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Technical Report WRA83038
Viewed at 04:02:30 on 18/02/2010 Page 1 of 15.
CONTENTS :
1. Introduction
2. Geology of the area
3. Survey objectives
4.
5.
6.
Instrumentation
Field techniques
Results
Technical Report WRA83038
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1. INTRODUCTION
During the period 6.6.83 to 10.6.83 resistivity surveys were conducted at Neutral Junction ~~d Pine Hill Stations by staff of the Water Division, Northern Territory Department of Transport and Works.
In this time 8 line-kilometres of two electrode resistivity profiling, 2 line-kilometres of pole-dipoxe resistivity profiling and 3 vertical electrical soundings (VES) were completed by a crew of 1 geophysicist and 3 field assistants.
This work was done to assist the Division's Hydrogeology Section in the siting of water bores as part of its rural advisory service.
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2. GEOLOGY OF THE AREA
2.1 Neutral Junction
The survey area lies on the western side of the stuart Highway approximately 15 km s.w. of the Crawford Range and is covered by the Barrow Creek 1.250 000 geological series map. In this area archean gneisses and schists have been intruded by proterozoic granites. Associated with the intrusions shear zones have developed and been infilled with pegmatite.
2.2 pine Hill
This area is covered by the Reynolds Range 1:100 000 map. 3 to 4 kilometres north of the station homestead, at the base of the southern margin of the Anmatjira Range, proterozoic gneisses and sohists have been faulted against felsic granulite. The faulting has been regional in extent but in the area of interest its exact position is unknown.
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3. SURVEY OBJECTIVES
3.1 Neutral Junction
The resistivity survey was designed to firstly investigate the subsurface electrical conditions near to, and to the south of bore ~~ 13629. This hole had been sited to intersect a suspected shear zone but had yielded only a small (0.1 Lis) supply of very good quality water. On the basis of resistivity measurements it was hoped to either more accurately position a new bore within the fracture zone r or site another along strike in an area of more favourable recharge.
The problem, in geoelectrical terms, translates into searcn~ng for a probably conductive anomaly that could be caused by a subvertically dipping body extensive in both strike direction and depth.
3.2 Pine Hill
The aim o£ £~e resistivity survey was to accurately locate the regional fault which might act as a collector of run off from the Anmatjira Range. Further it was hoped that some areas (crush zones) more favourable to the entrapment of groundwater might be detected.
A simple fault between differing rock types would be expected to manifest itself as two blocks of differing resistivity while a crush zone would presumably add a conductive anomaly to this picture.
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4. INSTRUMENTATION
The resistivity instrumentation used is fully doclli~ented in Geophysical Report 82/1. Briefly, it consisted of a 300 W DC/DC,convertor employed as a transmitter while a high impedance digita~ volmeter was used as a receiver •
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5. FIELD TECHNIQL~S
5.1 Neutral Junction
5.1.1 Surveying:
Both traverses were marked out using tape' and compass. Traverse 1 was situated to begin near ~~ 13629 as shown in figure I, and was orientated north-south. Traverse 2 was placed 2.5 kID to the east also northsouth and was intended to coincide with the supposed location of the vein near its midpoint.
5 1 2 P f'l' . . _ ro ~ ~ng :
The pole-dipole array was used on both traverses and the two electrode array on traverse 1 onlv. Details of array geometri~s, plotting point and p:;'ofiling direction are given in figure 1. On all traverses the remote electrodes were emplaced 1000 m from the beginning, roughly at right angles to traverse direction. For the two electrone profiling, where 2 remote electrodes were needed, their mutual separation was 2000 m.
The array geometries used were chosen to enable subsurface investigation to be as deep as possible while retaining both lateral resolution and good received signal strength. No VES were felt necessary initially since observation in the area revealed that the surface cover was very thin .
5.1.3 sounding :
One schlumberger VES was carried out on traverse 2 in the position indicated in figure 1. The half current separation (AB/2) was expanded to 215 m while the halfpotential electrode separation, (MN/2) was moved from .3 m to 10 m with one intermediate step. AB/~m was kept ~5. The frequency of sampling was 6 points/decade.
5.2 Pine Hill
5.2.1 Surveying
All three traverses were marked out using tape and compass and all were orientated north-south. Traverse 3 is approximately 3.5 km north of the Pine Hill Homestead and .5 km west. Traverse 1 is 1.5 km west along the fault line and traverse 2 is in turn a further .5 km west from there.
5.2 .. 2 sounding:
VES PH-l and PH-2 were done at the origin of each of traverses 1 and 2 as a check on subsurface resistivities and as a guide to array geometries. Observation frequency was 6 points/decade.
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5.2.3 Profiling:
The two electrode array was used throughout the survey. Details of interelectrode distances, plotting point and profiling direction are given in figure 6. The remote electrodes were emplaced 1000 ill
at right angles to the traverse direction, with the mutual separation being 2000 m.
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6. RESULTS
6.1 Neutral Junction
6.1.1 profiling:
The results of the resistivity profiling are shown in figure ,1. with reference to traverse 1, the most obvious feature is a general increase in apparent resistivity with increasing station number. The feature most pertinent to this investigation is the low at station 300. A possible interpretation is a conductive dykelike body positioned as shown in figure 2(a). The theoretical curves for this and all succeeding models have been computed on the basis of infinite extent in both strike and depth. The correspondence between observed and theoretical data would be closer if the background trend was removed from the observed data.
A conductive body of similar dimensions and position may also be inferred from the two electrode results (figure 2(b)) but with less confidence because of the low amplitude of the anomaly and the strong background trend. .~
The need for caution in interpretina these results _ J
is underlined by figure 2(c). Here. the pole-dipole data from traverse 2 is ';lell matched to ~'le anomaly due to a resistive body yet the anomalies of traverse 1 and 2 are not very different .
. 6.1.2 Sounding :
The VES presented in figure 3 was done primarily as a check on the values chosen for the array dimensions.
For the completeness the interpretation shown is offered with this note. The sharply rising terminal branch exceeds the maximum theoretical gradient and is probably caused by the relatively shallow basements being other than flat lying.
6.2 Pine Hill
6.2.1 Sounding:
The results of the two VES are given in figures 4 and 5. Because of the lack of generally available interpretation procedures for this array, the models given have been arrived at by a trial and error computer based curve matching procedure. The fits obtained are not good but serve to indicate the generally thin surficial cover. Although relatively small a spacings ( ~ 10 m) could be used to reflect bedrock resistivities, much larger dimensions (50 m & 100 m) were chosen in the hope that any indications might lead to deeper more reliable supplies. .
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6.2.2 profiling:
The most immediately obvious feature of all !:..l-J.e pro-files is the generally increasing measured resistivity observed as the foot of the Mrr,atjira Range is approached; i.e. with increasing station nQ~ber.
The position of the fault on traverses 1 and 2 has been marked beneath those profiles in figure 6. These have been deduced after comparison with theoretical curves. The fault zone beneath traverse 2 seems to have more width than that of. traverse 1.
No fault position has been given for traverse 3. Here there is very little resistivity contrast over the length of the line. This is probably due to the materials separated by the fault being very similar; i.e. gneiss and granulite compared to schist and granulite on traverses 1 and 2.
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Technical Report WRA83038
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Technical Report WRA83038
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Technical Report WRA83038
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Technical Report WRA83038
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