Informational Notices:

Vegetation and Soil Monitoring Study in the Vicinity of 8-8 Battery

Tilston, Manitoba 1999

Floyd Phillips
Vicki Henderson
Terrestrial Quality Management Section
Manitoba Conservation
Manitoba Conservation Report 2000-05

September 2000

Executive Summary

The Tilston area is the site of oil extraction from underground reserves in the southwest corner of Manitoba. A vegetation and soil monitoring study was carried out during the summer of 1999 in response to concerns of rural residents near the 8-8 oil processing battery (SE8-6-29). The objective of the study was to determine if there were any observable effects caused by the sulphur compounds present in the air emissions from the battery.

Ten monitoring sites were selected, 5 along each of two 2 km transects running SE and W of the battery. Aspen leaves were collected from each of the sites in May, July and August, and soil samples were collected in July. Aspen leaves were analyzed for sulphur and soil samples were analyzed for sulphur and sulphate. The condition of plant leaves was observed several times during the summer, at the monitoring stations, at the aspen bluffs close to the battery, and at farmyards within 2.5 km of the battery. Samples of unhealthy or injured leaves were collected and sent to the Crop Diagnostic Centre, Manitoba Agriculture where plant pathologists diagnosed the cause.

Although many plants in the study area and the control farm showed injury symptoms, disease (mostly fungus) or insects caused them all. There was no visible SO2 injury to plants in the study area. The relatively high incidence of fungal infection and other plant diseases was probably aproduct of the abnormally wet conditions during the spring and summer of 1999.

The sulphur content of aspen leaves suggested that there may have been some effect from the battery emissions at one close-in site, although the data were too variable to reach a definitive conclusion.

Available sulphate in the surface soil was slightly elevated at locations within 500m of the 8-8 battery, but due to the high variability, there was no conclusive evidence that emissions of sulphur compounds may have been a contributing factor. Total sulphur in the soil was also variable but there was no pattern that suggested that this parameter might have been affected by sulphur compounds emitted from the 8-8 oil processing battery.

In summary, emissions of sulphur compounds in the study area did not injure vegetation. There was no conclusive evidence that sulphur compounds in the air of the study area affected sulphur levels in aspen leaves or sulphate or sulphur in the soil. The levels of sulphur found in the aspen leaves were within the normal range and would not be detrimental to plant health. The sulphate levels in the soil were lower than or in the low part of the range reported in the Soil Survey Report for the area.

Acknowledgments

The authors wish to thank the local residents of the study area for their cooperation in providing access to their property and for agreeing to allow the sampling of soils and vegetation. The authors also acknowledge the assistance of Mr. D. Bezak who provided comments on an earlier draft of the report and Mr. G. Jones for preparing the figure showing the study area.

Introduction and Background

Oil reserves are present in the southwest corner of Manitoba, and oil extraction has been occurring in the Tilston area since the early 1950s.

The Terrestrial Quality Section of Manitoba Conservation conducted a vegetation and soil monitoring program in the vicinity of the 8-8 oil processing battery during the summer of 1999. The 8-8 battery is located north of Tilston, in the southeast quarter of Section 8 Township 6 Range 29. This is one of the larger processing batteries in the area and has operated since 1985. Rural residents living within a few kilometres of the 8-8 battery have complained about odours and are concerned that air pollutants may be causing health effects to both humans and livestock.

The product pumped from the oil wells in the area is approximately 10 percent oil and 90 percent salt water. The oil contains solution gases, including hydrocarbon components of natural gas and hydrogen sulphide (H2S). Oil processing batteries perform two initial treating steps: (i) separation of the crude oil from the salt water during which some of the solution gases are released, and (ii) heating the oil to drive off more of the solution gases. Some of the solution gases is burned as fuel in the oil treater, and the past practice, was to direct the excess gas to a flare stack where it was partially burned. A more recent technology used at Tundra’s 8-8 battery since November 1999, is to burn the excess gas in an incinerator to effect more complete combustion. Since the combustion of H2S produces sulphur dioxide (SO2), the air emissions from a processing battery can contain both H2S and SO2.

Although air quality monitoring was being conducted at two fixed locations, plus some spot monitoring with a portable monitor, there was interest in using other monitoring tools to provide further information about the levels of sulphur gases and their distribution in the area. If the sulphur dioxide dose (concentration x duration) is high enough it can cause visible injury symptoms to the leaves of susceptible plants or to the needles of conifers. Plants, including some that are native to the area (e.g. aspen, rose, wild pea), are susceptible to SO2 injury. There is a potential that these plants may be injured if doses are above a critical minimum. Dreisinger and McGovern (1970) reported injury to aspen leaves after a one hour exposure to 0.42 ppm SO2, but usually did not observe damage until exposures were in the range of 0.95 ppm for one hour. If the relative humidity is high, SO2 exposures that may cause acute damage are typically lower, for instance in the 70 ppm range (Dreisinger and McGovern, 1970). Acute SO2 damage (brown tissue) typically occurs on the leaf margins and between the veins of the leaves in broad leaf plants and on the tips of needles in conifer trees.

