MCM 41 & MCM 48 (Mobil Composition of Matter)
MCM / SBA / MCF Type Materials – Product Data & ReferencesSilica Powder – Material Safety Data SheetMSDS for Glantreo Silica Powder…Read More Silica Pellets – Material Safety Data SheetMSDS for Glantreo Silica Pellets…Read More Mesoporous Silica ApplicationsBackground Since their discovery in the late 1970s mesoporous silicas have attracted much attention due…Read More Glantreo GMP Silica CapabilityOver the past 15 years Glantreo has established a proven capability of delivering silica based…Read More Typical Physical Properties Particle TypeMCM-41MCM-48 Purity99.99%99.99% Particle Sizes100um*10um & 150um* (MCM-48 Aluminosilicate) Particle MorphologyHexagonalCubic Pore Sizes25A & 30A* (MCM41-Aluminosilicate)25A & 30A* (MCM41-Aluminosilicate) FormatsPowders & PelletsPowders & Pellets ChemistriesRaw, Amine, Thiol Raw, Amine, Thiol * Indicative values. The materials specification is a range in value. Product Variations Product CodeTypePore MorphologyFormatParticle SizePore SizePack SizeChemistry PMCM4110025R-5MCM-41HexaganolPowder100um25A5gSilanol/Raw PMCM4110025NH1-5MCM-41HexaganolPowder100um25A5gAmine PMCM4110025SH1-5MCM-41HexaganolPowder100um25A5gThiol PMCM4110025R-50MCM-41HexaganolPowder100um25A50gSilanol/Raw PMCM4110025NH1-50MCM-41HexaganolPowder100um25A50gAmine PMCM4110025SH1-50MCM-41HexaganolPowder100um25A50gThiol PMCM41AL10030R-50MCM-41 AluminosilicateHexaganolPowder100um30A50gSilanol/Raw PMCM41AL10030R-5MCM-41 AluminosilicateHexaganolPowder100um30A5gSilanol/Raw PMCM41AL10030NH1-5MCM-41 AluminosilicateHexaganolPowder100um30A5gAmine PMCM41AL10030SH1-5MCM-41 AluminosilicateHexaganolPowder100um30A5gThiol PMCM41AL10030NH1-50MCM-41 AluminosilicateHexaganolPowder100um30A50gAmine PMCM41AL10030SH1-50MCM-41 AluminosilicateHexaganolPowder100um30A50gThiol PELMCM4110025R-5MCM-41 PelletsHexaganolPellets100um25A5gSilanol/Raw PMCM481025R-5MCM-48CubicPowder10um25A5gSilanol/Raw PMCM481025NH1-5MCM-48CubicPowder10um25A5gAmine PMCM481025SH1-5MCM-48CubicPowder10um25A5gThiol PMCM481025R-50MCM-48CubicPowder10um25A50gSilanol/Raw PMCM481025NH1-50MCM-48CubicPowder10um25A50gAmine PMCM481025SH1-50MCM-48CubicPowder10um25A50gThiol PMCM48AL15030NH1-5MCM-48 AluminosilicateCubicPowder150um30A5gAmine PMCM48AL15030R-5MCM-48 AluminosilicateCubicPowder150um30A5gSilanol/Raw PMCM48AL15030SH1-5MCM-48 AluminosilicateCubicPowder150um30A5gThiol PMCM48AL15030R-50MCM-48 AluminosilicateCubicPowder150um30A50gSilanol/Raw PMCM48AL15030NH1-50MCM-48 AluminosilicateCubicPowder150um30A50gAmine PMCM48AL15030SH1-50MCM-48 AluminosilicateCubicPowder150um30A50gThiol PELMCM481025R-5MCM-48 PelletsCubicPellets10um25A5gSilanol/Raw Citations using Glantreo’s materials If you have published and cited Glantreo’s materials then click here to let us know. a Abdallah et al., 2014, Comparison of mesoporous silicate supports for the immobilisation and activity of cytochrome c and lipase Noreldeen H. Abdallah, Miriam Schlumpberger, Darragh A. Gaffney, John P. Hanrahan, Joseph M. Tobin, Edmond Magner, Comparison of mesoporous silicate supports for the immobilisation and activity of cytochrome c and lipase, Journal of Molecular Catalysis B: Enzymatic, Volume 108, October 2014, Pages 82-88, ISSN 1381-1177http://www.sciencedirect.com/science/article/pii/S1381117714001805 a Ahern et al, 2013, Comparison of fenofibrate–mesoporous silica drug-loading processes for enhanced drug delivery Robert J. Ahern, John P. Hanrahan, Joseph M. Tobin, Katie B. Ryan, Abina M. Crean, Comparison of fenofibrate–mesoporous silica drug-loading processes for enhanced drug delivery, European Journal of Pharmaceutical Sciences 50 (2013) 400–409 a Ahern et al., 2013, Comparison of fenofibrate–mesoporous silica drug-loading processes for enhanced drug delivery Robert J. Ahern, John P. Hanrahan, Joseph M. Tobin, Katie B. Ryan, Abina M. Crean, Comparison of fenofibrate–mesoporous silica drug-loading processes for enhanced drug delivery, European Journal of Pharmaceutical Sciences, Volume 50, Issues 3–4, 20 November 2013, Pages 400-409, ISSN 0928-0987 http://www.sciencedirect.com/science/article/pii/S0928098713003400 a Barreca et al., 2006, Methanolysis of styrene oxide catalysed by a highly efficient zirconium-doped mesoporous silica Davide Barreca, Mark P. Copley, Andrew E. Graham, Justin D. Holmes, Michael A. Morris, Roberta Seraglia, Trevor R. Spalding, Eugenio Tondello, Methanolysis of styrene oxide catalysed by a highly efficient zirconium-doped mesoporous silica, Applied Catalysis A: General, Volume 304, 10 May 2006, Pages 14-20, ISSN 0926-860Xhttp://www.sciencedirect.com/science/article/pii/S0926860X06001013 a Delaney et al., 2010, Porous silica spheres as indoor air pollutant scavengers Paul Delaney, Healy RM, Hanrahan JP, Gibson LT, Wenger JC, Morris MA, Holmes JD. Porous silica spheres as indoor air pollutant scavengers. Journal of Environmental Monitoring. 