Linking Remote Sensing and Geodiversity and Their Traits Relevant to Biodiversity—Part I: Soil Characteristics
Abstract
:1. Introduction
- Discuss approaches to monitor geodiversity and its traits (geotraits) with RS,
- Define geodiversity and its characteristics,
- Explain the concepts of spectral traits (ST) and the spectral trait variation (STV) approach applicable for monitoring issues,
- Present the state-of-the-art technologies and capabilities of monitoring geodiversity and traits remotely, including: Soil characteristics (mineralogical characterization, pedology, and soil moisture) with different RS sensors, and
- Provide a concise overview of those geo-traits that can be monitored using RS.
2. Understanding Geodiversity
- (I)
- Geo-genesis diversity - GGD (which is described by the geo-genesis concept - GGC) represents the diversity of the length of evolutionary pathways, linked to a given set of geo-taxa. Therefore, geo-taxa sets that maximize the accumulation of geo-functional diversity are identified.
- (II)
- Geo-taxonomic diversity - GTD (which is described by the geo-taxonomic concept, GTaxC) - is the diversity of geo-components that differ from a taxonomic perspective.
- (III)
- Geo-structural diversity - GSD (which is described by the geo-structural concept, GSC) - is the diversity of composition or configuration of 2D to 4D geo-components.
- (IV)
- Geo-functional diversity - GFD (which is described by the geo-functional concept, GFC) - is the diversity of geo-functions and processes as well as their intra- and inter-specific interactions.
- (V)
- Geo-trait diversity - GTD (which is described by the geo-trait concept, GTC) - represents the diversity of biogeochemical, bio-/geo-optical, chemical, physical, morphological, structural, textural, or functional characteristics of geo-components that affect, interact with, or are influenced by the geo-genesis diversity, the geo-taxonomic diversity, the geo-structural diversity, or the geo-functional diversity.
3. Approach for Monitoring Geodiversity by RS
4. Trends in Air- and Spaceborne RS for Assessing Soil Characteristics
4.1. Characterization of Soil Diversity and Soil Traits by RS
4.1.1. Mineralogical Characterization by RS
4.1.2. Pedology
4.2. Soil Moisture by RS
4.2.1. Soil Moisture Characteristics using Active and Passive Microwave RS Approaches
4.2.2. Active Microwave Sensors (RADAR, Scatterometers)
4.2.3. Passive Microwave Sensors
4.2.4. Combining Active and Passive Microwave Sensors
4.2.5. Direct and Indirect Measurements by Optical and Thermal Sensors
4.2.6. Airborne Geophysical Sensors of Natural Radiation-Gamma and Cosmic-Ray Neutron Sensors
4.2.7. Surface and Soil Moisture Characterization by Land Surface Temperature RS Approach
