Your search keyword '"Jernej Jež"' showing total 11 results

1. Paraglacial adjustment of alluvial fans to the last deglaciation in the Snežnik Mountain, Dinaric karst (Slovenia)

Author

Silke Mechernich, Branko Mušič, Petra Jamšek Rupnik, Manja Žebre, Jernej Jež, and Barbara Horn

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Alluvial fan, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, Surface exposure dating, Paraglacial, Moraine, Aggradation, Deglaciation, Glacial period, Physical geography, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Glaciokarst depressions are major glacigenic depocenters in the Dinaric mountain karst areas and often store important information about the timing and nature of glacial processes and paraglacial sediment reworking. This study focuses on Praprotna draga, which is one of the largest glaciokarst depressions in the Snežnik Mountain (Dinaric karst), with an area of ~3.4 km2 and a maximum depth of 140 m. The western slopes of the depression are characterized by undulated moraine morphology and alluvial fans are filling its entire floor. We present the results on the thickness, origin and age of the sediment infill using a complementary geomorphological, sedimentological, geophysical and dating approach. Distribution of moraines point to two glacial advances that were associated with two main alluvial fan aggradation phases recognized using the electrical resistivity tomography measurements. The youngest alluvial deposits were sampled for cosmogenic 36Cl analysis using amalgamated carbonate pebbles. The depth profile of 36Cl concentrations suggests an age of 12.3 ± 1.7 ka when assuming a likely denudation rate of 20 mm ka−1. Since the existence of the Younger Dryas glaciers in the study area is climatically difficult to explain, we tentatively propose that the youngest alluvial deposition in Praprotna draga took place after the glacier retreat during the paraglacial period. Our findings suggest that the time window of paraglacial adjustment in the Snežnik Mountain was brief and likely conditioned by quick recolonization with vegetation and inefficient surface runoff on deglaciated karst terrain.

Published

2019

2. Engineering-geological conditions of landslides above the settlement of Koroška Bela (NW Slovenia)

Author

Mateja Jemec Auflič, Tina Peternel, Blaž Milanič, Anže Markelj, and Jernej Jež

Subjects

landslide, QE1-996.5, debris flw, 010504 meteorology & atmospheric sciences, debris fow, Settlement (structural), Koroška Bela Čikla, Paleontology, Geology, Landslide, 010501 environmental sciences, Bela stream, 01 natural sciences, Archaeology, Geophysics, Čikla, engineering-geological mapping, geotechnical monitoring, Urbas, 0105 earth and related environmental sciences

Abstract

This paper focuses on the studying of landslides in the hinterland area of the Koroška Bela settlement, NW Slovenia. Research has shown that these landslides have the potential to mobilize the material into a debris flw. The area of interest is located on the Karavanke mountain ridge, above the settlement of Koroška Bela, which lies on the outskirts of the town of Jesenice. In order to recognize and understand the kinematics of landslides and their triggering mechanisms, a multidisciplinary approach using engineering-geological and geotechnical investigations was applied. Thus, landslide source areas were determined based on engineering-geological mapping. Furthermore, landslide boundaries, types of landslides and sediments that are involved in processes of sliding were mapped in detail. Geotechnical monitoring is benefiial in evaluating rates of movement and failures in the ground under real conditions in the fild. Current investigations as well as historical evidence and previous research prove that the hinterland of Koroška Bela is prone to various types of landslides that together form a source area that has the potential to mobilize into larger debris flw.

Published

2018

3. Database of Active Faults in Slovenia: Compiling a New Active Fault Database at the Junction Between the Alps, the Dinarides and the Pannonian Basin Tectonic Domains

Author

Bogomir Celarc, Jure Atanackov, Petra Jamšek Rupnik, Blaž Milanič, Miloš Bavec, Jernej Jež, Matevž Novak, Vanja Kastelic, and Anže Markelj

Subjects

Eastern Alps, 010504 meteorology & atmospheric sciences, Mass movement, Science, Active fault, Fault (geology), 010502 geochemistry & geophysics, computer.software_genre, 01 natural sciences, Dinarides, active faults, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Database, seismic hazard, Tectonics, Seismic hazard, Denudation, geologic data input, Data quality, Geological survey, General Earth and Planetary Sciences, computer, Geology, Southern Alps