The purpose of this study was to determine if sulphur compounds, released into the air from oil processing at the 8-8 battery, were affecting local vegetation or soils. The study was conducted during the 1999 growing season and had the following objectives:

  1. examine plants in the vicinity of 8-8 battery for visible signs of leaf injury and diagnose the cause;
  2. determine if there were differences in the concentration of sulphur in the vegetation of the area and if so, was there a pattern that might suggest the likely source of the sulphur; and
  3. determine if there were differences in the concentration of sulphur in the soil of the area and if so, was there a pattern that might suggest the likely source of the sulphur.

Methods

Vegetation Health

During the course of the study, the leaves of plants were examined to see if there were any visible signs of injury. Native plants including trees, shrubs, and herbaceous species, which grow along the edges of poplar bluffs in the area, were the main focus of this investigation. All poplar bluffs growing within 200m of the 8-8 battery were examined as well as the bluffs selected for soil and vegetation (aspen) sampling. Local species considered to be most susceptible to SO2 injury included members of the pea family, rose family and trembling aspen (Populus tremuloides).

During the summer, several species of trees and shrubs in shelterbelts or gardens at three farmyards within 2.5 km of the battery were periodically examined for leaf or needle injury (Figure 1). On September 1, 1999, trees and shrubs in a farmyard northeast of Sinclair, were examined as a control. If vegetation was injured or appeared to be in poor health, samples were taken, placed in sealed plastic bags, refrigerated, and taken to the Crop Diagnostic Centre, Manitoba Agriculture, for a determination of the cause.

Table 1. Farmyards where vegetation health was examined

Farmyard
Legal Description
Direction
Distance (km)
Yard 1
SE 9-6-29
E
1.5
Yard 2
NE 4-6-29
SE
2.1
Yard 3
SE 5-6-29
SSW
2.2
Control
NE 22-7-28
NE
21.9


Orthophoto of Tilston 8-8 Study Area

Figure 1. Orthophoto of Tilston 8-8 Study Area.-Click on image for a larger view

Trembling Aspen Monitoring

Ten sites were selected to collect leaves of trembling aspen trees to determine the concentration of sulphur in the foliage. Five sites were selected along each of two transects, one running southeast of the battery and one running west of the battery. The study design called for sites to be spaced along each transect at distances of 125m, 250m, 500m, 1km, and 2km from the battery. Although suitable natural vegetation was not available at the precise distances and directions identified in the study design, poplar bluffs that matched the distance and direction criteria as closely as possible were selected (Figure 1).

Three replicate samples of aspen leaves were obtained at each site by stripping leaves by hand from branches that could be reached from the ground. The samples were stored in paper bags and frozen within a few hours of sampling. Frozen samples were submitted to the Enviro-Test Laboratory for tissue analysis. Each sample was dried, ground and homogenized and subsampled for each analysis. Leaf samples were analyzed for total sulphur (S), iron (Fe), nitrogen (N), phosphorous (P), and potassium (K).

Alfalfa Monitoring

Four replicate samples of alfalfa were collected from fields and roadsides within 2.2 km of the 8-8 battery (August). The stems and leaves were dried, ground and analyzed for total S, Fe, P, K, and selenium (Se).

Soil Monitoring - Surface Organic Soils

Three replicate samples of the surface organic layer of soils were obtained from each of the five sites along the southeast and west transects. At each sample location, the vegetation was removed from an area approximately 15cm by 30cm. Using a plastic template as a guide, a sharp knife was used to cut out two 10cm by 10cm squares. A flat 10cm wide plastering trowel was used to help lift out each square of the organic layer. The depth of the organic layer (usually approximately 5 cm thick) was recorded to enable calculation of the total volume of the sample. Each replicate sample was comprised of two 10cm by 10cm squares of organic material.

Soil Monitoring - Mineral Soils

Fifteen-centimetre deep samples of the mineral soil were obtained with a 5cm diameter by 15cm long soil core sampler. Using its pile-driver handle, the sampling tube was driven into the ground in the area where the surface organic sample had been removed. Two 5cm by 15cm samples comprised each replicate sample and three replicate samples were collected at each site along each transect. The sampler was disassembled to remove each core sample, and soil adhering to the sampler was cleaned off prior to taking the next sample.