5. Conclusions and Further Requirements in Monitoring Geodiversity
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Mission/Sensor/ Platform UAV 1 Airborne 2 Spaceborne 3 | Sensor Type | Spectral Resolution Spectral Bands/Frequency | Spatial Resolution [m] | References |
---|---|---|---|---|
Clay Content | ||||
Landsat 5 TM 3 Landsat 7 ETM+ 3 | Multispectral/TIR | 0.45–12.5 μm/8 | L5:30/120 L7:30/60 | [68] |
Landsat 8 OLI/TIRS 3 | Multispectral/TIR | 0.43–2.3 μm/8 10.6–12.51 μm/2 | 30/100 | [68] |
Terra ASTER 3 | Multispectral/TIR | 0.52–9.2 μm/9 8.12–11.65 μm/5 | 30/90 | [68,80,85] |
Sentinel–2 MSI 3 | Multispectral | 0.40 3.0 μm/13 | 10/20/60 | [68] |
IKONOS OSA3 | Multispectral | 0.45–0.85 μm/4 | 4 | [152] |
AHS 2 | Hyperspectral | 0.43–12.7 μm/~80 | ~2 | [88] |
AisaDUAL 2 | Hyperspectral | 0.40–2.45 μm/~200–400 | ~1–5 | [68,151] |
AisaOWL 2 | Hyperspectral Longwave Infrared (LWIR) | 7.7–12.0 μm/~100 | ~2 | [89,90] |
AVNIR 2 | Hyperspectral | 0.43–1.01 μm/~60 | ~1.20 | [153] |
AVIRIS 2 | Hyperspectral | 0.37–2.45 μm/~200 | ~18 | [67,154] |
DAIS-7915 2 | Hyperspectral | 0.40–2.50 μm/~72 | ~8 | [130] |
EnMAP 2 (simulated) | Hyperspectral | 0.42–2.45 μm/~250 | 30 | [155] |
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [84,115,116,117,123,131,156] |
HySpex 2 | Hyperspectral | 0.40–2.45 μm /~200–400 | ~1–5 | [157] |
HyperSpecTIR 2 | Hyperspectral | 0.40–2.45 μm/~178 | ~2.5 | [158] |
TASI-600 2 | Thermal Airborne Spectrographic Imager | 8.0–11.4 μm/~32 | ~1–5 | [84,85] |
SEBASS 2 | Hyperspectral Thermal Infrared (TIR) Sensor | 2.5–13.5 μm/~260 | ~2 | [87,95] |
Cubert UHD 185 1 | Hyperspectral | 0.45–0.95 μm/~125 | ~ 0.2–0.5 | [95] |
Silt Content | ||||
AisaDUAL 2 | Hyperspectral | 0.40–2.45 μm /~200–400 | ~1–5 | [133] |
HyperSpecTIR 2 | Hyperspectral | 0.40–2.45 μm/~178 | ~2.5 | [158] |
Sand Content | ||||
EO-1 Hyperion 3 | Hyperspectral | 0.40–2.50/242 μm/220 | 30 | [159] |
AisaDUAL 2 | Hyperspectral | 0.40–2.45 μm /~200–400 | ~1–5 | [133] |
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [84] |
HyperSpecTIR 2 | Hyperspectral | 0.40–2.45 μm/~178 | ~2.5 | [158] |
TASI-600 2 | Thermal Airborne Spectrographic Imager | 8.0–11.4 μm/~32 | ~1–5 | [84] |
Carbonate Content | ||||
Terra ASTER 3 | Multispectral/TIR | 0.52–9.2 μm/9 8.12–11.65 μm/5 | 30/90 | [76,79,80,85] |
AVIRIS 2 | Hyperspectral | 0.37–2.45 μm/~200 | ~18 | [67] |
HySpex 2 | Hyperspectral | 0.40–2.45 μm/~200–400 | ~1–5 | [115,116] |
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [117,156,160] |
HyperSpecTIR 2 | Hyperspectral | 0.40–2.45 μm/~178 | ~2.5 | [158] |
AisaOWL 2 | Hyperspectral Longwave Infrared (LWIR) | 7.7–12.0 μm/~100 | ~2 | [89] |
SEBASS 2 | Hyperspectral Thermal Infrared (TIR) Sensor | 2.5–13.5 μm/~260 | ~2 | [86,87,95] |