Abstract

We present the compilation of a new database of active faults in Slovenia, aiming at introducing geological data for the first time as input for a new national seismic hazard model. The area at the junction of the Alps, the Dinarides, and the Pannonian Basin is moderately seismically active. About a dozen Mw > 5.5 earthquakes have occurred across the national territory in the last millennium, four of which in the instrumental era. The relative paucity of major earthquakes and low to moderate fault slip rates necessitate the use of geologic input for a more representative assessment of seismic hazard. Active fault identification is complicated by complex regional structural setting due to overprinting of different tectonic phases. Additionally, overall high rates of erosion, denudation and slope mass movement processes with rates up to several orders of magnitude larger than fault slip rates obscure the surface definition of faults and traces of activity, making fault parametrization difficult. The presented database includes active, probably active and potentially active faults with trace lengths >5 km, systematically compiled and cataloged from a vast and highly heterogeneous dataset. Input data was mined from published papers, reports, studies, maps, unpublished reports and data from the Geological Survey of Slovenia archives and dedicated studies. All faults in the database are fully parametrized with spatial, geometric, kinematic and activity data with parameter descriptors including data origin and data quality for full traceability of input data. The input dataset was compiled through an extended questionnaire and a set of criteria into a homogenous database. The final database includes 96 faults with 240 segments and is optimized for maximum compatibility with other current maps of active faults at national and EU levels. It is by far the most detailed and advanced map of active faults in Slovenia.

Published

2021

4. Monitoring Surface Displacement of a Deep-Seated Landslide by a Low-Cost and Near Real-Time GNSS System

Author

Angelo Consoli, Jernej Jež, Andrea Gatti, Eugenio Realini, Mateja Jemec Auflič, Tina Peternel, Tilen Urbančič, Giulio Tagliaferro, Joaquín Reyes González, Matija Zupan, Stefano Caldera, and Ela Šegina

Subjects

landslide, 010504 meteorology & atmospheric sciences, Slovenia, 0211 other engineering and technologies, Satellite system, remote sensing, landslide, GNSS, classic geodetic measurement, Slovenia, 02 engineering and technology, Processing, remote sensing, GNSS, classic geodetic measurement, 01 natural sciences, Displacement (vector), zemeljski plazovi, Slovenija, lcsh:Science, 0105 earth and related environmental sciences, computer.programming_language, Remote sensing, 021110 strategic, defence & security studies, geodetske meritve, business.industry, Geodetic datum, Landslide, Surface displacement, GNSS applications, daljinsko zaznavanje, General Earth and Planetary Sciences, udc:528:504.4(497.4), The Internet, lcsh:Q, business, computer, Geology

Abstract

A prototype of a low-cost GNSS (Global Navigation Satellite System) monitoring system was installed on a deep-seated landslide in north-western Slovenia to test its performance under field conditions. The system consists of newly developed GNSS stations based on low-cost, dual-frequency receivers and open-source GNSS processing software. It automatically receives GNSS data and transmits them over the Internet. The system processes the data server-side and makes them available to the end user via a web portal. The detected surface displacements were evaluated through a comparison with the network of classic geodetic measurements. The results of a nine-month monitoring period using seven GNSS stations provided a detailed insight into the spatial and temporal pattern of deep-seated landslide surface movements. The displacement data were correlated with precipitation measurements at the site to reveal how different parts of the landslide react to rainfall. These data form the basis for the further development of an early-warning system which will help to manage the risk the landslide poses to the local population and infrastructure.

