International Archives of Photogrammetry and Remote Sensing. Vol. XXXII Part 7C2, UNISPACE III, Vienna. 1999 
115 
15PR5 
UNISPACE III - ISPRS/EARSeL Workshop on 
“Remote Sensing for the Detection, Monitoring 
and Mitigation of Natural Disasters” 
2:30-5:30 pm, 22 July 1999, VIC Room B 
Vienna, Austria 
The INCO Limited Copper Cliff tailings area is the largest 
repository of acid generating tailings in North America, and 
possibly the world. The site covers approximately 5500 acres 
and contains more than 10 percent of all tailings in Canada. 
Mill tailings have been deposited since the 1937. The 
impoundments contain silt to sand size tailings including sulfide 
minerals, such as pyrrhotite, pentlandite, calcopyrite and pyrite 
(McGregor et al 1995). The mill waste is impounded in a basin 
enclosed by bedrock ridges and dams made of till material. The 
tailings dams were designed to seep in order to maintain a low 
phreatic head for structural stability (Puro et al 1995).Tire 
sulfide minerals contained in the tailings are oxidized by 
atmospheric oxygen. A 1-3 m thick oxidation zone is present at the 
old tailing surface (De Vos et al 1995). The water infiltrating the 
tailings surface will ultimately seep as acid drainage. Some of the 
acid drainage accumulates in depressions below the dam, and 
gradually kills the nearby vegetation. 
Restoration of the tailings area involves treating the acid soils with 
a lime- rich fertilizer and revegetation with varieties of grasses and 
legumes. The casi image was used to discriminate vegetation, lime 
and oxidized tailings (Figure 2). In this image Levesque et al., 
1997 use a linear unmixing technique to separate three surfaces of 
the tailings. Tire linear unmixing technique uses the spectrum of 
each pixel which is decomposed into a linear combination of 
"endmembers" spectra, representing the purest pixels.Manual 
selection of endmember spectra from the extremities of various 
combinations of first three principal components scatter plots were 
used to separate the tailings surface. Field verification shows that 
the resulting thematic images accurately corrispond to the tailing 
surfaces. Images taken at subsequent periods were used to monitor 
the revegetation progress at specific sites. 
Monitoring Pollution of Mining Lakes environmental 
restoration in Germany. 
In Germany, today there is a need to provide low cost 
techniques for the assessment and long term monitoring of 
mining areas. Because of the size of the mining areas and the 
changing landscape multi temporal and multisensor remote 
sensing data offer the best possibilities to fulfil these demands 
(Glaesser at 1999, Birger et.al 1998). In this section, we report 
the results of Boine et. al. 1999 and Glaesser et al 1999. They 
used satellite and airborne multispectral (casi) images, and field 
spectroradiometric measurements to map sulphate content of 
mining lakes and monitor restoration programs 
The test area is part of the Eocene lignite deposit (bituminous 
brown lignite) in Central Germany. It is characterised by 
widespread lignite seams - mostly two seams of 5 to 15 m 
thickness- that are overlaid by marine Tertiary and glacial 
Pleistocene sediments. In these mining areas many acid lake 
exists because of the oxidation of pyrite and marcasite minerals 
of waste sediments, and the rising groundwater. To explore the 
uses of airborne multispectral data to characterise the acid lakes, 
casi data were flown with the enhanced spectral mode with 48 
adjacent non-overlapping bands with a 10.6 nm band with 
within the spectral range from 428 mn to 975 nm. The casi data 
were corrected and classified, based on field spectral 
information (Figure 3). Water sampling and spectral field 
measurements were made on the acid lakes at the time of the 
casi flights overpass. Figure 3 summarises some of the field 
measurements, which included pH. secchi depth, total dissolved 
iron content and sulphate content and reflectance spectra of the 
acid lakes (Boine et al 1999) 
This case study suggests that remote sensing methods can be 
used to characterise acid lakes in mining areas. To achieve a 
more reliable classification results Boine et.al suggests that 
information related to the hydrochemical and hydrobiological 
properties of the lakes, be considered. Also because of extensive 
variability in optical and chemical properties of the lakes the 
classification procedures should be done within individual lakes 
and between single lakes. These new methods provide another 
tool to monitor the temporal and spatial variability of acid lakes 
in mining areas. 
The classification of the sediments and vegetation uses three 
different satellite and airborne sensors for comparison of their 
specific potentials in mining areas. During each flight a spectral 
field measurement of sediments were carried out with a field 
spectrometer GER Mark V in the wavelength range from 400 to 
2500 nm. Classification methods include the maximum- 
likelihood, spectral angle mapping, and linear spectral 
unmixing. The highest spectral resolution airborne data 
(HYMAP and DIAS) and TM5 were the most useful for the 
classification of the sediments For the vegetation, it was 
possible to classify the airborne data to produce information at 
the level of the vegetation units. Glaesser at al 1999 noted that 
the airborne data was useful to classify single trees and quite 
good for determination of differences in the density of the 
vegetation even when then pixel size is much larger then the 
size of the plants. 
Image Maps for Groundwater Protection in Jordan 
In Jordan, there is an urgent need to manage and utilize the 
water resources in order to comply with the immediate and 
projected water demand in the country. Hydrogeological 
mapping is fundamental to the economic development of 
Jordan. Pumping of groundwater is already in danger of 
exceeding levels at which the resource cannot be renewed; and 
water quality is declining (World Bank 1995). Groundwater is 
the major water resources in many areas in the country. All the 
known aquifers have been explored. Water harvesting is a 
national priority as water supplies are being depleted by 
intensive pumping. For this reason it is necessary to map in 
detail the hydrogeology of all the aquifers. Since the distribution 
of groundwater in Jordan is fairly well known, the main 
problem is to optimize the utilization of groundwater resources, 
and protect them against depletion and pollution. Although 
several studies have shown that there has been considerable 
work done for the search for potable water in Jordan (Bajjalli 
1994, GTZ 1977, etc.), the use of remote sensing techniques for 
groundwater protection is increasing. This case study reports on 
the use of and SAR/TM data fusion technique integration for 
providing information on the surface hydrogeological 
characteristics of a sensitive aquifer in Azraq. Jordan. The 
image map produced from the data fusion technique was used to 
map wadis, rock units, fractures and land practices necessaiv for 
environmental protection of the aquifers. 
The SAR/TM synergy image was integrated using the IHS 
integration method (Cliche et al., 1985). The three Eigen vectors 
of the TM image were transferred to the IHS space then, the