Iron Content | ||||
Terra ASTER 3 | Multispectral/TIR | 0.52–9.2 μm/9 8.12–11.65 μm/5 | 30/90 | [76] |
Sentinel-2 MSI 3 | Multispectral | 0.40 3.0 μm/13 | 10/20/60 | [76] |
EnMAP 2 (simulated) | Hyperspectral | 0.42–2.45 μm/~250 | 30 | [155] |
CASI 2 | Hyperspectral | 0.40–1.0/ 48 | ~3 | [137] |
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [98,117,155] |
HySpex 2 | Hyperspectral | 0.40–2.45 μm /~200–400 | ~1–5 | [98,155] |
HyperSpecTIR 2 | Hyperspectral | 0.40–2.45 μm/~178 | ~2.5 | [158] |
ROSIS 2 | Hyperspectral | 0.42–0.87/ 115 | ~2 | [161] |
TASI-600 2 | Thermal Airborne Spectrographic Imager | 8.0–11.4 μm/~32 | ~1–5 | [84] |
Heavy metals (in plants and vegetation) | ||||
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [162] |
Silicate Content | ||||
Terra ASTER 3 | Multispectral/TIR | 0.52–9.2 μm/9 8.12–11.65 μm/5 | 30/90 | [76,80] |
AHS 2 | Hyperspectral | 0.43–12.7 μm/~80 | ~2 | [88] |
AisaOWL 2 | Hyperspectral Longwave Infrared (LWIR) | 7.7–12.0 μm/~100 | ~2 | [89,91] |
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [84] |
SEBASS 2 | Hyperspectral Thermal Infrared (TIR) Sensor | 2.5–13.5 μm/~260 | ~2 | [86,87,95] |
TASI-600 2 | Thermal Airborne Spectrographic Imager | 8.0–11.4 μm/~32 | ~1–5 | [85] |
Sulphate Content | ||||
Terra ASTER 3 | Multispectral/TIR | 0.52–9.2 μm/9 8.12–11.65 μm/5 | 30/90 | [80] |
AisaOWL 2 | Hyperspectral Longwave Infrared (LWIR) | 7.7–12.0 μm/~100 | ~2 | [89] |
AisaFENIX 2 | Hyperspectral | 0.40–2.45 μm/~200–400 | ~1–5 | [90] |
AVIRIS 2 | Hyperspectral | 0.37–2.45 μm/~200 | ~18 | [67] |
SEBASS 2 | Hyperspectral Thermal Infrared (TIR) Sensor | 2.5–13.5 μm/~260 | ~2 | [87,95] |
Granitoid Classification | ||||
TASI-600 2 | Thermal Airborne Spectrographic Imager | 8.0–11.4 μm/~32 | ~1–5 | [92] |
Further Elements: (Chemometric diversity of soil) Aluminium (AL), Potassium (K), Calcium (Ca), Magnesium (Mg), Manganese (Mn), Zinc (Zn), (Nt) | ||||
HyperSpecTIR 2 | Hyperspectral | 0.40–2.450 μm/~178 | 2.5 | [158] |
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [131,132] |
Soil Organic Carbon (SOC) | ||||
Terra ASTER 3 | Multispectral/TIR | 0.52–9.2 μm/9 8.12–11.65 μm/5 | 30/90 | [163] |
Sentinel-2 MSI 3 | Multispectral | 0.40 –3.0 μm/13 | 10/20/60 | [164] |
EO-1 Hyperion 3 | Hyperspectral | 0.40–2.50/242 μm/196 | 30 | [115] |
AHS 2 | Hyperspectral | 0.43–12.7 μm/~80 | ~2 | [118] |
AisaDUAL 2 | Hyperspectral | 0.40–2.45 μm/~200–400 | ~1–5 | [133] |
APEX 2 | Hyperspectral | 0.40–2.50 μm/~320 | ~1–3 | [113] |
AVNIR 2 | Hyperspectral | 0.43–1.01 μm/~60 | ~1.20 | [153] |
DAIS-7915 2 | Hyperspectral | 0.40–2.50 μm/72 | 8 | [130] |
EnMAP 2 (simulated) | Hyperspectral | 0.42–2.45 μm/~250 | 30 | [155] |
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [84,123,127,131,132,165] |
