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Podstawy i możliwości wykorzystania procesu biomineralizacji węglanu wapnia

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Warianty tytułu
EN
Principles and possible applications of calcium carbonate biomineralization
Języki publikacji
PL
Abstrakty
PL
Węglan wapnia CaCO3 jest substancją szeroko rozpowszechnioną w przyrodzie i znajduje liczne zastosowania praktyczne. W przyrodzie jego biomineralizacja jest między innymi wynikiem procesów strącania indukowanych mikrobiologicznie. Jednym z nich jest strącanie indukowane przez bakterie ureolityczne. Proces ten, jeśli prowadzony biomimetycznie, zachodzi w łagodnych warunkach i co ważne, może być zastosowany w warunkach polowych in situ. W ten sposób stanowi on ekoprzyjazną i energooszczędną technikę do wykorzystania jako ekologiczna alternatywa dla obecnie stosowanych technik w wielorakich obszarach inżynieryjnych. W obszarach tych wytrącany CaCO3 spełnia rolę czynnika remediacyjnego i cementującego, na przykład w celu (1) oczyszczania wód z jonów metali toksycznych i radionuklidów, (2) wzmacniania i konsolidacji gruntu i piasku, (3) uszczelniania formacji geologicznych, (4) naprawy obiektów budowlanych i (5) ochrony powierzchni tych obiektów warstwami ochronnymi. Choć stosowana z powodzeniem w sektorze ochrony i restauracji budowli historycznych, technika ta pozostaje ciągle na etapie badań i procesów optymalizacyjnych. By stać się w pełni niezawodną i ekonomiczną techniką wymaga ona dalszych badań, których zadaniem jest rozwiązanie ograniczeń i parametryczna optymalizacja, oraz testy w pełnowymiarowych eksperymentach polowych. Jest to zadanie interdyscyplinarne dla inżynierów budownictwa, geologów, chemików, mikrobiologów i konserwatorów zabytków, którego efektem będzie wprowadzenie tej ekoprzyjaznej i innowacyjnej techniki na rynek inżynierski do wykorzystania w inżynierii środowiska i lądowej, geotechnice i konserwacji zabytków. W kontekście ekopotencjału i innowacyjności tej techniki, w niniejszym artykule przedstawiono jej podstawy, obszary jej zastosowań oraz zalety i ograniczenia.
EN
Calcium carbonate (CaCO3) is a substance widespread in nature and used in numerous practical applications. In nature, its biomineralization relies, among others, on microbiologically induced precipitation processes. One of such processes is precipitation induced by ureolytic bacteria. If performed in a biomimetic manner, the process is carried out under mild conditions and, most importantly, can be employed in field applications in situ. Therefore, the process constitutes an eco-friendly and energy-saving technique to be used as an ecological alternative to conventional techniques in a variety of engineering fields. In these fields, CaCO3 serves as a remediating and cementing agent, for instance to (1) clean waste- and groundwater from toxic metals and radionuclides, (2) strengthen and consolidate soil and sand, (3) seal geological formations to enhance oil recovery and geologic CO2 sequestration, (4) repair stone and concrete structures, and (5) cover surfaces of these structures with protective layers. Although already in use in the sector of protection and renovation of stone monuments, to date the technique has remained mostly under research and optimization. To become fully implementable as a reliable and economically viable technique, it still requires further research in order to address its limitations, focus on parametrical optimization, up-scaling and life-size field experiments. All these, in an interdisciplinary effort of geologists, microbiologists, chemists, civil engineers and conservators of historic monuments, will move this eco-friendly and innovative branch of engineering from laboratory to field applications in the environmental and civil engineering, geotechnology and conservation of historic buildings. Given its eco-potential and innovativeness, in this study the principles of the technique, advantages, possible applications and challenges are reviewed.
Czasopismo
Rocznik
Strony
31--37
Opis fizyczny
Bibliogr. 57 poz., rys.
Twórcy
Bibliografia
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Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-77ea9adb-a1bf-4932-8f48-1e73190a40ae
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