samples that were exposed to and melted in CO2 showed that no degradation was occurring during melting in CO2. These findings show that melt processing of PHB and PHBV which are prone to thermal degradation upon melting in ambient atmosphere is achievable without causing degradation in CO2 medium. It is also shown that the measurement of transmitted light intensities can be an effective technique in assessing the multiple melting temperatures and complete melting of different domains." @default.
W2151208855 created "2016-06-24" @default.
W2151208855 creator A5013859822 @default.
W2151208855 creator A5035498982 @default.
W2151208855 creator A5036379411 @default.
W2151208855 date "2012-12-01" @default.
W2151208855 modified "2023-10-16" @default.
W2151208855 title "Melting behavior of biodegradable polyesters in carbon dioxide at high pressures" @default.
W2151208855 cites W162430886 @default.
W2151208855 cites W1966217561 @default.
W2151208855 cites W1967278855 @default.
W2151208855 cites W1969493338 @default.
W2151208855 cites W1971916284 @default.
W2151208855 cites W1972451885 @default.
W2151208855 cites W1972915436 @default.
W2151208855 cites W1973397182 @default.
W2151208855 cites W1975140717 @default.
W2151208855 cites W1984418916 @default.
W2151208855 cites W1989180239 @default.
W2151208855 cites W1989238463 @default.
W2151208855 cites W1990335336 @default.
W2151208855 cites W1992671336 @default.
W2151208855 cites W1996173241 @default.
W2151208855 cites W2000665714 @default.
W2151208855 cites W2003519902 @default.
W2151208855 cites W2006061790 @default.
W2151208855 cites W2007787821 @default.
W2151208855 cites W2007809256 @default.
W2151208855 cites W2008231912 @default.
W2151208855 cites W2008421016 @default.
W2151208855 cites W2008652822 @default.
W2151208855 cites W2011904261 @default.
W2151208855 cites W2014742001 @default.
W2151208855 cites W2015892866 @default.
W2151208855 cites W2016041170 @default.
W2151208855 cites W2017110903 @default.
W2151208855 cites W2025292917 @default.
W2151208855 cites W2028996989 @default.
W2151208855 cites W2029889679 @default.
W2151208855 cites W2032983037 @default.
W2151208855 cites W2038486860 @default.
W2151208855 cites W2040550121 @default.
W2151208855 cites W2043038625 @default.
W2151208855 cites W2044483416 @default.
W2151208855 cites W2045129810 @default.
W2151208855 cites W2048703822 @default.
W2151208855 cites W2051658225 @default.
W2151208855 cites W2051876363 @default.
W2151208855 cites W2052523778 @default.
W2151208855 cites W2056049046 @default.
W2151208855 cites W2058569705 @default.
W2151208855 cites W2066061791 @default.
W2151208855 cites W2067650133 @default.
W2151208855 cites W2075986712 @default.
W2151208855 cites W2077326384 @default.
W2151208855 cites W2083848277 @default.
W2151208855 cites W2086935704 @default.
W2151208855 cites W2088301937 @default.
W2151208855 cites W2091775508 @default.
W2151208855 cites W2091822530 @default.
W2151208855 cites W2091887567 @default.
W2151208855 cites W2092343777 @default.
W2151208855 cites W2095361047 @default.
W2151208855 cites W2100724046 @default.
W2151208855 cites W2103330792 @default.
W2151208855 cites W2108463100 @default.
W2151208855 cites W2115345521 @default.
W2151208855 cites W2115979945 @default.
W2151208855 cites W2121242400 @default.
W2151208855 cites W2122105905 @default.
W2151208855 cites W2138059837 @default.
W2151208855 cites W2151585742 @default.
W2151208855 cites W2162786412 @default.
W2151208855 cites W2162901606 @default.
W2151208855 cites W2171415478 @default.
W2151208855 cites W2785478374 @default.
W2151208855 cites W298995639 @default.
W2151208855 cites W4231953041 @default.
W2151208855 cites W4232732649 @default.
W2151208855 cites W4250776470 @default.
W2151208855 doi "https://doi.org/10.1016/j.supflu.2012.09.009" @default.
W2151208855 hasPublicationYear "2012" @default.
W2151208855 type Work @default.
W2151208855 sameAs 2151208855 @default.
W2151208855 citedByCount "31" @default.
W2151208855 countsByYear W21512088552013 @default.
W2151208855 countsByYear W21512088552014 @default.
W2151208855 countsByYear W21512088552015 @default.
W2151208855 countsByYear W21512088552016 @default.
W2151208855 countsByYear W21512088552017 @default.
W2151208855 countsByYear W21512088552018 @default.
W2151208855 countsByYear W21512088552019 @default.
W2151208855 countsByYear W21512088552020 @default.
W2151208855 countsByYear W21512088552021 @default.
W2151208855 countsByYear W21512088552022 @default.
W2151208855 countsByYear W21512088552023 @default.
W2151208855 crossrefType "journal-article" @default.
W2151208855 hasAuthorship W2151208855A5013859822 @default.