TASI-600 2 | Thermal Airborne Spectrographic Imager | 8.0–11.4 μm/~32 | ~1–5 | [84] |
Soil Organic Matter (SOM) | ||||
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [84] |
TASI–600 2 | Thermal Airborne Spectrographic Imager | 8.0–11.4 μm/~32 | ~1–5 | [84]. |
HyperSpecTIR 2 | Hyperspectral | 0.40–2.45 μm/~178 | ~2.5 | [158] |
Total Nitrogen | ||||
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [131,132] |
Microbial Biomass C (MBC) | ||||
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [132] |
Hot Water Extractable C (HWEC) | ||||
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [132] |
pH -Soil | ||||
HyperSpecTIR 2 | Hyperspectral | 0.40–2.45 μm/~178 | ~2.5 | [158] |
Salinity (EC) | ||||
Landsat 5 TM 3 Landsat 7 ETM+ 3 | Multispectral/TIR | 0.45–2.3 μm/6 10.4–12.5 μm/1 | L5:30/120 L7:30/60 | [166,167] |
Landsat 8 OLI/TIRS 3 | Multispectral/TIR | 0.43–2.3 μm/8 10.6–12.51 μm/2 | 30/100 | [168] |
Sentinel-2 MSI 3 | Multispectral | 0.40 –3.0 μm/13 | 10/20/60 | [169] |
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [130,170] |
AIRSAR TOPSAR 2 | Microwave | P–, L-bands (full polarimetric), C-band (VV polarization) | [171] | |
JERS-1 3 | Microwave | L-band (23 cm)-HH pol | [171] | |
Cation-Exchange Capacity (CEC) | ||||
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [117,139] |
Soil crust (physical, biological crust) | ||||
Landsat 5 TM 3 Landsat 7 ETM+ 3 | Multispectral/TIR | 0.45–2.3 μm/6 10.4–12.5 μm/1 | L5:30/120 L7:30/60 | [172] |
AISA-EAGLE 2 | Hyperspectral | 0.42–0.89 μm/~30 | ~3 | [173] |
DAIS-791 2 | Hyperspectral | 0.50–2.50 μm/~72 | ~1–3 | [174] |
CASI 2 | Hyperspectral | 0.42–0.95 μm/~36 | ~1 | [175] |
Soil surface roughness | ||||
TerraSAR-X/TanDEM-X 3 | X-band | 9.63 GHz | [176] | |
Sentinel-1 3 | C-band | 5.3 GHz | [177] | |
PLMR 2 InfraTec thermal imager 2 AISA-EAGLE 2 | L-band microwave radiometer / TIR/ Hyperspectral | 1.26 GHz 7.5–14 μm 0.42–0.89 μm/~30 | ~3–5 | [178] |
Riegl-LMS-Q560 full-waveform 2D laser scanner-LiDAR 2 | LiDAR | 240 KHz | [179] | |
RGB-Camera-UAV 1 | Photogrammetry | ~1–4mm | [180] | |
Soil texture, sediment texture | ||||
Landsat 5 TM 3 Landsat 7 ETM+ 3 | Multispectral/TIR | 0.45–2.3 μm/6 10.4–12.5 μm/1 | L5:30/120 L7:30/60 | [166] |
Landsat 8 OLI/TIRS 3 | Multispectral/TIR | 0.43–2.3 μm/8 10.6–12.51 μm/2 | 30/100 | [159] |
Terra ASTER 3 | Multispectral/TIR | 0.52–9.2 μm/9 8.12–11.65 μm/5 | 30/90 | [181] |
Sentinel-2 MSI 3 | Multispectral | 0.40–3.0 μm/13 | 10/20/60 | [159] |
EO-1 Hyperion 3 | Hyperspectral | 0.40–2.50/242 μm/220 | 30 | [159] |
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | ~5 | [117,123] |
EnMAP 2 (simulated) | Hyperspectral | 0.42–2.45 μm/~250 | 30 | [155,159] |
AisaDUAL 2 | Hyperspectral | 0.40–2.45 μm/~200–400 | ~1–5 | [182] |