Soil Monitoring - Deeper Mineral Soils

Deeper soil samples (15 to 30 cm, 30 to 60 cm, 60 to 90 cm and 90 to 120 cm, provided rocks were not encountered) were collected from three locations to provide data on the baseline chemistry of the soil parent materials. A Dutch auger was used to collect the samples. After each bit full of soil was brought to the surface, the outer edges were pared off to remove any contamination that might have been picked up as it rubbed the wall of the hole while being removed. The remainder was then removed from the auger bit and placed in a sealed plastic bag.

Soil Handling and Analysis

The soil samples were frozen within a few hours. The frozen samples were submitted to Enviro-Test Laboratories for analyses including total S, and available sulphate (SO4), nitrate-nitrite (NO3-NO2), phosphate (PO4) and K.

Monitoring Schedule

Table 2. Sampling dates.

Date
Vegetation Health
Aspen
Samples
Alfalfa
Samples
Soil
Samples
Farmyards
Aspen Bluffs
May 31/99
3
3
3
   
June 30/99
3
3
     
July 14/99
3
3
3
 
3
Aug. 11/99
3
3
     
Aug. 25/99
3
3
3
3
 
Sept. 1/99
*
*
*
  
*

* Control farm NE of Sinclair NE22-7-28

Results and Discussions

Vegetation Condition Poplar bluffs within 200m of the battery in any direction:

Several aspen trees showed signs of insect damage, including rolled leaves and leaves that had been partially eaten.

Some aspen trees in the S and SW directions had interveinal chlorosis (yellow-green tissue between the veins of the leaves), a symptom that is sometimes indicative of chronic SO2 injury. However, the Crop Diagnostic Centre (MB Agriculture) determined this to be an iron deficiency symptom.

By June 30, a few aspen trees in each bluff (especially smaller trees along the edge) had developed brown areas along the leaf margins and between the veins. Although this resembled acute SO2 injury symptoms, the Crop Diagnostic Centre determined it to be a shoot blight fungal disease (Table 3). By August 11, leaves at the ends of affected branches had died and the stem had turned black, which is consistent with the development of the shoot blight disease.

The shoot blight fungal disease was also observed in the aspen bluff from the control farm (Table 4), indicating that the disease was not correlated in any way with the emissions of sulphur compounds.

No symptoms that resembled SO2 injury were observed on any plant species.

Monitoring sites

A few aspen trees at each location showed iron deficiency symptoms, and there was sporadic occurrence of the shoot blight disease at all sample locations. The occurrence of a similar level of shoot blight infection at the control farm confirmed that it was not related in any way to emissions in the study area.

No SO2 injury symptoms or injury that might have been caused by other pollutants were observed on any plant species in the poplar bluffs.

  • Alfalfa
    No leaf damage from insects, disease or SO2 injury was observed on alfalfa in the study area or at the control farm.
  • Farmyards
    Several species of trees, shrubs and flowers in the farmyards had injury symptoms or unhealthy appearance and were collected for further diagnosis. The Crop Diagnostic Centre determined the cause of the symptoms, and the results are presented in Tables 3 and 4. It is noteworthy that some of the same fungal infections were found in both the study area and the control farmyard, although there did seem to be a higher proportion of foliage affected in the study area. This was probably a result of natural variability in an abnormally wet year although the study was not able to rule out the remote chance that sulphur compounds in the air may have made the plants more susceptible to disease.

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Table 3. Cause of leaf tissue damage within the study area as determined by the Crop Diagnostic Centre, Manitoba Agriculture.

