FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2299539658> ?p ?o ?g. }

• W2299539658 abstract "The present investigation is based on a comparative study of the polymerization reactions of 2-hydroxyethyl methacrylate (HEMA) using riboflavin (RF), camphorquinone (CQ) and safranin T (ST) as photoinitiators and triethanolamine (TEOHA) as a co-initiator in aqueous and organic solvents.HEMA is involved in photoinitiated polymerization reactions occurring in glass-ionomer cements (GICs).The above photoinitiators are stable on exposure to a 15 W lamp emitting in the visible region during the irradiation period.A UV spectrophotometric method has been developed to determine the concentration of HEMA in polymerized solutions at low conversion, i.e., about 5% concentration change in the monomer.The effect of pH, solvent characteristics and HEMA / TEOHA concentration on the rate of polymerization reactions has been evaluated.The rates of the reactions have been found to increase with pH probably as a result of the deprotonation of TEOHA and the presence of a labile proton on the hydroxyl group of HEMA.The steady-state assumption of the rate of initiation being equal to the rate of termination is considered valid only at a low conversion of the monomer.Under these conditions the polymerization reactions have been found to follow pseudo first-order kinetics (within about 5 % change in HEMA concentration) and the determined apparent firstorder rate constants (kobs) range from 5.44–7.63×10–4s–1 at pH 6.0–9.0 using 0.01M TEOHA.The polymerization reactions of HEMA are affected by the dielectric constant and viscosity of the medium.There is a linear relation between the rate constants and the solvent dielectric constant indicating the involvement of a polar intermediate in the reaction.The observation of a linear relation between the rate constants and the inverse of solvent viscosity indicates the effect of viscosity on the diffusional processes of reacting species and hence the decrease in rates with an increase in the viscosity of the medium.For all the photoinitiators used the polymerization reaction is dependent on the TEOHA concentration and the secondorder rate constants for the interaction of HEMA (1–3M) and TEOHA 0.0025– 0.01M) range from 1.79–8.87×10–2 M–1s–1 at pH 6.0–9.0.The reactivity of the photoinitiators appears to depend on the energy of the excited triplet state, and its degree of interaction with the amine to form a radical ion pair, its dissociation and further interaction of amine radicals with HEMA to undergo polymerization.In the present work, the reactivity of the photoinitiators has been found to be in the order: RF > CQ > ST.The irradiation wavelength of the photoinitiators also increases in the same order resulting in decreased energy and, therefore, it may influence the efficacy of the photoinitiator.The polymerization of HEMA photoinitiated by the three compounds is faster in aqueous solution compared with the organic solvent under identical conditions.The results indicate that the reactivity of the photoinitiators depends upon their structural features, ionization behavior, spectral characteristics, triplet energy and solvent characteristics.It appears that the photoinitiators absorbing in the lower visible region are more efficient (RF 445 nm, CQ 468 nm) in causing polymerization of HEMA compared to those absorbing in the relatively higher visible region (ST 520 nm), as indicated by their absorption maxima.Therefore, the use of RF as a photoinitiator in glass ionomer cements would require a relatively less curing time for the setting of resin restorative materials and it appears to be the most efficient photoinitiator in the polymerization process under the conditions studied." @default.
• W2299539658 created "2016-06-24" @default.
• W2299539658 creator A5000921734 @default.
• W2299539658 creator A5008758296 @default.
• W2299539658 date "2011-01-01" @default.
• W2299539658 modified "2023-09-27" @default.
• W2299539658 title "PHOTOPOLYMERIZATION OF 2 HYDROXYETHYL METHACRYLATE IN THE DEVELOPMENT OF GLASS-IONOMER CEMENTS" @default.
• W2299539658 cites W1008229601 @default.
• W2299539658 cites W134868747 @default.
• W2299539658 cites W142237626 @default.
• W2299539658 cites W152111335 @default.
• W2299539658 cites W1532976563 @default.
• W2299539658 cites W1555088795 @default.
• W2299539658 cites W1572391771 @default.
• W2299539658 cites W1581549611 @default.