2010 Dec;12(12):2244-51. doi: 10.1039/c0em00226g.http://www.ncbi.nlm.nih.gov/pubmed/20941430 a Deninga et al, 2019, adsorption isotherm to explain incomplete drug release from ordered mesoporous silica materials under supersaturating conditions, Tahnee J. Deninga,1, Dmitry Zemlyanovb, Lynne S. Taylora, Application of an adsorption isotherm to explain incomplete drug release from ordered mesoporous silica materials under supersaturating conditions, Journal of Controlled Release 307 (2019) 186–199 a Fordea et al, 2010, modification and immobilisation of lipase B from Candida antarctica onto mesoporous silicates Jessica Fordea, Alex Vakurovb, Tim D. Gibsonb, Paul Millnerb, Mícheál Whelehana, Ian W. Marisona, Ciarán Ó’Fágáina, Chemical modification and immobilisation of lipase B from Candida antarctica onto mesoporous silicates, Journal of Molecular Catalysis B: Enzymatic 66 (2010) 203–209 a Lapidot et al, 2019, Calcium sulphate crystallisation in the presence of mesoporous silica particles Tomer Lapidot, Omar K. Matar, Jerry Y.Y. Heng, Calcium sulphate crystallisation in the presence of mesoporous silica particles: Experiments and population balance modelling, Chemical Engineering Science 202 (2019) 238–249 a McCarthy et al, 2017, In vitro dissolution models for the prediction of in vivo performance of an oral mesoporous silica formulation Carol A. McCarthy, Waleed Faisal, Joseph P. O’Shea, Colm Murphy, Robert J. Aherne, Katie B. Ryan, Brendan T. Griffin, Abina M. Crean , In vitro dissolution models for the prediction of in vivo performance of an oral mesoporous silica formulation, Journal of Controlled Release, Volume 250, 28 March 2017, Pages 86-95 a Mole et al, 2017, Proton dynamics in phosphotungstic acid impregnated mesoporous silica proton exchange membrane materials K. Lamb, R.A. Mole, D. Yu, R. de Marco, J.R. Bartlett, S. Windsor, S.P. Jiang, J. Zhang, V.K. Peterson, Proton dynamics in phosphotungstic acid impregnated mesoporous silica proton exchange membrane materials, Green Energy & Environment (2017), doi: 10.1016/ j.gee.2017.06.007. a Siebert et al, 2019, An immobilized fungal chlorogenase rapidly degrades chlorogenic acid in a T coffee beverage Mareike Siebert∗, Thorben Detering, Ralf G. Berger, An immobilized fungal chlorogenase rapidly degrades chlorogenic acid in a T coffee beverage without altering its sensory properties, LWT – Food Science and Technology 115 (2019) 108426 a Tan et al, 2019, material balance for the phase transition of fluid mixtures confined in nanopores Sugata P. Tan*, Elizabeth Barsotti, Mohammad Piri, Application of material balance for the phase transition of fluid mixtures confined in nanopores, Fluid Phase Equilibria 496 (2019) 31e41 a Waters et al, 2013, Inclusion of fenofibrate in a series of mesoporous silicas using microwave irradiation, Laura J. Waters a,⇑, Talib Hussain a, Gareth Parkes a, John P. Hanrahan b, Joseph M. Tobin, Inclusion of fenofibrate in a series of mesoporous silicas using microwave irradiation, European Journal of Pharmaceutics and Biopharmaceutics 85 (2013) 936–941 a Waters et al., 2013, Inclusion of fenofibrate in a series of mesoporous silicas using microwave irradiation Laura J. Waters, Talib Hussain, Gareth Parkes, John P. Hanrahan, Joseph M. Tobin, Inclusion of fenofibrate in a series of mesoporous silicas using microwave irradiation, European Journal of Pharmaceutics and Biopharmaceutics, Volume 85, Issue 3, Part B, November 2013, Pages 936-941, ISSN 0939-6411http://www.sciencedirect.com/science/article/pii/S0939641113002816
Specifications
- MCM Type
- MCM-41, MCM-41 Aluminosilicate, MCM-41 Pellets, MCM-48, MCM-48 Aluminosilicate, MCM-48 Pellets
- chemistry
- Amine, Silanol/Raw, Thiol
- pore-size
- 25A, 30A
AI Readiness
Good foundation, but some important product data is still missing.