Location / Date
Plant
Symptoms
Disease Name / Type
Yard 3
99/06/15*		 Blue spruce Brown needles & needle tips Resembled SO2 injury but needle cast disease was confirmed in later samples
SE8-6-29
99/06/30		 Aspen poplar Chlorosis (yellowing) between veins Iron deficiency
SE8-6-29
99/06/30		 Aspen poplar Brown lesions on the margins of leaves and between veins Pollacia shoot blight / fungus
Yard 3
99/07/14		 Blue spruce Brown needle tips and brown needles on previous years growth Winter injury
Needle cast disease / fungus
Yard 3
99/07/14		 Green ash White flecks on leaves Ash plant bugs / insects
Yard 3
99/07/14		 Green ash Leaf curling Uncertain, possibly herbicide drift / herbicide such as 2-4D
Yard 3
99/07/14		 Lilac Brown lesions on the margins of the leaves Leaf scorch / saline soils or stem injury from an unknown cause
Yard 3
99/07/14		 Amur maple Black spots on leaves Tar spot / fungus
Yard 3
99/07/14		 Manitoba maple Leaves curled and light green colour Herbicide drift / group 4 growth regulator herbicide, e.g. 2-4D
Yard 3
99/07/14		 Apple Chlorosis (yellowing) between veins Iron deficiency
Yard 3
99/07/14		 Apple Brown spots or areas on the leaves Frogeye leaf spot / fungus
Yard 3
99/07/14		 Chokecherry Spots on leaves and holes in the leaves Shot hole / fungus
Yard 3
99/07/14		 Petunia Extremely chlorotic (yellow) Nutrient deficiency
SW4-6-29
99/08/11		 Aspen Brown areas on the leaf margins and between the veins Marssonina leaf spot / fungus
Leaf rust / fungus
Yard 3
99/08/11		 Blue spruce Brown needle tips and brown needles on previous years growth Rhizosphaera needle cast disease / fungus
Yard 3
99/08/11		 Saskatoon Chlorosis (yellow) between the veins & poor leaf colour Iron deficiency + insect injury (aphids, leaf hoppers)
Yard 2
99/08/11		 Caragana Yellow leaves and some brown areas on the leaves Septoria leaf spot / fungus
Yard 2
99/08/11		 Lilac Yellowing leaves and brown areas especially on the leaf margins Nutritional deficiency with browning caused by dehydration of the stressed leaf tissues
Yard 2
99/08/11		 Apple Chlorosis and development of dry brown areas Iron deficiency & stressed tissue is dehydrated
Yard 2
99/08/11		 Ash Chlorosis between veins Iron deficiency
Yard 2
99/08/11		 Raspberry Yellowish leaves with some browning on the margins Anthracnose / fungus
Yard 1
99/08/11		 Elm Yellowing areas on the leaves Lace bugs which suck juices from the leaves
Yard 1
99/08/11		 Cotoneaster Shoot dieback with all leaves turning a reddish brown Fire blight / bacterial disease
Yard 1
99/08/11		 Cotoneaster Brown spotted areas on the leaves Larvae of the pear sawfly (pear slug) feeding damage
Yard 1
99/08/11		 Chokecherry Shot hole damage to leaves & some brown spots Shothole (leaf spot) disease / fungus
Yard 1
99/08/11		 Ash Small white marks on the leaves & some areas brown Insect feeding damage
Anthracnose / fungus
Yard 1
99/08/11		 Manitoba maple Leaf curling on new growth, yellowing between the veins and occasional brown areas on the leaf margins Stress symptoms, possibly caused by twig or branch canker diseases.
Yard 1
99/08/11		 Saskatoon Brown areas on the leaves Entomosporium leaf spot / fungus

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*Collected by Glen Robertson, Environment Officer, Park-West Region

Table 4. Cause of leaf tissue damage at the control farm as determined by the Crop Diagnostic Centre, Manitoba Agriculture.

Location / Date
Plant
Symptoms
Disease Name / Type
Control Yard
99/09/01		 Lilac White powdery material on the leaves Powdery mildew / fungus
Control Yard
99/09/01		 Chokecherry Brown dry spots on leaves and some holes in leaves Shot hole / fungus
Control Yard
99/09/01		 Raspberry Leaves drying and turning yellow and red May be nutrient deficiency
Control Yard
99/09/01		 Cotoneaster Brown spotted areas on the leaves This sample was lost in transit, but it resembled the sample from Yard 1. The diagnosis of the latter was feeding by pear sawfly larvae.
Control Yard
99/09/01		 Manitoba maple Misshapen leaves with light green colour Leaf galls / Eriophyid mites
Leaf spot disease (unidentified) / fungus
Control Yard
99/09/01		 Apple Brown areas along leaf margins
Some areas on the leaves turning yellow or reddish brown		 Marginal leaf scorch / unknown
Insect feeding damage
Unidentified virus disease
NE22-7-28
99/09/01		 Aspen Brown necrotic areas on the leaves Poplar rust
NE22-7-28
99/09/01		 Aspen Brown necrotic areas on the margins and between the veins of leaves Marssonia leaf spot disease

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Chemical Analysis of Aspen

Samples of trembling aspen leaves were analyzed for total sulphur (S), total iron (Fe), available nitrogen (N), total phosphorous (P), and total potassium (K). The NPK analyses were done to provide backup data in case it appeared that nutrient deficiencies may have been a factor in vegetation health. The nutrient data are included in the tables but since there was no evidence of nutrient deficiencies, the nutrient data are not discussed in this report.