Sediment dynamic | ||||
EO-1 Hyperion 3 | Hyperspectral | 0.40–2.50/242 μm/220 | 30 | [75] |
Terra/Aqua MODIS 3 | Multispectral/TIR | 0.41–14.34 μm/36 | 250/500/1km | [183] |
Land degradation | ||||
Terra/Aqua MODIS 3 | Multispectral/TIR | 0.41–14.34 μm/36 | 250/500/1km | [184] |
Soil erosion | ||||
Landsat 5 TM 3 Landsat 7 ETM+ 3 | Multispectral/TIR | 0.45–2.3 μm/6 10.4–12.5 μm/1 | L5:30/120 L7:30/60 | [185] |
Landsat 8 OLI/TIRS 3 | Multispectral/TIR | 0.43–2.3 μm/8 10.6–12.51 μm/2 | 30/100 | [186] |
Sentinel-1 3 | C-band | 5.3 GHz | [177] | |
UAV 1 Lumix DMC-LX3 (Panasonic); Sony NEX 5N (Sony) | Photogrammetry | 2 & 4 μm | 2–4 mm | [187] |
Desertification processes | ||||
Landsat 8 OLI/TIRS 3 | Multispectral/TIR | 0.43–2.3 μm/8 10.6–12.51 μm/2 | 30/100 | [188] |
Spectral Soil Quality Index (SSQI) | ||||
AisaDUAL 2 | Hyperspectral | 0.40–2.45 μm/~200–400 | ~1–5 | [135] |
Mission/ Sensor | Organisation (Country) | Spatial Resolution [m] | Swath at Nadir [km] | Spectral Resolution [μm] | Number of Bands | Spectral Resolution [nm @FWHM] | Launch Year | Reference |
---|---|---|---|---|---|---|---|---|
Missions Currently in Orbit | ||||||||
Hyperion | NASA (USA) | 30 | 7.65 | 0.37–2.57 | 242 | 10 | 2000 | [69] |
CHRIS | ESA (UK) | 17/34 | 13 (nominal) | 0.40–1.05 | 18/63 | 5.6–32.9 | 2001 | [190] |
HJ-1A | CAST (China) | 100 | ≥50 | 0.45–0.95 | 110–128 | 5 | 2008 | [191] |
HySI | ISRO (India) | 506 | 129.5 | 0.45–0.95 | 64 | ~10 | 2008 | [192] |
HICO | NASA/ONR (USA) | 90 | 42 | 0.35–1.08 | 128 | 5.7 | 2009 | [193] |
Missions under construction | ||||||||
GISAT | ISRO (India) | 500 | NA | NA | 210 | NA | 2019 | [194] |
PRISMA | ASI (Italy) | 30 | 30 | 0.40–2.50 | 237 | ~12 | 2019 | [195] |
HISUI | METI (Japan) | 30 | 15 | 0.40–2.50 | 185 | 10 (VNIR) 12.5 (SWIR) | 2019 | [196] |
EnMAP | DLR/GFZ (Germany) | 30 | 30 | 0.42–2.45 | 218 | 5/10 (VNIR) 10 (SWIR) | 2020 | [197] |
Missions in the planning stage | ||||||||
FLORIS/FLEX | ESA | 300 | 100–150 | 0.50–0.78 | NA | 0.3–3.0 | 2022 | [198,199] |
HYPXIM-P | CNES (France) | 8 | 16 | 0.40–2.50 | >200 | ≤10 | In study | [200] |
HyspIRI | NASA (USA) | 60 | 145 | 0.38–2.50 | >200 | 10 | 2025 | [129] |
CHIME | ESA | 20–30 | NA | 0.40–2.50 | >200 | 10 | 2025 | [201,202] |
SHALOM | ISA/ASI (Israel/Italy) | 10/5 | 10 | 0.40–2.50 | 200 | 10 | 2022 | [203] |
Sentinel Satellite | Sensor Type | Link | Spatial Resolution | Launch Time | |
---|---|---|---|---|---|
S-1 | RADAR | land and ocean monitoring, ice mapping, ground movements | https://www.esa.int/Our_Activities/Observing_the_Earth/Copernicus/Sentinel-1 | 5–20 m | S-1A–2014 S-1B–2016 S-1C–2022 S-1D–2028 |