Published

2020

5. Application of a mass movement susceptibility model in the heterogeneous Miocene clastic successions of the Slovenj Gradec Basin, northeast Slovenia

Author

Jernej Jež, Špela Kumelj, Kristina Ivančič, Blaž Milanič, and Andrej Šmuc

Subjects

021110 strategic, defence & security studies, education.field_of_study, geography, geography.geographical_feature_category, Mass movement, Lithology, Geography, Planning and Development, Population, 0211 other engineering and technologies, Landslide, 02 engineering and technology, Structural basin, 010502 geochemistry & geophysics, 01 natural sciences, Paleontology, Rockfall, Clastic rock, General Earth and Planetary Sciences, education, Spatial planning, Geology, 0105 earth and related environmental sciences

Abstract

In Slovenia, mass movements are not only a threat to the population, but also a major environmental and social science challenge. Lithologically heterogeneous areas have been found to be problematic, and the Miocene Slovenj Gradec basin (in northeast Slovenia) is one such area. For this area, we developed landslide and rockfall susceptibility maps based on detailed geological research combined with statistical modeling schemes. Crucial factors include lithological composition, land use, geological structural elements, slope curvature, aspect and inclination, and bed dipping. The approach taken in the development of mass movement susceptibility maps presented here is transferable to other areas defined by heterogeneous lithology. Such maps could prove useful spatial planning, forestry, environmental protection, landscape architecture, and other fields.

Published

2020

6. The variety of landslide forms in Slovenia and its immediate NW surroundings

Author

Janko Logar, Matej Maček, Chiara Boccali, Luca Zini, Matjaž Mikoš, Timotej Verbovšek, Mateja Jemec Auflič, Ana Petkovšek, Tomislav Popit, Adrijan Košir, Chiara Calligaris, Jernej Jež, Jürgen M. Reitner, Jemec Auflič, Mateja, Jež, Jernej, Popit, Tomislav, Košir, Adrijan, Maček, Matej, Logar, Janko, Petkovšek, Ana, Mikoš, Matjaž, Calligaris, Chiara, Boccali, Chiara, Zini, Luca, Reitner, Jürgen M., and Verbovšek, Timotej

Subjects

Rainfall, 010504 meteorology & atmospheric sciences, Post-Forum Study Tour, Slovenia, 0211 other engineering and technologies, Landslide form, 4th World Landslide Forum 2017, 02 engineering and technology, Fault scarp, 01 natural sciences, Debris flow, Rockfall, Natural hazard, Geological setting, Geomorphology, Landslide forms, Geotechnical Engineering and Engineering Geology, 0105 earth and related environmental sciences, 021110 strategic, defence & security studies, geography, geography.geographical_feature_category, Landslide, Rockslide, Debris, Mudflow, Physical geography, Geology

Abstract

The Post-Forum Study Tour following the 4th World Landslide Forum 2017 in Ljubljana (Slovenia) focuses on the variety of landslide forms in Slovenia and its immediate NW surroundings, and the best-known examples of devastating landslides induced by rainfall or earthquakes. They differ in complexity of the both surrounding area and of the particular geological, structural and geotechnical features. Many of the landslides of the Study Tour are characterized by huge volumes and high velocity at the time of activation or development in the debris flow. In addition, to the damage to buildings, the lives of hundreds of people are also endangered; human casualties occur. On the first day, we will observe complex Pleistocene to recent landslides related to the Mesozoic carbonates thrust over folded and tectonically fractured Tertiary siliciclastic flysch in the Vipava Valley (SW Slovenia), serving as the main passage between the Friulian lowland and central Slovenia, and thus also an important corridor connecting Northern Italy to Central Europe. A combination of unfavourable geological conditions and intense short or prolonged rainfall periods leads to the formation of different types of complex landslides, from large-scale deep-seated rotational and translational slides to shallow landslides, slumps and sediment gravity flows in the form of debris or mudflows. The second day of the study tour will be held in the Soča River Valley located in NW Slovenia close to the border with Italy, where the most catastrophic Stože landslide in Slovenia recently caused the deaths of seven people, and the nearby Strug landslide, which is a combination of rockfall, landslide and debris flow. The final day of the Post-Forum Study Tour will start in the Valcanale Valley located across the border between Slovenia and Italy, severely affected by a debris flow in August 2003. The flow caused the deaths of two people, damaged 260 buildings; large amounts of deposits blocked the A23 Highway, covering both lanes. In Carinthia (Austria), about 25 km west of Villach, the Dobrač/Dobratsch multiple scarps of prehistoric and historic rockslides will be observed. Dobratsch is a massive mountain ridge with a length of 17 km and a width of 6 km, characterized by steep rocky walls. The 3-day study tour will conclude with a presentation of the Potoška planina landslide, a slide whose lower part may eventually generate a debris flow and therefore represents a hazard for the inhabitants and for the infrastructure within or near the village of Koroška Bela.