The total S in aspen leaves ranged from 1040 to 3530 m g/g (Appendix, Tables 5 and 6) which is within the normal range of 500 to 14,000 m g/g depending on the species (Malhotra and Hocking. 1976). Freedman and Hutchinson (1980) reported concentrations of S in aspen of 2700 m g/g at control sites in the Sudbury area compared to 4900 m g/g at sites close to the smelter. Data from the SE transect show a trend of decreasing S with distance from the 8-8 battery (Figure 2).

Total Sulphur in Aspen Foliage

Figure 2. Mean concentration of total sulphur in leaves of trembling aspen along the SE transect from the 8-8 Battery.

The S in the aspen from the control site was slightly lower than at a few of the sites close to the battery. That suggests that there may have been some local effect from the S emissions, although it could also have been the result of variability in uptake of naturally occurring sulphur compounds. However, if the source of the S in the foliage had been the emissions from the 8-8 battery, the S content of the leaves from close-in sites should have increased markedly by August 25, 1999. Since that seasonal increase was not observed along the SE transect, sulphur compound emissions probably were not the cause of the slightly elevated S levels in the aspen leaves. At the site closest to the battery along the W transect, the S in the leaves did increase through the season (Figure 3). Based on these data, it appears that the average sulphur compound emissions may have had a very minor local effect on the S concentrations in aspen foliage but given the high variability in the data, the evidence is inconclusive. Sulphur is a necessary plant nutrient and the concentrations found in the aspen leaves of this study would not have a negative effect the growth and health of vegetation.

Chemical Analysis of Alfalfa

Samples of alfalfa were collected from four sites within 2.5 km of the 8-8 battery (Appendix Table 7). The concentrations of all chemical elements were highly variable. Unfortunately, no alfalfa samples could be found in close proximity to the 8-8 battery. The average total S in alfalfa collected from Yard 1 and Yard 2 was similar, but was lower in the samples collected near Yard 3. The alfalfa from the ditch 1.6 km west had the highest average S content. Since there is no other explanation for the differences, it appears that this can only be attributed to natural variability.

Total Sulphur in Aspen Foliage
Available Sulphate in Soil

Chemical Analysis of Deeper Mineral Soils

Available SO4 was generally low, ranging from 24 to 48 m g/g in the 15 cm to 60 cm zone of the soil at all three sites (Appendix Table 10). It continued to be low in the 60 to 90 cm zones at two of the sites, 1 km W and 2 km SE of the battery. The third site, 125 m from the battery, was the exception with levels of SO4 increasing to 114 m g/g in the 60 to 90 cm zone and 132 m g/g in the 90 to 120 cm zone. It is unlikely that the SO4 in the deeper soils at the closest site was caused by the operation of the battery. If the elevated SO4 had originated from airborne deposition of sulphur compounds, the samples closer to the surface would also have been enriched. In any case, the concentration of SO4 in the deeper soils is lower than the amounts reported in by Eilers et al (1978) which indicates that there has been no abnormal elevation of SO4 in the soils of the study area.

The total S in the soil was highest at the surface and decreased with depth at all three sites. At first, one might wonder whether this was the result of the deposition of sulphur compounds at the surface. However, for this to be the case total S in the organic and near surface mineral layers close to the battery would have been elevated and that was not observed. Rather, the S appears to be from the decaying plant material at the soil surface which was to be expected given that S in aspen leaves was often in the 1000 to 3000 m g/g range.

Available Sulphate in Soil

Figure 5. Mean concentration of available sulphate in surface organic and the mineral soil directly beneath it along the W transect.

Total Sulphur in Soil

Figure 6. Mean concentration of total sulphur in surface organic and the mineral soil directly beneath it along the SE transect.

Total Sulphur in Soil

Figure 7. Mean concentration of total sulphur in surface organic and the mineral soil directly beneath it along the W transect.

Conclusions

  • Although several plants in the study area and control farm had leaf injury, disease (mostly fungus) or insects caused all the symptoms. There were no visible symptoms of SO2 injury on plants in this study area and there were no plant injuries that might have been caused by other pollutants.
  • Although many of the same fungal diseases found in trees and shrubs of farmyards in the study area were also found in the control yard, there appeared to be more infected leaf tissue in the study area. This was probably a result of natural variability in such an abnormally wet year but the study was not able to rule out the remote chance that sulphur compounds in the air may have made the plants more susceptible to disease.
  • The sulphur content of aspen leaves suggested that there may have been some elevation caused by the battery emissions at one close-in site, but the data were too variable to reach a definitive conclusion. S in aspen leaves was in the normal range and would not be detrimental to plant health.
  • Available sulphate in the surface soil was slightly elevated at locations within 500m of the 8-8 battery. Considering the small data set and the variability in the data, there is no conclusive evidence that emissions of sulphur compounds were the cause. Sulphate content of soils was in the low part of the range or less than that reported for the same soil type at another location in the southwest corner of Manitoba.
  • Total sulphur in the soil was variable and the concentrations did not decrease with distance from the 8-8 battery, indicating that sulphur compounds emitted from the battery did not affect this parameter.

