Submitted:
04 June 2026
Posted:
05 June 2026
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Abstract
Keywords:
1. Introduction
1.1. Cultural Heritage Management and the Multi-Hazard Approach
1.2. Study Area: Çatalca and Ferhatpaşa Mosque
2. Materials and Methods
2.1. Determination of GIS-Based Multi-Hazard Criteria and Rationale for Selection
2.2. Expert Opinions and Criteria Weighting Process
2.3. Weighted Overlay Modeling
| Data | Source Institution |
|---|---|
| Boundaries of Çatalca District and Ferhatpaşa Neighborhood | Istanbul / Çatalca Cadastral Directorate |
| Digital Elevation Model (DEM) of Çatalca District | ALOS PALSAR EarthData Platform |
| Soil capability and land use | Ministry of Agriculture and Forestry, Soil, Fertilizer and Water Resources Central Research Institute |
| Fault lines | General Directorate of Mineral Research and Exploration |
| Hydrological structure | Istanbul Metropolitan Municipality, ISKI General Directorate |
| Precipitation data | Ministry of Environment, Urbanization and Climate Change, Turkish State Meteorological Service |
| Location of Ferhatpaşa Mosque and information on cultural heritage assets in Ferhatpaşa Neighborhood | Istanbul Metropolitan Municipality, Directorate of Cultural Heritage Conservation |
| Registration decisions and historical photographs of Ferhatpaşa Mosque | General Directorate of Foundations, 1st and 2nd Regional Directorates of Foundations |
3. Results
3.1. Disaster Risk Factors Affecting Ferhatpaşa Mosque
- Slope (%): 0–5, 5–10, 10–15, 15–20, 20–25, and above 25
- Aspect: east–west; south (south, southeast, southwest); north (north, northeast, northwest)
- Elevation (m): 0–50, 50–100, 100–150, 150–200, and above 200
- Precipitation (mm/year): 897.8–930; 930–960; 960–990; 990–1120; 1120–1127
- Distance to fault lines (m): 25,000–27,000; 27,000–29,000; 29,000–31,000
- Distance to hydrological structures (m): 10, 50, 90, 130, 170
- Soil capability (soil types): alluvial soils, brown forest soils, non-calcareous brown forest soils, non-calcareous brown soils, vertisols, settlement areas
- Land use: dry farming (rainfed), pasture, settlement areas
3.1.1. Slope Factor
3.1.2. Elevation Factor
3.1.3. Aspect Factor
3.1.4. Precipitation Factor
3.1.5. Distance to Fault Lines Factor
- 25,000–27,000 m
- 27,000–29,000 m
- 29,000–31,000 m
3.1.6. Distance to Hydrological Features Factor
- 10 m
- 50 m
- 90 m
- 130 m
- 170 m
3.1.7. Land Use Factor
- non-rotational dry farming areas
- pasturelands
- settlement areas
3.1.8. Soil Capability Factor
- alluvial soils
- brown forest soils
- non-calcareous brown forest soils
- non-calcareous brown soils
- vertisols
- settlement areas
3.1.9. Reclassification and Assessment of Risk Classes
3.2. Determination of Weight Values for the Factors
4. Discussion
5. Conclusions
- 71.99% as medium risk;
- 28% as low risk;
- 0.02% as high risk.
6. Patents
Author Contributions
Informed Consent Statement
Data Availability Statement
Acknowledgments
Abbreviations
| MDPI | Multidisciplinary Digital Publishing Institute |
| DOAJ | Directory of open access journals |
| TLA | Three letter acronym |
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| Selected Criterion | Relationship with Historic Buildings, Earthquakes, and Disaster Risk | Literature Reference |
|---|---|---|
| Distance to Fault Lines | Directly determines the seismic shock waves and acceleration values to which the structure may be exposed. | [13]; [14] |
| Slope and Elevation | Determine slope instability during earthquakes, including landslides, as well as the effect of topographic amplification of seismic waves. | [15] |
| Soil Capability / Soil Type | Alluvial or clayey soils, including vertisols, may amplify seismic waves and increase the risk of settlement or liquefaction during earthquakes. | [16]; [17] |
| Precipitation and Hydrological Structure | Increase the water saturation level of the soil and may intensify liquefaction, slope instability, and retaining wall failure under seismic triggering through hydro-seismic interaction. | [18]; [19] |
| Data Layer | Data Structure | Data Type |
|---|---|---|
| Slope | Raster. | Pixel |
| Elevation | Raster. | Pixel |
| Aspect | Raster. | Pixel |
| Precipitation | Raster. | Pixel |
| Land Use | Vector | Polygon |
| Soil Capability | Vector | Polygon |
| Fault Lines | Vector | Polyline |
| Hydrological Structure | Vector | Polyline |
| Parameter | Values | Disaster Risk Classification | Effect Value |
|---|---|---|---|
| Slope (%) | 0–10 | Low risk | 1 |
| 0–10 | Medium risk | 2 | |
| 20 and above | High risk | 3 | |
| Elevation (m) | 0–75 | Low risk | 1 |
| 75-150 | Medium risk | 2 | |
| 150–321 | High risk | 3 | |
| Aspect | East–West | Low risk | 1 |
| South, Southeast, Southwest | Medium risk | 2 | |
| North, Northeast, Northwest | High risk | 3 | |
| Soil Capability | Vertisols | Low risk | 1 |
| Brown forest soils | Low risk | 1 | |
| Non-calcareous brown forest soils | Medium risk | 2 | |
| Non-calcareous brown soils | High risk | 3 | |
| Alluvial soils | High risk | 3 | |
| Settlement areas | High risk | 3 | |
| Land Use | Pastureland | Low risk | 1 |
| Dry farming / rainfed agriculture | Medium risk | 2 | |
| Settlement areas | High risk | 3 | |
| Distance to Fault Lines (m) | 29,000–31,000 | Low risk | 1 |
| 27,000–29,000 | Medium risk | 2 | |
| 25,000–27,000 | High risk | 3 | |
| Distance to Hydrological Features (m) | 170 | Low risk | 1 |
| 130 | Low risk | 1 | |
| 90 | Medium risk | 2 | |
| 50 | High risk | 3 | |
| 10 | High risk | 3 | |
| Precipitation Amount (mm) | 897.8–925 | Low risk | 1 |
| 925–975 | Medium risk | 2 | |
| 975–1,027 | High risk | 3 |
| Parameter | Weight Value (%) |
|---|---|
| Distance to Fault Lines (m) | 17,22 |
| Precipitation Amount (mm) | 17,22 |
| Distance to Hydrological Features (m) | 13,89 |
| Soil Capability | 13,89 |
| Slope | 13,33 |
| Land Use | 12,78 |
| Elevation (m) | 7,78 |
| Aspect | 3,89 |
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