• W2299539658 cites W1595853473 @default.
• W2299539658 cites W1600921146 @default.
• W2299539658 cites W1605522739 @default.
• W2299539658 cites W176309609 @default.
• W2299539658 cites W1771664669 @default.
• W2299539658 cites W1931172525 @default.
• W2299539658 cites W1934583032 @default.
• W2299539658 cites W1964789752 @default.
• W2299539658 cites W1966246114 @default.
• W2299539658 cites W1966513117 @default.
• W2299539658 cites W1968710778 @default.
• W2299539658 cites W1968952585 @default.
• W2299539658 cites W1969761504 @default.
• W2299539658 cites W1969768053 @default.
• W2299539658 cites W1971543966 @default.
• W2299539658 cites W1972851496 @default.
• W2299539658 cites W1972888996 @default.
• W2299539658 cites W1973728751 @default.
• W2299539658 cites W1973782464 @default.
• W2299539658 cites W1975550918 @default.
• W2299539658 cites W1978179044 @default.
• W2299539658 cites W1978293427 @default.
• W2299539658 cites W1982805170 @default.
• W2299539658 cites W1983695433 @default.
• W2299539658 cites W1984068532 @default.
• W2299539658 cites W1984073972 @default.
• W2299539658 cites W1984837099 @default.
• W2299539658 cites W1987105695 @default.
• W2299539658 cites W1987347838 @default.
• W2299539658 cites W1988823306 @default.
• W2299539658 cites W1988914011 @default.
• W2299539658 cites W1988986340 @default.
• W2299539658 cites W1991937742 @default.
• W2299539658 cites W1992669762 @default.
• W2299539658 cites W1993439357 @default.
• W2299539658 cites W1994326397 @default.
• W2299539658 cites W1994369615 @default.
• W2299539658 cites W1995954769 @default.
• W2299539658 cites W1996684454 @default.
• W2299539658 cites W1998447144 @default.
• W2299539658 cites W1999572601 @default.
• W2299539658 cites W2000661666 @default.
• W2299539658 cites W2001128249 @default.
• W2299539658 cites W2001245676 @default.
• W2299539658 cites W2001270915 @default.
• W2299539658 cites W2003631136 @default.
• W2299539658 cites W2005269306 @default.
• W2299539658 cites W2006192669 @default.
• W2299539658 cites W2006469698 @default.
• W2299539658 cites W2006585076 @default.
• W2299539658 cites W2007163520 @default.
• W2299539658 cites W2008098588 @default.
• W2299539658 cites W2009463750 @default.
• W2299539658 cites W2011833279 @default.
• W2299539658 cites W2011934987 @default.
• W2299539658 cites W2013011921 @default.
• W2299539658 cites W2013515654 @default.
• W2299539658 cites W2014632288 @default.
• W2299539658 cites W2014838859 @default.
• W2299539658 cites W2015977186 @default.
• W2299539658 cites W2018691062 @default.
• W2299539658 cites W2018848065 @default.
• W2299539658 cites W2019145433 @default.
• W2299539658 cites W2020252762 @default.
• W2299539658 cites W2021571134 @default.
• W2299539658 cites W2022794555 @default.
• W2299539658 cites W2023063966 @default.
• W2299539658 cites W2023135981 @default.
• W2299539658 cites W2023311833 @default.
• W2299539658 cites W2023433221 @default.
• W2299539658 cites W2023633063 @default.
• W2299539658 cites W2024199754 @default.
• W2299539658 cites W2025161633 @default.
• W2299539658 cites W2026252203 @default.
• W2299539658 cites W2027291050 @default.
• W2299539658 cites W2027989631 @default.
• W2299539658 cites W2028130616 @default.
• W2299539658 cites W2028138785 @default.
• W2299539658 cites W2031416312 @default.
• W2299539658 cites W2034121262 @default.
• W2299539658 cites W2034736249 @default.
• W2299539658 cites W2035098687 @default.
• W2299539658 cites W2036337279 @default.
• W2299539658 cites W2036639435 @default.
• W2299539658 cites W2037177514 @default.

• next