Published

2017

7. Reconstruction of landslide activity using dendrogeomorphological analysis in the Karavanke mountains in NW Slovenia

Author

Jernej Jež, Milan Kobal, Tomislav Levanič, and Domen Oven

Subjects

Return period, 010504 meteorology & atmospheric sciences, indeks ekscentričnosti, media_common.quotation_subject, zemeljski plaz, ekscentričnost branik, 010502 geochemistry & geophysics, 01 natural sciences, digitalni model terena, Multivariate interpolation, eccentricity index, dendrogeomorphology, Dendrochronology, udc:630*58:630*56:630*81(497.4Karavanke)(045)=111, prostorska interpolacija, Eccentricity (behavior), Digital elevation model, 0105 earth and related environmental sciences, media_common, geography, geography.geographical_feature_category, biology, landslide activity, tree ring eccentricity, Forestry, Landslide, Picea abies, biology.organism_classification, Karst, digital terrain model, dendrogeomorfologija, Physical geography, spatial interpolation, Geology

Abstract

Tree ring eccentricity was used to reconstruct landslide activity in the last 138 years in the Urbas landslide located at Poto&scaron, ka planina in the NW part of the Karavanke Mountains, Slovenia. The research was based on the dendrochronological sampling of Norway spruce (Picea abies (L.) Karst.) in areas of varying landslide intensity. Analysis of a sudden change in the eccentricity index of 82 curved trees concluded that there were 139 growth disturbances and 16 landslide reactivations between 1880 and 2015, with a landslide return period of 8.5 years. Using lidar data, changes in the surface of the digital terrain model (DTM) were compared with changes in the eccentricity index of trees at the same location in the period 2014&ndash, 2017. On the basis of temporal changes in the eccentricity index and by using spatial interpolation, landslide activity was reconstructed for the period 1943&ndash, 2015. During this period, landslide intensity increased in the central part of the landslide. Although categorization into seven categories of different stem curvature was proposed, no distinction between categories with respect to their eccentricity index was found.

Published

2019

8. Landslide databases in the Geological Surveys of Europe

Author

Michaela Frei, Vedad Demir, Tatiana-Constantina Filipciuc, Hugo Raetzo, Michael Sheehy, Eleftheria Poyiadji, Mateja Jemec Auflič, Arben Kociu, Veronika Kopackova, Maria Przyłucka, Gilles Grandjean, Xavier M. Pellicer, Rosa María Mateos, Reginald L. Hermanns, Niki Koulermou, Claire Dashwood, Juan Carlos García-Davalillo, Charise McKeown, Vidas Mikulėnas, Jernej Jež, Graham Ryan, Balazs Fusi, Marta González, Pere Buxó, Peter Pauditš, Lídia Maria Quental, Margus Raha, Laszlo Podolszki, Odd Are Jensen, Helen Reeves, Marcin Kułak, Colby A. Smith, Pavel Liscak, Raluca Maftei, Carla Iadanza, Francesca Cigna, Cvjetko Sandić, Alessandro Trigila, Gerardo Herrera, Dirk Kuhn, Mats Engdahl, EuroGeoSurvey, Geological Survey of Spain, Bureau de Recherches Géologiques et Minières (BRGM) (BRGM), Institute of geology and mineral exploration - Athens (IGME), IGME, Natural Hazard Department, Geological Institute of Romania, Geological Survey of Slovenia, Hrvatski Geološki Institut - Croatian Geological Survey (HGI), Istituto Superiore per la Protezione e la Ricerca Ambientale (ISPRA), Swiss Federal Insitute of Aquatic Science and Technology [Dübendorf] (EAWAG), Geological Survey of Austria, Depart. of Engineering Geology, Polish Geological Institute = Państwowy Instytut Geologiczny (PIB), Geological Survey of Ireland, Czech Geological Survey [Praha], Federal Institute for Geosciences and Natural Resources (BGR), Geological Survey of Norway (NGU), Cyprus Geological Survey, Geological Survey of Sweden, Institut Cartografic de Catalunya, British Geological Survey (BGS), Geological Survey Slovakia, Geological Survey Lithuania, Federal Institute for Geology, Geological Survey Estonia, Lab Nacl Energia & Geol, Geol Survey Republ Srpska, Mining and Geological Survey of Hungary, and Norwegian Water Resources and Energy Directorate (NVE)

