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Diatomite - a material of many possibilities
Języki publikacji
Abstrakty
Diatomit to ziemia okrzemkowa, naturalny minerał pochodzenia organicznego. Skały okrzemkowe należą do skał osadowych, powstałych w okresie trzeciorzędu i czwartorzędu z pancerzyków jednokomórkowych okrzemek, które osiadły na dnie mórz i jezior. Podstawowym składnikiem diatomitu jest krzemionka SiO2 o różnym stopniu uwodnienia, której towarzyszą niewielkie ilości innych substancji mineralnych. Materiał ten posiada ujemny ładunek elektryczny, stąd zdolność diatomitu do przyciągania różnorodnych cząsteczek, do których należą liczne zanieczyszczenia. Artykuł omawia unikatowe właściwości diatomitu, które mogą być wykorzystane w wielu dziedzinach biogospodarki.
Diatomite is diatomaceous earth, a natural mineral of organic origin. Diatomaceous rocks were formed in the Tertiary and Quaternary periods from the shells of single celled diatoms that settled on the bottom of seas and lakes. The basic component of diatomite is silica SiO2 of various degrees of hydration, with small amounts of other minerals. This mineral material has a negative electric charge, therefore diatomite shows ability to attract various particles, including numerous impurities. The paper discusses the unique properties of diatomite that can be used in many areas of the bioeconomy.
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Tom
Strony
59--62
Opis fizyczny
Bibliogr. 33 poz.
Twórcy
autor
- Katedra Biotechnologii Środowiskowej, Wydział Biotechnologii i Nauk o Żywności, Politechnika Łódzka
autor
- Katedra Biotechnologii Środowiskowej, Wydział Biotechnologii i Nauk o Żywności, Politechnika Łódzka
Bibliografia
- 1. Ibrahim S.S., Selim A.Q: Producing a micro-porous diatomite by a simple classification-calcination proces. „The Journal of ORE DRESSING”, 2010, 12 (23), 25-33.
- 2. Elden H., Morsy G., Bakr M.: Diatomite: Its characterization, modifications and applications. „Asian Journal of Materials Science", 2010, 2 (3), 121-136.
- 3. Ivanov S.E., Belyakov A.V.: Diatomite and its applications. „Glass and Ceramics”, 2008, 65, 48-51.
- 4. Wang Y., Lu Y., Chen R., Ma L., Jiang Y., Wang H.: Lead ions sorption from waste solution using aluminum hydroxide modified diatomite. „Journal of Environmental Protection”, 2014, 5, 509-516.
- s. Danil de Namor A.F., El Gamouz A., Frangie S., Martinez V., Valiente L., Webb O.A: Turning the volume down on heavy metals using tuned diatomite. A review of diatomite and modified diatomite for the extraction of heavy metals from water. „Journal of Hazardous Materials”, 2012, 241-242, 14-31.
- 6. El-Shafey E.L., Gameiro M., Correia P.J. de Cravalho: Dewatering of brewer's spent grain using a membrane filter press: A pilot plant study. „Separation Science and Technology”, 2004, 39 (14), 3237-3261.
- 7. Ibrahim S.S., Selim A.Q: Evaluation of Egyptian diatomite for filter aid applications. „Physicochemical Problems of Mineral Processing”, 2011, 47, 113-122.
- 8. Iliescu M., Farago M., Popa M., Cristea M.: Reuse of residual kieselguhr from beer filtration as a fertilizer. „Journal of Environmental Protection and Ecology”, 2009, 10, 156-162.
- 9. Dessalew G. , Beyene A. , Nebiyu A. , Ruelle M.L. : Use of industrial diatomite wastes from beer production to improve soil fertility and cereal yields. „Journal of Cleaner Production”, 2017, 157, 22-29.
- 10. Tsai W.T., Hsien K.J., Yang J.M.: Silica adsorbent prepared from spent diatomaceous earth and its application to removal of dye from aqueous solution. „Journal of Colloid and Interface Science”, 2004, 275, 428-433.
- 11. Dessalew G., Beyene A., Nebiyu A., Astatkie T.: Effect of brewery spent diatomite sludge on trace metal availability in soil and uptake by wheat crop, and trace metal risk on human health through the consumption of wheat grain. „Heliyon”, 2018, 4 (9), e00783.
- 12. Luque O., Bracho O., Maier T.W.: Utilization of brewery was te water sludge for soil improvement. „The Technical Quarterly of Master Brewers Association of the Americas”, 1990, 27, 5-9.
- 13. Katsarova A., Koutev V.: Incubation study of kieselguhr (diatomite) for application as organic fertilizer and soil a meliorant. RAMIRAN 2013 - 15th International Conference, Versailles, France, 2013. Proceedings S1.30.
- 14. Gong X., Tian W., Bai J., Qiao K., Zhao J., Wang L.: Highly efficient deproteinization with an ammonifying bacteria Lysinibacillus fusiformis isolated from brewery spent diatomite. „Journal of Bioscience and Bioengineering”, 2019a, 127 (3), 326-332.
