99 research outputs found

    Global climate change and effects on soil, crop productivity and water resources

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    Soil micromorphology for construction science: the mortar archaeometry

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    Micromorphology revealed in depth evaluation of materials particularly soil micromorphology yielded numerous data on processes such as formation, neoformation and transformation of minerals and microstructure in soils, pottery and construction materials. Mortars, one of the first human made materials for construction of Byzantine and the Ottoman worlds were compared in terms of micromorphology and mineralogy

    Central Anatolian terrestrial sand dunes: enhancing carbon sequestration by indigenous vegetation

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    Assessment of the changes in natural resource quality requires long term monitoring. This study outlines the changes achieved in soils and vegetation quality in a sand dune area of Central Turkey maintained since 1960s

    Polygenetic evolution and bioturbation: micromorphological study of a Terra Rossa soil in a traditional olive crop (Sardinia, Italy)

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    The origin of Mediterranean red soils has been the subject of numerous studies. Complex genetic processes, and massive inputs of allochtonous materials such as wind-blown Saharan dust and volcanic ashes, have been advocated to interpret their genesis. The present study was carried out in a traditional olive grove nearby Sassari (Sardinia, Italy), where the land use remained unchanged for the last 150 years, on Terra Rossa developed on Miocene marine limestone

    Paleoenvironmental implications through the study of an Eemian paleosol in northwestern Sardinia (Italy)

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    The aim of this work is to define the paleoenvironmental changes related to a soil belonging to the studied succession, by means of an in-depth micromorphological study. In particular, the presence of this paleosol is associated to the fast climatic fluctuations that took place between MIS5e and MIS5c

    Mikro-korozija stalagmita v jami Küpeli, južna Turčija

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    This article deals with micro-karstification forming abundant dissolution features in a stalagmite from Küpeli Cave in southern Turkey. Dissolution occurs when cave water enriched with CO2 from the atmosphere and soil seeps into the stalagmite. Water is transmitted from the surface of the stalagmite to the interior by the roughly vertical or diagonal notch-shaped pores formed by the enlargement of intercrystalline pores by dissolution. These slightly elongated pores appear embedded in different parts of the stalagmite and characterize different stages of dissolution during the stalagmite formation. Later, when this water reaches the relatively more permeable growth layer surfaces, it flows along these surfaces, and diffuse dissolution features form. These features include micro-scale pitted and etched surface structures, rounded and enlarged crystal boundaries and intercrystalline pores, and the breakdown of relatively large crystals into small crystals (micritization). When the percolating water is sufficiently saturated with calcium carbonate in the stalagmite, secondary calcite precipitation occurs as rim and pore-filling cements within the pores formed as a result of dissolution. In general, dissolution and calcite re-precipitation as cement are early diagenetic events and occur at different stages of stalagmite development due to seasonal variation in CO2 and CaCO3 contents of the water in the epikarst zone and within the stalagmite. These conditions were probably provided during the wet season.  V članku obravnavamo mikro-korozijske oblike v stalagmitu iz jame Küpeli v južni Turčiji. Korozijo kapnikov lahko povzroča prenikla voda, ki se  v tleh, epikrasu ali jamski atmosferi obogati  s CO2 in pronica v kapnik. V članku postavimo domnevo, da je voda iz nekdanje površine stalagmita prodrla v notranjost vzdolž vertikalnih in diagonalnih por zarezne oblike, ki so nastale s korozivnim širjenjem medkristalnih por. Te podolgovate pore so precej naključno nastajale ob cikličnih pogojih rasti stalagmita in segajo nekaj rastnih plasti globoko pod površino stalagmita, ki jo je kasneje prekrila nova plast sige. Voda je ob pronicanju vzdolž teh por dosegla relativno bolj prepustno rastno ploskev in korodirala vzdolž le-te.  Pri tem so nastale različne mikro-korozijske oblike, kot so korozijske jamice,  zaobljene in povečane kristalne meje, medkristalne pore in nanometrski kristalni skupki, ki so nastali ob porušitvi večjih kristalov ((≥ 4 μm). V korozijskih porah se je kasneje na nekaterih mestih iz prenasičene vode ponovno izločal kalcit, bodisi zgolj na robovih por bodisi kot polnilo por. V cikličnih pogojih rasti je izločanje praviloma sledilo raztapljanju, verjetno zaradi sezonske spremenljivosti dostopnega  CO2 in v vodi raztopljenega kalcita
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