Earth Surface Processes

❄️Earth Surface Processes Unit 15 – Remote Sensing in Geomorphology

Remote sensing revolutionizes geomorphology by allowing scientists to observe and analyze Earth's surface from afar. Using satellites, aircraft, and advanced sensors, researchers can map vast areas, monitor changes over time, and study inaccessible regions with unprecedented detail and efficiency. This powerful tool enables the creation of digital elevation models, land cover maps, and other geospatial products. By harnessing various parts of the electromagnetic spectrum, remote sensing provides valuable insights into terrain, vegetation, water content, and surface temperature across large scales.

What's Remote Sensing?

  • Remote sensing involves gathering information about the Earth's surface from a distance using sensors on satellites or aircraft
  • Enables mapping and monitoring of large areas of the Earth's surface that would be difficult or impossible to survey from the ground
  • Provides a synoptic view of the Earth's surface allows for the identification of large-scale patterns and processes
  • Remote sensing data can be used to create digital elevation models (DEMs), land cover maps, and other geospatial products
  • Offers a cost-effective and efficient means of collecting data over large areas compared to ground-based surveys
  • Enables the study of inaccessible or hazardous areas (volcanic regions, glaciers) without putting researchers at risk
  • Provides a means of monitoring changes in the Earth's surface over time (deforestation, urban sprawl, coastal erosion)

Key Remote Sensing Tools

  • Sensors are the primary tools used in remote sensing to detect and record electromagnetic radiation reflected or emitted by the Earth's surface
    • Passive sensors detect naturally reflected or emitted energy (sunlight, thermal radiation)
    • Active sensors emit their own energy and record the reflection (radar, lidar)
  • Satellites are the most common platforms for remote sensing sensors provide a stable and consistent vantage point for data collection
    • Polar-orbiting satellites (Landsat, Sentinel) orbit from north to south and cover the entire Earth's surface
    • Geostationary satellites (GOES, Meteosat) orbit above a fixed point on the equator and provide continuous coverage of a specific region
  • Airborne platforms (planes, drones) offer higher spatial resolution and flexibility compared to satellites but cover smaller areas
  • Spectroradiometers measure the intensity of electromagnetic radiation at different wavelengths used for calibration and validation of satellite data
  • GPS receivers provide precise location information for ground control points and field data collection

Electromagnetic Spectrum Basics

  • The electromagnetic spectrum is the range of all possible frequencies of electromagnetic radiation from low-frequency radio waves to high-frequency gamma rays
  • Different parts of the spectrum interact with the Earth's surface in different ways depending on their wavelength and energy
  • Visible light (400-700 nm) is the part of the spectrum that humans can see consists of the colors red, orange, yellow, green, blue, and violet
  • Near-infrared (700-1400 nm) is sensitive to healthy vegetation often used for vegetation mapping and monitoring
  • Shortwave infrared (1400-3000 nm) is sensitive to water content in plants and soils used for drought monitoring and mineral mapping
  • Thermal infrared (3000-14000 nm) is emitted by all objects above absolute zero used for temperature mapping and heat loss studies
  • Microwave (1 mm - 1 m) can penetrate clouds, smoke, and vegetation used for soil moisture mapping and sea ice monitoring

Remote Sensing Data Types

  • Multispectral data consists of multiple bands of data collected at different wavelengths across the electromagnetic spectrum
    • Landsat and Sentinel satellites collect multispectral data with 4-12 bands
    • Enables the identification of different land cover types and surface features based on their spectral signatures
  • Hyperspectral data consists of hundreds of narrow bands collected across the electromagnetic spectrum
    • Provides more detailed spectral information compared to multispectral data
    • Enables the identification of specific minerals, vegetation species, and other surface materials
  • Radar data is collected using active sensors that emit microwave energy and record the backscattered signal
    • Enables the mapping of surface roughness, soil moisture, and vegetation structure
    • Can penetrate clouds, smoke, and vegetation to map the underlying surface
  • Lidar data is collected using active sensors that emit laser pulses and record the reflected signal
    • Provides high-resolution 3D point clouds of the Earth's surface
    • Enables the mapping of vegetation height, building heights, and other surface features