- 15. Gong X., Tian W., Wang L., Bai J., Qjao K., Zhao J.: Biological regeneration of brewery spent diatomite and its reuse in basic dye and chromium (III) ions removal. „Process Safety and Environmental Protection”, 2019b, 128, 353-361.
- 16. Tsai W-T., Hsien K-J., Lai C-W.: Chemical activation of spent diatomaceous earth by alkaline etching in the preparation of mesoporous adsorbents. „Industrial & Engineering Chemistry Research”, 2004, 43, 7513-7520.
- 17. Selim A.Q., El-Midany A.A., Ibrahim S.S.: Microscopic evaluation of diatomite for advanced applications: Case study. [In]: Mendez-Vilas A., Diaz J.: Microscopy: Science, Technology, Applications and Education. ©FORMATEX 2010, 2174-2181.
- 18. Ibrahim S.S., Selim A.Q.: Heat treatment of natural diatomite. „Physicochemical Problems of Mineral Processing”, 2020, 48 (2), 413-44.
- 19. Li Q., Qi Y., Gao C.: Chemical regeneration of spent powdered activated carbon used in decolorization of sodium salicylate for the pharmaceutical industry. „Journal of Cleaner Production”, 2015, 86, 424-431.
- 20. Khraisheh M.A.M., Al-Ghouti M.A., Allen S.J., Ahmad M.N.: Effect of OH and silanol groups in the removal of dyes from aqueous solution using diatomite. „Water Reserach”, 2005a, 39, 922-932.
- 21. Khraisheh M.A.M., Al-Ghouti M.S.: Enhanced dye adsorption by microemulsion-modified calcined diatomite (μE-CD). „Adsorption”, 2005b, 11, 547-559.
- 22. Larsson M., Nosrati A., Kaur S., Wagner J., Baus U., Nydén M.: Copper removal from acid mine drainage-polluted water using glutaraldehyde - polyethyleneimine modified diatomaceous earth particles. „Heliyon”, 2018, 4 (2), e00520.
- 23. El Sayed El Bastamy E.: Natural diatomite as an effective adsorbent for heavy metals in water and wastewater treatment (a batch study). „Water Science”, 2018, 32, 32-43.
- 24. Yusan S., Gok C., Erenturk S., Aytas S.: Adsorptive removal of thorium (IV) using calcined and flux calcined diatomite from Turkey: Evaluation of equilibrium, kinetic and thermodynamic data. „Applied Clay Science”, 2012, 67, 106-116.
- 25. Tekle-Haimanot R., Melaku Z., Kloos H., Reimann C., Fantaye W., Zerihun L., Bjorvatn K.: The geographic distribution of fluoride in surface and groundwater in Ethiopia with an emphasis on the Rift Valley. „Science of the Total Environment”, 2006, 367 (1), 182-190.
- 26. Yitbarek M., Abdeta K., Beyene A., Astatkie H., Dadi D., Desalew G., Van der Bruggen B.: Experimental evaluation of sorptive removal of fluoride from drinking water using natural and brewery waste diatomite. „Process Safety and Environmental Protection”, 2019, 128, 95-106.
- 27. Tsai W. T., Hsien K.J]., Chang Y.M., Lo C.C.: Removal of herbicide paraquat from an aqueous solution by adsorption on to spent and treated diatomaceous earth. „Bioresource Technology”, 2005, 96, 657-663.
- 28. Brinkmana N.E., Hafflera T.D., Cashdollara J.L., Rhodes E.R.: Evaluation of methods using celite to concentrate norovirus, adenowirus and enterovirus from wastewater. „Journal of Virological Methods”, 2013, 193, 140-146.
- 29. Liu Y., Tian T.: Fabrication of diatomite/silicalite-1 composites and their property for VOCs adsorption. „Materials”, 2019, 12, 551.
- 30. Letelier V., Tarela E., Moriconi G.: Assessment of the mechanical properties of a concrete made by reusing both: Brewery spent diatomite and recycled aggregates. „Construction and Building Materials”, 2016, 114, 492-498.
- 31. Gökçe M.V., Koç I.K.: Use of diatomite in the production of lightweight building elements with cement as binder. „Scientific Research and Essays”, 2012, 7 (7), 774-781.
- 32. Smoleńska A., Rembiś M.: Diatomit jako lekkie kruszywo mineralne w tynkach renowacyjnych. „Prace Naukowe Instytutu Górnictwa Politechniki Wrocławskiej. Konferencje”, 2002, 97, 197-203.
- 33. Shih Y.F., Wang C.H., Tsai M.L., Jehng J.M.: Shape-stabilized phase change material/nylon composite based on recycled diatomite. „Materials Chemistry and Physics”, 2020, 242, 122498.
Uwagi
PL
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-d919ed0a-52e6-4fab-9ee7-6ff0544bf796