S-2 | Multi-spectral | land monitoring, land cover/land use, vegetation, soil and water cover, inland waterways, and coastal areas | https://www.esa.int/Our_Activities/Observing_the_Earth/Copernicus/Sentinel-2 | 10–60 m | S-2A–2015 S-2B–2017 S-2C–2022 S-2D–2029 |
S-3 | RADAR and multispectral | land- and ocean monitoring, sea-surface topography, sea- and land-surface temperature, ocean color, land color | https://www.esa.int/Our_Activities/Observing_the_Earth/Copernicus/Sentinel-3 | 300–1000 m | S-3A–2016 S-3B–2018 S-3C–2023 S-3D–2029 |
S-4 | Atmospheric sensors optical, geo-stationary | atmospheric monitoring Air quality (O3, NO2, SO2) | S-4A–2022 S-4B–2032 | ||
S-5 | Atmospheric sensors optical | air quality (O3, NO2, SO2, HCHO, CO, CH4) | S-5A–2013 S-5B–2030 S-5B–2037 | ||
S-5P Sentinel-5 Precursor | Atmospheric sensors optical | air quality (O3, UV) | https://www.esa.int/Our_Activities/Observing_the_Earth/Copernicus/Sentinel-5P | 7 × 3.5 km | S-5-2017 |
S-6 | RADAR-Altimeter | global sea-surface height, primarily for operational oceanography and for climate studies | S-6A–2020 S-6B–2025 |
Mission/Sensor/Platform UAV 1 Airborne 2 Spaceborne 3 | Name | Spectral Resolution Spectral Bands/Frequency | Reference |
---|---|---|---|
Soil moisture estimation for bare soil to sparse vegetation conditions | |||
Active and passive microwave sensors | |||
SMAP 3 | Radiometer | 1.41 GHz | [233] |
RADAR | 1.26 GHz | [233] | |
SMOS 3 | MIRAS | 1.4 GHz | [276,314,338,339] |
ALOS-2 3 | PALSAR-2 | 1.3 GHz | [340] |
GCOM 3 | AMSR2 | 6.9 GHz | [341] |
Coriolis 3 | Windsat | 6.8 GHz | [342] |
MetOp 3 | ASCAT | 5.3 GHz | [343] |
RADARSAT2 3 | SAR | 5.3 GHz | [344] |
RISAT 3 | Compact-SAR | 5.35 GHz | [345] |
Sentinel-1 3 | SAR | 5.3 GHz | [346] |
TerraSAR-X/TanDEM-X 3 | SAR | 9.63 GHz | [347,348,349] |
PLMR 2 | L-band microwave radiometer | 2.4 GHz | [178,275,297,298,350,351,352] |
PALS 2 | Radiometer | 1.41 and 2.69 GHz | [353] |
RADAR | 1.26 and 3.15 GHz | ||
PLIS 2 | RADAR | 1.26 GHz | [302] |
FSAR 2 | RADAR | 9.60 GHz, 5.30 GHz, 3.25 GHz, 1.325 GHz, and 0.435 GHz | [299] Horn et al., 2018 |
Other geophysical methods-passive radiation techniques | |||
Cosmic-ray neutron sensing 2 | Natural neutron radiation | 1–1000 eV | [335] |
Gamma-ray surveys 2 | Natural gamma radiation | 40K, 208Tl (0.4–3.0 MeV) | [326] |
Optical remote sensing sensors | |||
Terra/Aqua MODIS 3 | Multispectral/TIR | 0.41–14.40 μm/ 36 | [315,354] |
Landsat 5 TM 3 Landsat 7 ETM+ 3 | Multispectral/TIR | 0.45–2.3 μm/6 10.4–12.5 μm/1 | [316,355] |
Landsat 8 OLI/TIRS 3 | Multispectral/TIR | 0.43–2.3 μm/8 10.6–12.51 μm/2 | [356] |
Terra ASTER 3 | Multispectral/TIR | 0.52–9.2 μm/9 8.12–11.65 μm/5 | [357] |
Meteosat II SEVIRI 3 | Multispectral/TIR | 0.48–7.6μm/8 8.5–13.9 μm/5 | [318] |
Sentinel-2 MSI 3 | Multispectral | 0.40–3.0 μm/13 | [358] |