References

Dreisinger, Bruce R. and Peter C. McGovern. 1970. Monitoring Atmospheric Sulphur Dioxide and Correlating its Effects on Crops and Forests in the Study Area. Proceedings of the Impact of Air Pollution on Vegetation Conference Toronto, Ontario, April 7-9, 1970. p.11-28.

Eilers, R. G., L. A. Hopkins, and R. E. Smith. 1978. Soils of the Boissevain-Melita Area. Manitoba Soil Survey Report No. 20. Canada-Manitoba Soil Survey 204 pp.

Green, Don. Forage Specialist, Manitoba Agriculture, Carman, Manitoba. Personal Communication.

Malhotra, S. S. and D. Hocking. 1976. Biochemical and Cytological Effects of Sulphur Dioxide on Plant Metabolism. New Phytol. 76: 227-237.

Freedman, B. and T. C. Hutchinson. 1980. Pollutant Inputs from the Atmosphere and Accumulations in Soils and Vegetation near a Nickel-Copper Smelter at Sudbury, Ontario, Canada. Can. J. Botany 58: 108-132.

Shipley, B. L. 1975. Short and Long Term Effects of Sulphur Gas Emissions on the Gray Wooded and Dark Gray Wooded Soils as Evidenced by Studies in the Whitecourt and Edson Forest Regions of Alberta. Proceedings of Alberta Sulphur Gas Research Workshop II. p.84-93.

Hocking, D. 1975. Interim Report on the Long-term Impact on the Forest of Emissions from a Sulphur Extraction Plant. Proceedings of Alberta Sulphur Gas Research Workshop II. p.132-138.

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Appendix: Data Tables

Table 5. Aspen tissue analysis data (m g/g except for N%) for sites SE of the 8-8 battery

 
Distance
Control
Analyte
Date
Rep
125 m SE
250 m SE
500 m SE
1000m SE
2000m SE
21 km NE
Total S May 31/99
1
2090
1740
2120
1570
1540
  
   
2
1870
1780
1770
1610
1170
  
   
3
1920
1510
1970
1530
1370
  
  July 14/99
1
2520
2850
2020
1260
1360
  
   
2
1900
2890
1630
1530
1040
  
   
3
2230
1730
1810
1170
1220
  
  Aug 25/99
1
1780
2250
1470
1450
1720
1710
   
2
1580
1900
2080
1320
1480
1330
   
3
3530
1940
1690
1300
1180
1510
Total Fe May 31/99
1
69
49
54
56
72
  
   
2
62
44
138
60
62
  
   
3
56
46
56
69
78
  
  July 14/99
1
122
68
90
78
130
  
   
2
86
44
93
83
100
  
   
3
106
89
93
68
113
  
  Aug 25/99
1
149
122
114
95
223
122
   
2
123
123
137
87
179
151
   
3
244
113
120
131
127
162
Avail. N % May 31/99
1
3.74
3.13
4.31
3.44
2.54
  
   
2
3.3
2.63
4.2
3.34
2.94
  
   
3
3
2.49
4.13
3.22
2.67
  
  July 14/99
1
2.24
2.4
2.88
2.33
2.4
  
   
2
1.89
1.82
3.11
2.7
2.15
  
   
3
2.78
2.34
2.8
2.22
2.36
  
  Aug 25/99
1
1.75
1.75
1.65
1.94
1.61
2.8
   
2
1.75
2.06
1.99
1.92
1.95
2.8
   
3
1.77
1.69
1.88
2.05
1.82
2.0
Total P May 31/99
1
3160
2690
5630
3630
2620
  
   
2
3540
3080
5250
3670
2740
  
   
3
3060
2600
4980
3530
2300
  
  July 14/99
1
1800
1500
2290
2020
1590
  
   
2
1460
1560
2220
2180
1610
  
   
3
1790
1610
1920
1810
1800
  
  Aug 25/99
1
1600
1390
1580
1850
1540
2110
   
2
1600
1710
1810
1820
1410
1960
   
3
1600
1610
1850
1970
1630
1900
Total K May 31/99
1
13500
10600
19300
14800
10400
  
   
2
12300
9910
16500
15000
10700
  
   
3
11300
9690
16200
13900
9730
  
  July 14/99
1
5670
7160
8470
7750
9750
  
   
2
5240
7380
10200
8130
5350
  
   
3
5450
8340
7500
7180
7760
  
  Aug 25/99
1
5110
4590
3300
6450
7030
6880
   
2
5610
5830
4590
5610
6710
7490
   
3
8790
5790
7110
6640
5170
8740

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Table 6. Aspen tissue analysis data (m g/g except for N%) for sites W of the 8-8 battery.