Subjects

010504 meteorology & atmospheric sciences, Landslide classification, 0211 other engineering and technologies, [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, Harmonization, 02 engineering and technology, computer.software_genre, 01 natural sciences, Landslides, Europe, Legal framework, Natural hazard, 11. Sustainability, Population growth, Economic impact analysis, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences, landslides, 021110 strategic, defence & security studies, Database, Landslide, Geotechnical Engineering and Engineering Geology, legal framework, Europe, Identification (information), Geography, [SDU]Sciences of the Universe [physics], Scale (map), computer, Cartography

Abstract

Acceso electrónico sólo desde el IGME, Landslides are one of the most widespread geohazards in Europe, producing significant social and economic impacts. Rapid population growth in urban areas throughout many countries in Europe and extreme climatic scenarios can considerably increase landslide risk in the near future. Variability exists between European countries in both the statutory treatment of landslide risk and the use of official assessment guidelines. This suggests that a European Landslides Directive that provides a common legal framework for dealing with landslides is necessary. With this long-term goal in mind, this work analyzes the landslide databases from the Geological Surveys of Europe focusing on their interoperability and completeness. The same landslide classification could be used for the 849,543 landslide records from the Geological Surveys, from which 36% are slides, 10% are falls, 20% are flows, 11% are complex slides, and 24% either remain unclassified or correspond to another typology. Most of them are mapped with the same symbol at a scale of 1:25,000 or greater, providing the necessary information to elaborate European-scale susceptibility maps for each landslide type. A landslide density map was produced for the available records from the Geological Surveys (LANDEN map) showing, for the first time, 210,544 km2 landslide-prone areas and 23,681 administrative areas where the Geological Surveys from Europe have recorded landslides. The comparison of this map with the European landslide susceptibility map (ELSUS 1000 v1) is successful for most of the territory (69.7%) showing certain variability between countries. This comparison also permitted the identification of 0.98 Mkm2 (28.9%) of landslide-susceptible areas without records from the Geological Surveys, which have been used to evaluate the landslide database completeness. The estimated completeness of the landslide databases (LDBs) from the Geological Surveys is 17%, varying between 1 and 55%. This variability is due to the different landslide strategies adopted by each country. In some of them, landslide mapping is systematic; others only record damaging landslides, whereas in others, landslide maps are only available for certain regions or local areas. Moreover, in most of the countries, LDBs from the Geological Surveys co-exist with others owned by a variety of public institutions producing LDBs at variable scales and formats. Hence, a greater coordination effort should be made by all the institutions working in landslide mapping to increase data integration and harmonization., Earth Observation and Geohazards Expert Group (EOEG), EuroGeoSurveys, the Geological Surveys of Europe, Bélgica, Geohazards InSAR Laboratory and Modeling Group, Instituto Geológico y Minero de España, España, Risk and Prevention Division, Bureau de Recherches Géologiques et Minières, Francia, Engineering Geology Department, Institute of Geology and Mineral Exploration, Grecia, GeoHazard team, Geological Institute of Romania, Rumanía, Geological Survey of Slovenia, Eslovenia, Croatian Geological Survey, Croacia, Italian Institute for Environmental Protection and Research, Geological Survey of Italy, Italia, Swiss Federal Office for the Environment, Suiza, Geological Survey of Austria, Austria, Polish Geological Institute, National Research Institute, Polonia, Geological Survey of Ireland, Irlanda, Czech Geological Survey, República Checa, Federal Institute for Geosciences and Natural Resources, Alemania, Geological Survey of Norway, Noruega, Cyprus Geological Survey, Chipre, Geological Survey of Sweden, Suecia, Institut Cartogràfic i Geològic de Catalunya, España, British Geological Survey, Reino Unido, Geological Survey of Slovakia, Eslovaquia, Geological Survey of Lithuania, Lituania, Federalni zavod za geologiju, Bosnia y Herzegovina, Geological Survey of Estonia, Estonia, Laboratório Nacional de Energia e Geologia, Portugal, Geological Survey of Hungary, Hungría, Norwegian Water and energy Directorate of Norway, Noruega