APEX 2 | Hyperspectral | 0.38–2.50 μm /~125 | [126] |
HyMAP 2 | Hyperspectral | 0.45–2.48 μm/~125 | [123,317,359] |
DAIS-7915 2 | Hyperspectral | 0.40–2.50 μm/72 | [130] |
AHS 2 | Hyperspectral | 0.43–12.7 μm/~ 80 | [357] |
Cubert UHD 185 1 | Hyperspectral | 0.45–0.95 μm/~125 | [136] |
Soil moisture and soil characteristics estimation using plant proxy information | |||
Landsat 4 MSS 3, Landsat 5 TM 3; Landsat 7 ETM+ 3, Landsat 8 OLI/TIRS 3, Sentinel-1 3, Sentinel-2 MSI 3 | Multispectral/TIR/SAR | [360] | |
RapidEye REIS 3 | Multispectral | 0.40–1.3 μm/5 | [144] |
AisaDUAL 2 | Hyperspectral | 0.40–2.45 μm /~200–400 | [100] |
Mission/Sensor/ Platform UAV 1 Airborne 2 Spaceborne 3 | Sensor Type | Spectral Resolution Spectral Bands/Frequency | Spatial Resolution [m] | References |
---|---|---|---|---|
Land surface temperature (LST) | ||||
Terra/Aqua MODIS 3 | Multispectral/TIR | 0.41–14.40 μm/36 | 250/500/1000 | [21,387,388] |
Landsat 5 TM 3 Landsat 7 ETM+ 3 | Multispectral/TIR | 0.45–2.3 μm/6 10.4–12.5 μm/1 | L5:30/120 L7:30/60 | [389,390] |
Landsat 8 OLI/TIRS 3 | Multispectral/TIR | 0.43–2.3 μm/8 10.6–12.51 μm/2 | 30/100 | [356,391] |
NOAA/MetOp AVHRR 3 | Multispectral/TIR | 0.58–3.93 μm/4 10.3–12.5 μm/2 | 1100 | [392,393] |
Terra ASTER 3 | Multispectral/TIR | 0.52–9.2 μm/9 8.12–11.65 μm/5 | 30/90 | [388,394] |
Sentinel-3 OLCI/SLSTR 3 | Multispectral/TIR | 0.4–1.02 μm/21 0.55–12.0 μm/9 | 300/1000 | [395] |
MSG (Meteosat Second Generation) SEVERI/GERB 3 | Multispectral/TIR | 3.4–12.0 μm/8 | 3000 | [396,397] |
GEOS 17 (Geostationary Operational Environmental Satellites) ABI 3 | Multispectral/TIR | 0.45–2.27μm/6 3.8–13.56 μm /10 | 4000 | [21,398] |
AHS 2 | Hyperspectral | 0.43–12.7 μm/~80 | ~ 2 | [399] |
Heitronics IR Pyrometer 2 | Pyrometer | 9.6 and 11.5 μm | 16 m (Radius) | [21] |
Q300, QuestUAV, UK 1 | TIR | 7.5–13 μm | ~ 0.13 m | [383] |
ThermalCapture 2.0 640 thermal camera (TeAx, Wilnsdorf, Germany) 1 | TIR | 7.5–13.5 μm | NA | [384] |
RGB-compact digital camera (Samsung ES80)/Optris Pi 400 1 | RGB/TIR | 7.5–13 μm | 1-5 cm | [377] |
Land surface emissivity (LSE) | ||||
Meteosat II/SEVIRI 3 | Multispectral/TIR | 0.48–7.6 μm/8 8.5–13.9 μm/5 | NA | [318] |
Telops HYPER-CAM 2 | Hyperspectral TIR | 1.5–5.5 μm 8–11.5 μm | NA | [400,401] |
RGB-compact digital camera (Samsung ES80)/Optris Pi 400 1 | RGB/TIR | 7.13 μm | 1-5 cm | [377] |
Evapotranspiration | ||||
MODIS Aqua SST 3 | Multispectral/TIR | 3.66–4.08 μm/4 10.78–12.27 μm/2 | 1000 | [385] |
Terra ASTER 3 | Multispectral/TIR | 0.52–9.2 μm/9 8.12–11.65 μm/5 | 30/90 | [402] |
Landsat 5 TM 3 | Multispectral/TIR | 0.45–12.5 μm/8 | L5:30/120 | [403] |
Landsat 7 ETM+ 3 | Multispectral/TIR | 0.45–12.5 μm/8 | 30/60 | [404] |
Q300, QuestUAV, UK 1 | TIR | 7.5–13 μm | ~0.13 | [383] |