     
Distance
Analyte
Date
Rep
125 m W
250 m W
500 m W
1000m W
2000m W
Total S May 31/99
1
1700
1410
1330
1290
2570
   
2
2200
1230
1670
1210
2170
   
3
2020
1350
1620
1420
2380
  July 14/99
1
3050
2110
1590
846
1930
   
2
2530
1820
1340
837
4510
   
3
2880
1350
2060
881
820
  Aug 25/99
1
4390
1640
1660
1400
2600
   
2
3980
1750
1450
2510
4500
   
3
5530
1850
1590
1220
6750
Total Fe May 31/99
1
43
56
63
99
84
   
2
50
50
70
70
53
   
3
57
49
64
76
79
  July 14/99
1
115
83
79
113
77
   
2
72
83
66
105
69
   
3
77
78
94
93
78
  Aug 25/99
1
167
131
130
145
176
   
2
173
94
127
174
112
   
3
174
120
112
117
110
Avail. N % May 31/99
1
2.09
2.86
3.71
3.66
5.22
   
2
2.19
2.92
3.65
3
3.59
   
3
2.79
3.06
3.33
2.83
5.06
  July 14/99
1
2.46
2.98
2.2
3.27
3.17
   
2
2.29
2.71
2.39
2.3
2.1
   
3
2.4
2.6
3.51
1.87
2.22
  Aug 25/99
1
1.85
1.54
1.71
1.61
1.57
   
2
1.86
1.67
1.78
1.63
2.04
   
3
1.61
1.75
1.85
1.26
2.05
Total P May 31/99
1
2280
2790
3570
4070
6340
   
2
2220
2890
4770
3220
3170
   
3
3020
3010
3720
3210
6080
  July 14/99
1
1650
1980
2170
2460
1880
   
2
1650
1740
1820
1910
1570
   
3
1880
2110
2420
1820
1740
  Aug 25/99
1
1500
1710
1680
1560
1510
   
2
1700
1840
2000
1380
1580
   
3
1650
1660
1770
1280
1640
Total K May 31/99
1
10300
9940
14600
11400
21900
   
2
10300
10100
17400
11100
13500
   
3
12000
9500
13300
11400
20700
  July 14/99
1
12600
8670
10100
5540
11800
   
2
9170
7700
9910
9390
10000
   
3
8450
10200
10600
7590
11300
  Aug 25/99
1
7450
8080
8110
5520
4540
   
2
8150
8230
12300
5820
6850
   
3
7060
7400
7730
6570
7030

Table 7. Alfalfa tissue analysis data (m g/g) for sites in the vicinity of the 8-8 battery.



Analyte


Rep
Site, Distance and Direction
Yard 1
1.7 km E
Yard 2
2 km SE
Yard 3
2.4 km SSW
Ditch
1.6 km W
Total S
1
1730
3020
1200
3420
 
2
2860
2190
1350
4050
 
3
1600
2220
1510
2800
Total Fe
1
73
75
107
239
 
2
96
84
140
231
 
3
53
105
222
136
Total P
1
3340
2640
2520
1980
 
2
4300
2710
2860
1990
 
3
2910
2770
2930
1880
Total K
1
27200
31000
27600
14900
 
2
47700
21500
28600
23100
 
3
30000
24500
25100
14600
Total Se
1
0.57
0.43
0.46
0.25
 
2
0.82
0.37
0.64
0.13
 
3
0.6
0.35
0.82
0.08

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Appendix: Data Tables

Table 8. Soil analysis data (m g/g) for soil samples collected at sites SE of the 8-8 battery.