Published

2018

9. TXT-tool 1.386-2.1 Landslide Susceptibility Assessment Method

Author

Jernej Jež and Marko Komac

Subjects

010504 meteorology & atmospheric sciences, Computer science, Landslide, Statistical model, Landslide susceptibility, 010502 geochemistry & geophysics, computer.software_genre, 01 natural sciences, Hazard, Field (geography), Assessment methods, Data mining, Scale (map), computer, Spatial planning, 0105 earth and related environmental sciences

Abstract

A method was developed for the susceptibility estimation of different landslide types, and tested in the Bovec municipality, NW Alpine Slovenia. The purpose of the susceptibility maps, at the 1:25,000 scale, is to be used in spatial planning by the local municipality to minimize potential landslide hazard. The requirements taken into account were the following: expert approach, GIS tools support, reasonable production time, and the product being simple to read and understand. The elaboration of the final products comprises four phases, the first three of which are desktop phases: (1) synthesis of archive data, (2) probabilistic model of landslide susceptibility, (3) compilation of phases 1 and 2 into the final map at the 1:25,000 scale. The fourth phase consists of field reconnaissance of areas considered most hazardous.

Published

2017

10. Mass Movement Processes of Quaternary Deposits in the Vipava Valley, SW Slovenia

Author

Jernej Jež, Tomislav Popit, and Timotej Verbovšek

Subjects

021110 strategic, defence & security studies, Mass movement, Pleistocene, 0211 other engineering and technologies, 02 engineering and technology, 010502 geochemistry & geophysics, Spatial distribution, 01 natural sciences, Paleontology, Tectonics, Sedimentary rock, Quaternary, Geomorphology, Geology, Holocene, 0105 earth and related environmental sciences

Abstract

Slope sediments of the Vipava Valley represent a complex sedimentary system deposited by very different mechanisms of transport and sedimentary processes that are controlled by a specific lithological and tectonic structure as well as climate conditions of the valley. Varying intensities and dynamics of mass movement processes in this area during the recent geological history (late Pleistocene and early Holocene) influenced the spatial distribution of slope sediments.

Published

2017

11. Geology of the Classical Karst Region (SW Slovenia–NE Italy)

Author

Franco Cucchi, Stefano Furlani, Miloš Bavec, Giorgio Tunis, Bogdan Jurkovšek, Luca Zini, Sara Biolchi, Tea Kolar-Jurkovšek, Jernej Jež, Jurkovšek, Bogdan, Biolchi, Sara, Furlani, Stefano, Kolar Jurkovšek, Tea, Zini, Luca, Jež, Jernej, Tunis, Giorgio, Bavec, Miloš, and Cucchi, Franco

Subjects

Planning and Development, 010506 paleontology, geography, Classical Karst, geography.geographical_feature_category, Scale (ratio), Geography, Geography, Planning and Development, Slovenia, Dinaride, Geology, Kras–Carso, 010502 geochemistry & geophysics, Karst, 01 natural sciences, Cross-border cooperation, Work (electrical), Italy, Dinarides, Earth and Planetary Sciences (miscellaneous), Physical geography, 0105 earth and related environmental sciences

Abstract

The paper aims to present the geology of the western part of the Classical Karst (NW Dinarides), located at the border between Slovenia and Italy. The work is based on archive, published and new data collected by Slovenian and Italian researchers within several scientific national and Cross Border Cooperation projects. The map, produced at a scale of 1:50,000, summarizes the lithological and structural setting and is supplemented by three geological cross-sections of the study area.

Published

2016