Keywords:
Geography
;
Earth Sciences
;
Regional planning
;
Geotechnical engineering.
;
Urban planning.
;
Urban geography.
;
Geography
;
Regional planning
Description / Table of Contents:
Part I Keynote -- Part II Aggregates: The Most Widely Used Raw Material -- Part III Analysis and Control of Ground Deformations by Remote Monitoring -- Part IV Building Stones & Ornamental Rocks—Resource Evaluation, Technical Assessment, Heritage Designation -- Part V Communicating Engineering Geology with Urban Planners -- Part VI Complexity in Hazard and Risk Assessment -- Part VII Engineering Geology in Rural Infrastructure Planning -- Part VIII Engineering Problems in Karst -- Part IX Excavation in Potentially Asbestos-Bearing Rocks: Methodologies for Risk Evaluation and Safety Management -- Part X Experiences and Potentialities of Data-Driven Modeling in Earth Science Issues -- Part XI Geohazard in Urban Scenarios: Forcasting and Protective Monitoring -- Part XII Geo-Hydrological Risk and Town and Country Planning -- Part XIII Landslide and Flood Hazard in Urban Areas: Assessment, Monitoring and Mitigation Strategies -- Part XIV Mapping Urban Subsurface for Geohazard Assessment and Risk Management -- Part XV Off-Fault Coseismic Surface Effects and Their Impact in Urban Areas -- Part XVI Remote Sensing Applications for the Detection, Monitoring, Modeling, and Damage Assessment of Critical Structures and Complex -- Part XVII Surface Fault-Rupture Hazard in Urban Areas -- Part XVIII The Seismic Microzonation: Input Data, Methodology, and Impact on Planning -- Part XIX Underground Urban Development -- Part XX Urban and Land Planning Versus Risks Resilient Management -- Part XXI Contruction Materials -- Part XXII Aquifer Vulnerability and Springs/Wells Protection Zones.
Type of Medium:
Online Resource
Pages:
Online-Ressource (XXXV, 1400 p. 748 illus., 616 illus. in color, online resource)
ISBN:
9783319090481
Series Statement:
SpringerLink
URL:
https://doi.org/10.1007/978-3-319-09048-1
URL:
http://dx.doi.org/10.1007/978-3-319-09048-1
URL:
https://swbplus.bsz-bw.de/bsz414023498cov.jpg
DOI:
10.1007/978-3-319-09048-1
Language:
English
Note:
Description based upon print version of record
,
Foreword; Preface; Contents; Consiglio Nazionale delle RicercheIstituto di Ricerca per laProtezione Idrogeologica; Part IKeynote; 1Urban Landslides: Challenges for Forensic Engineering Geologists and Engineers; Abstract; 1.1 Introduction 1.2 Studying Urban Landslides; 1.3 Development of Inventory and Susceptibility Maps: Portland, Oregon Example; 1.4 Reactivation of Ancient Landslides; 1.5 Control of Water; 1.7 Conclusions; 1.6 Importance of Lidar; References; 2Large-Scale Thematic Geological Mapping of Moscow Area; Abstract; Keywords; 2.1 Introduction; 2.2 Geoenvironmental Conditions
,
of Moscow Territory2.4 Conclusion; 2.3 Engineering Geological Zoning; of Moscow Territory; References; 3Remote Sensing Role in Emergency Mapping for Disaster Response; Abstract; Keywords; 3.1 Introduction; 3.2 Satellite Remote Sensing; and Emergency Mapping; 3.3 Overcoming Satellite Imagery; Limitations; References; 3.4 Conclusions; 4Underground Urban Development: An Overview; Abstract; Keywords; 4.1 Economic Factors; 4.2 Environmental Factors; 4.3 (Geo-)technological Factors; 4.4 Legislative Factors; 4.5 Challenges, Perspectives; and Conclusions; References
,
Part IIAggregates: The Most Widely Used Raw MaterialAggregates: The Most Widely Used Raw MaterialAggregates: The Most Widely Used Raw MaterialAggregates: The Most Widely Used Raw MaterialAggregates: The Most Widely Used Raw MaterialAggregates: The Most Widely Used Raw MaterialAggregates: The Most Widely Used Raw Material5A Study of Fine Aggregate Properties and Their Effect on the Quality of Cementitious Composite Materials; Abstract; Keywords; 5.1 Introduction; 5.2 Materials and Methodology; 5.3 Results and Discussion; 5.4 Conclusions; References
,
6Assessment of Concrete Aggregate for ASR Potential by Petrography. The Work Developed by RILEM TC-ACS (2007-2013)Abstract; Keywords; 6.1 Introduction; 6.3 Results; 6.2 Materials and Methods; 6.4 Conclusions; References; 7Environmental Impact and Sustainability in Aggregate Production and Use; Abstract; Keywords; 7.1 Introduction; 7.2 Aggregates and Sustainability; 7.4 Life Cycle Thinking and Tools; in the Aggregate BAC; 7.3 A Best Available Concept for Aggregate; Production and Use; 7.5 Conclusions and Recommendations
,
8Contrast Behavior of Sandstone from Mount Nemrut (Adiyaman-Turkey) After the Accelerated Weathering TestsAbstract; Keywords; 8.1 Introduction; 8.2 Engineering Geological Properties; of the Sandstone; References; 8.3 Discussion and Conclusion; 9The ReAVA Project: Assessment of the Potential Alkali-Reactivity of Volcanic Aggregates from Azores Islands; Abstract; Keywords; 9.1 Introduction; 9.2 Materials 9.4 Results; 9.3 Methods for Assessment an Analysis; 9.5 Discussion; 9.6 Conclusions; References; 10Potential Reactivity to Alkalis of Portuguese Volcanic Aggregates for Concrete; Abstract
,
Keywords
Permalink