Analyte
Soil Type
Replicate #
Distance from the 8-8 Battery
Control
125m SE
250m SE
500m SE
1000m SE
2000m SE
21 km NE
Avail. SO4 Organic
1
171
258
66
33
33
168
c *
2
93
1420
180
54
21
138
*v *
3
159
240
252
2100
231
240
* Mineral
1
18
195
51
24
18
96
* *
2
75
720
60
15
18
47
* *
3
120
252
150
72
24
105
Total S Organic
1
857
925
893
517
818
1550
* *
2
673
1060
1240
844
687
1330
* *
3
851
796
1110
910
1000
1230
* Mineral
1
632
878
1080
496
1060
705
* *
2
628
990
892
467
797
591
* *
3
602
792
851
619
1040
796
NO3-NO2 Organic
1
27.9
41.9
16.6
28.4
18.9
10.4
* *
2
27.7
18.9
151
34.5
28.4
8.4
* *
3
33.4
40.2
42.6
53.2
48.5
10.4
* Mineral
1
14.8
16.1
21.6
10.8
24.5
6.4
* *
2
13.3
11.8
24.5
9.7
23.7
7.2
* *
3
9.5
14.2
22.4
10.8
19.9
7.6
Avail. PO4 Organic
1
10.8
23.3
27.4
25.3
30
10.0
   
2
12.2
16
63.6
25.8
20.6
19.0
   
3
22
33.3
78.3
29.4
27.9
39.0
  Mineral
1
6.4
9.1
18.2
12.8
11.3
2.6
   
2
7.4
10.8
16.9
4.4
25
13.0
   
3
8.1
10.8
27.4
7.4
9.3
584
Avail. K Organic
1
696
810
492
910
600
858
   
2
668
468
548
755
725
1370
   
3
912
975
660
750
615
1590
  Mineral
1
472
516
476
672
740
613
   
2
488
392
548
512
1030
578
   
3
504
448
572
584
592
584

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Table 9. Soil analysis data (m g/g) for soil samples collected at sites W of the 8-8 battery.

Analyte
Soil Type
Replicate #
Distance from the 8-8 battery
125m W
250m W
500m W
1000 m W
2000 m W
Avail. SO4 Organic
1
294
504
126
90
117
   
2
306
126
108
57
51
   
3
174
150
174
36
114
  Mineral
1
150
336
18
27
45
   
2
318
153
21
69
180
   
3
30
126
24
42
159
Total S Organic
1
711
846
691
1300
1110
   
2
697
752
790
883
1090
   
3
627
692
844
774
1390
  Mineral
1
530
900
624
763
927
   
2
798
785
599
766
1030
   
3
558
759
582
664
1140
N03-NO2 Organic
1
26
49.6
20.1
70.9
42.6
   
2
28.4
96.9
70.9
6.9
42.3
   
3
18.9
16.6
33.1
31.7
40.7
  Mineral
1
5.5
27.3
11.6
19.7
23.3
   
2
8.5
28.8
12.3
17.8
25.4
   
3
4.6
27.5
7.8
18
19.9
Avail. PO4 Organic
1
33.3
36.2
44
73.4
28.4
   
2
27.9
34.2
39.1
44
15.5
   
3
58.7
31.3
53.8
34.2
33.3
  Mineral
1
18.2
13.2
8.8
33.3
5.9
   
2
17.2
9.8
15.2
12.8
3.7
   
3
23.8
8.3
15.7
19.1
5.9
Avail. K Organic
1
710
600
720
1080
584
   
2
504
530
720
1170
580
   
3
1060
665
630
850
855
  Mineral
1
412
480
468
940
524
   
2
540
500
508
1080
476
   
3
720
576
508
552
508

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Table 10. Soil analysis data (m g/g) for deeper mineral soils collected at selected sites in the vicinity of the 8-8 battery.


Analyte

Depth
Distance and Direction
Control
125m SE
2000m SE
1000m W
21 km NE
Avail. SO4 15-30 cm
24
48
30
62
  30-60 cm
45
24
24
37
  60-90 cm
114
33
21
30
  90-120 cm
132
*
*
37
Total S 15-30 cm
615
824
525
700
  30-60 cm
427
277
219
169
  60-90 cm
532
210
184
254
  90-120 cm
331
*
*
621
NO3-NO2 15-30 cm
11.4
12.3
14.2
9.4
  30-60 cm
4.6
2.1
4.9
3.0
  60-90 cm
3
2.3
4.2
2.2
  90-120 cm
1.7
*
*
1.8
Avail. PO4 15-30 cm
3.4
2.4
23.6
2.0
  30-60 cm
0.5
0.5
4.4
0.5
  60-90 cm
0.5
0.5
2
0.5
  90-120 cm
0.5
*
*
0.5
Avail. K 15-30 cm
289
528
852
540
  30-60 cm
113
126
524
302
  60-90 cm
75
126
254
302
  90-120 cm
51
*
*
149

* stones encountered, no sample collected

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