Optris Pi Lightweight kit, Optris GmbH, Germany 1 | RGB/TIR | 7.5–13 μm | 1–5 cm | [377] |
RGB-Samsung ES80)/Optris Pi 400 1 | RGB/TIR | 7.5–13 μm | 1–5 cm | [377] |
Heat fluxes | ||||
RGB-Samsung ES80)/Optris Pi 400 1 | RGB/TIR | 7.5–13 μm | 1–5 cm | [377] |
Data Products | Scale | Link | References |
---|---|---|---|
NASA-Land Surface Temperature & Emissivity Products | Global/Regional | https://lpvs.gsfc.nasa.gov/LSTE/LSTE_home.html | NA |
Landsat and Surface Temperature Land Surface Temperature True Land Suface Albedo | Global | http://rslab.gr/downloads.html http://rslab.gr/downloads_LandsatLST.html | [405] |
GLS Surface Reflectance | Global | http://www.landcover.org/data/gls_SR/ | [406] |
Downward Shortwave Surface Radiation (DSSR) | Global | http://www.landcover.org/data/dssr/ | [407] |
Tropospheric Emission Monitoring Internet Service | Global | http://www.temis.nl/index.php | NA |
Land-Surface Temperature | Global | https://land.copernicus.eu/product-portfolio/overview | NA |
Surface Albedo | Global | NA | |
Lake Surface Water Temperature | Global | NA | |
Global Land Data Assimilation System (GLDAS) | Global | https://grace.jpl.nasa.gov/data/get-data/land-water-content/ https://ldas.gsfc.nasa.gov/ | [365] |
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Lausch, A.; Baade, J.; Bannehr, L.; Borg, E.; Bumberger, J.; Chabrilliat, S.; Dietrich, P.; Gerighausen, H.; Glässer, C.; Hacker, J.M.; et al. Linking Remote Sensing and Geodiversity and Their Traits Relevant to Biodiversity—Part I: Soil Characteristics. Remote Sens. 2019, 11, 2356. https://doi.org/10.3390/rs11202356
Lausch A, Baade J, Bannehr L, Borg E, Bumberger J, Chabrilliat S, Dietrich P, Gerighausen H, Glässer C, Hacker JM, et al. Linking Remote Sensing and Geodiversity and Their Traits Relevant to Biodiversity—Part I: Soil Characteristics. Remote Sensing. 2019; 11(20):2356. https://doi.org/10.3390/rs11202356
Chicago/Turabian StyleLausch, Angela, Jussi Baade, Lutz Bannehr, Erik Borg, Jan Bumberger, Sabine Chabrilliat, Peter Dietrich, Heike Gerighausen, Cornelia Glässer, Jorg M. Hacker, and et al. 2019. "Linking Remote Sensing and Geodiversity and Their Traits Relevant to Biodiversity—Part I: Soil Characteristics" Remote Sensing 11, no. 20: 2356. https://doi.org/10.3390/rs11202356
APA StyleLausch, A., Baade, J., Bannehr, L., Borg, E., Bumberger, J., Chabrilliat, S., Dietrich, P., Gerighausen, H., Glässer, C., Hacker, J. M., Haase, D., Jagdhuber, T., Jany, S., Jung, A., Karnieli, A., Kraemer, R., Makki, M., Mielke, C., Möller, M., ... Schaepman, M. E. (2019). Linking Remote Sensing and Geodiversity and Their Traits Relevant to Biodiversity—Part I: Soil Characteristics. Remote Sensing, 11(20), 2356. https://doi.org/10.3390/rs11202356