Image Processing Techniques

  • Geometric correction involves correcting distortions in the image caused by the sensor, platform, or Earth's curvature
    • Includes orthorectification, which corrects for topographic distortions using a DEM
    • Ensures that the image is properly aligned with a map projection and coordinate system
  • Radiometric correction involves correcting for variations in the sensor's response and atmospheric effects
    • Includes sensor calibration, atmospheric correction, and topographic correction
    • Ensures that the pixel values accurately represent the reflectance or emittance of the surface
  • Image enhancement involves improving the visual quality and interpretability of the image
    • Includes contrast stretching, color composites, and spatial filtering
    • Enhances specific features or patterns in the image for better visualization and analysis
  • Image classification involves assigning each pixel to a specific land cover or surface type based on its spectral signature
    • Includes supervised classification (using training data) and unsupervised classification (using clustering algorithms)
    • Produces a thematic map of the surface showing the distribution of different land cover types
  • Change detection involves comparing two or more images of the same area at different times to identify changes in the surface
    • Includes image differencing, principal component analysis, and post-classification comparison
    • Enables the monitoring of land cover changes, natural disasters, and human activities over time

Geomorphological Applications

  • Terrain analysis involves using DEMs to extract geomorphological parameters (slope, aspect, curvature) and identify landforms (valleys, ridges, peaks)
  • Landslide mapping involves using remote sensing data to identify and map the distribution of landslides and assess their hazard potential
    • Multispectral and radar data can be used to identify vegetation and soil changes associated with landslides
    • Lidar data can be used to create high-resolution DEMs for landslide susceptibility modeling
  • Coastal change monitoring involves using remote sensing data to map and monitor changes in coastlines, beaches, and dunes over time
    • Multispectral data can be used to map coastal land cover and sediment types
    • Lidar data can be used to create high-resolution DEMs for coastal erosion and accretion studies
  • Glacial mapping involves using remote sensing data to map and monitor changes in glaciers and ice sheets over time
    • Multispectral data can be used to map glacier extent, snow cover, and melt patterns
    • Radar data can be used to measure glacier velocity and ice thickness
  • Volcanic monitoring involves using remote sensing data to monitor volcanic activity and assess hazard potential
    • Thermal infrared data can be used to map lava flows and detect heat anomalies
    • Radar data can be used to measure ground deformation associated with volcanic activity

Limitations and Challenges

  • Cloud cover can obscure the Earth's surface and limit the availability of optical remote sensing data in some regions and seasons
  • Shadows can affect the spectral response of the surface and create challenges for image classification and change detection
  • Atmospheric effects (haze, dust, smoke) can reduce the quality and accuracy of remote sensing data if not properly corrected
  • Spatial resolution limitations can affect the ability to detect and map small-scale features and changes on the Earth's surface
    • Higher spatial resolution data (< 1 m) is often more expensive and has smaller coverage areas compared to lower resolution data
  • Temporal resolution limitations can affect the ability to monitor rapid or short-term changes on the Earth's surface
    • Satellites have fixed revisit times (days to weeks) that may not capture all relevant changes
    • Airborne and drone data can provide more frequent coverage but are limited by weather conditions and flight regulations
  • Data volume and processing requirements can be challenging for large-scale or high-resolution remote sensing studies
    • Hyperspectral and lidar data can generate terabytes of data that require specialized software and computing resources to process and analyze
  • Increased use of small satellites (CubeSats) and satellite constellations will provide more frequent and higher resolution data for Earth observation
  • Advances in sensor technology (hyperspectral, thermal, lidar) will enable new applications and more detailed analysis of the Earth's surface
  • Integration of remote sensing data with other geospatial data (GPS, GIS, crowdsourcing) will enable more comprehensive and multi-scale analysis of Earth surface processes
  • Increased use of machine learning and artificial intelligence techniques will enable more automated and efficient processing and analysis of remote sensing data
    • Deep learning algorithms can be used for image classification, object detection, and change detection
    • Cloud computing platforms (Google Earth Engine, Amazon Web Services) will enable more accessible and scalable processing of remote sensing data
  • Expansion of remote sensing applications beyond geomorphology to other fields (agriculture, forestry, urban planning, disaster response) will drive innovation and interdisciplinary collaboration
  • Increased emphasis on open data and open science will make remote sensing data and tools more accessible and reproducible for researchers and decision-makers worldwide


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© 2024 Fiveable Inc. All rights reserved.
AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.