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Mapping in the Oman ophiolite using enhanced Landsat Thematic Mapper images
7-ecton~@~rts.
3x7
151 (1988) 387-401
Elsevier Science Publishers
B.V.. Amsterdam
Mapping
- Printed
in The Netherlands
in the Oman ophiolite using enhanced Thematic Mapper images M.J. ABRAMS ‘, D.A. ROTHERY
Landsat
’ and A. PONTUAL ’
’ Jet Propulsion Lahorufor3;. California Institute of Technology, 4NO0 Ouk Grow Driw. Pasudenu, CA 91 100 (ti. S.A.) ’ Department
MK7 frAA (Great RriruinJ
of Earth Sciences, The Open C’nicersr(v. Milton Kqvnes, Butkinghum.~hire (Received
July 3. 1987: revised version
accepted
December
8, 1987)
Abstract Ahrams,
M.J., Rothery.
Mapper
images.
D.A. and Pontual,
In: F. Boudier
The large area1 extent programmes changes
and minor
images
ophiolite
outcrops
mapping.
the capacity products,
and complex
in the Oman
exhaustive
ultramafic
it is possible
intrusions.
to delineate
gossans
the area of a lo x lo
mapping
areas
across
dispersed
than
previously
appreciated.
provided
by the imagery.
Such data
semi-arid
regions,
even where already
infrared
in gabbro mantle
The significance
alteration. of certain
The Oman ophiolite is the largest and complete example of well-exposed ocean
mapping
faults
field-based. Recognition
Thematic
rock
types
stretching
to identify mantle.
Off-axis
Thematic
15 1: 387-401.
mapping of subtle
in the field only by unrealistically
Decorrelation
composition,
largely quality.
Landsat
of different
from the deeper
be a valuable
mapped
spectrum.
reflectances
to chloritic-epidotic could
inconsistent
Landsat
Tectonophyxicr.
that previous,
of internally
the whole ophiolite.
variations
the uppermost
subject
has meant
using enhanced
of Oman.
map sheet is possible
in the spectral
to recognize
to discriminate and
maps
ophiolite
The Ophiolites
of the terrain
of the short-wavelength
on distinctions
and to allow consistent in which
nature
in the Oman
(Editors),
have produced
across
By using parts
to capitalize
A., 1988. Mapping
and A. Nicolas
Mapper
and
their
data
of these data produces
small acidic.
gabbroic
to locate the Mohn precisely.
plutonism
is reassessed
tool in similarly
have
weathering
is more
widespread
and and and
in the light of new insights exposed
terrains
in arid
and
at the 1 : 100,000 scale.
contains a complete ophiolite sequence from tectonized and variably serpentinized harzburgite (the mantle sequence), passing upwards into
most floor
rocks now outcropping on land. Knowledge of its structure and petrology can cast much light on our understanding of processes occurring at and near modern-day oceanic spreading axes. It was formed by sea-floor spreading at about 95 Ma and had
layered cumulate gabbro and peridotites and isotropic or ‘high-level’ gabbro (and occasional less mafic differentiates) which formed in axial magma chambers, and sheeted dykes and pillow lavas fed from these magma chambers. Off-axis magmatism is manifested by a later series of lavas and ultra-
been emplaced over the Arabian continental margin by about 70 Ma. The ophiolite forms a sheet-like nappe covering an area of about 20,000 km2 (Fig. 1). Much of the recent work on the Oman ophiolite was synthesized by Lippard et al. (1986). It
mafic to acidic late-intrusive complexes. The ophioiite has virtually no soil or vegetation cover and forms rugged mountainous terrain at elevations mostly between 500 and 1500 m. Exposure of the rocks is excellent, though there is often a large amount of virtually in situ debris
O~O-1951/88/%03.50
@ 1988 Elsevier Science
Publishers
B.V
5WE
58%
ophiolite nappe)
24*1
L 58*E
Fig. 1. Generalized map of the northern part of tbc Oman ophiolite indicating the areas shown in more detail in Plates l-3 and 4-6. The area illustrated by Rothery (1987a) is on the south side of the Plate l-3 box.
which hinders precise mapping of specific contacts. The only map showing the whole of the Oman ophiolite in any detail is that produced by Glennie et al. (1974) at 1: 500,000. Thiswasproduced by interpretation of black and white air photographs backed up by a limited rmmber of field traverses. It was an excellent piece of work but contained many errors, omissions and oversimplifications, and was on too small a scale to i&&ate many important relationships. Subsequently, the northcentral part of the ophioiite (from the U.A.E. border to the Sumail Gap) was mapped at 1: lOtI, by the Open University Oman Ophiolite Project using extensive fiddwork tog&&r with p~t~t~~tat~~n (Smewing, 1979; Lippard, 1980; Lippard and Rothxy,1981; Browning and Lippard, 1982). Because of the nature of this project, during which eleven Ph.D. theses were
produced, parts of the sequence in certain areas were mapped in very great detail at much larger scale while several areas were covered on a reconnaissance-only basis. Other 1: 100,000 maps include a 35 km strip running south from Muscat based on the work of a U.S. team (Bailey, 1981), and thirteen sheets which cover the southeastern part of the ophiolite published in 19861987 by the Sultanate of Oman Ministry of Petroleum and Minerals Directorate of Minerals, based on field mapping by geologists from the French Bureau de Recherches C%ologiques et Mini&es. In this paper we show how enhanced imagee from the Landsat Thematic Mapper (TM) can provide coverage of the whole ophiolite to a consistent standard by taking advantage of the shortwavelength infrared reflectance properties of the ophiolite Cthologies. By way of example, we illustrate two areas (in different degrees of detail) which were mapped some years earlier by the Open University Oman Ophiolite Project. These are representative of the several areas of the opbiolite which we revisited in 1987 in order to investigate incompatibilities between the existing maps and our interpretation of the satellite images. In almost all cases, our new fieldwork showed the remote sensing imagery to be showing real lithological information which the earlier field and air photograph mapping had either misinterpreted, oversimplified or simply been unable to detect. We have previously outlined the level of apparent lithological discrimination possible with TM images in the Oman (Abrams, 1986; Rothery, 1987a), but now we are able to substantiate and refine this by incorporation of our new field observations. We are confident that the lithological discrimination revealed by the imagery is sufficiently uniform throughout the ophiolite to be used as a reliable mapping criterion. The TM date are adequate for producing lithological maps at 1: 100,000 scale and can show many details more appropriate to mapping at 1: SO,000 or better. Because of the large area and rugged nature of the terrain, it would be extremely difficult to map the ophiolite consistently and in such detail by conventional techniques alone. Map revision of a further area of the Oman ophiolite is presented in Rothery et al. (1988).
389
Spectral response of igneous rocks
Spectra of ophiolite lithologies
Spectral absorption features
Laboratory
reflectance
range of spectral In addition by remote
to the synoptic
sensing,
this method
another
range
surface,
The
provided
advantage
beyond spectrum
on the mineralogical which is usually
ophiolite
amples
of the idealized
spectral
reality
is partly
of its
of the whole-
rock mineralogy and weathering minerals. Absorption bands in the visible- and short-wavelength infrared can arise from either electronic or
covered
the following
and Salisbury
(1970)
review derived
Hunt
(1977). Electronic processes duction bands, charge
spectra
lithologies response,
or completely minerals.
surfaces
includes
masked
as exwhich in
by that of
The wavelength
by the TM are indicated
regions
above the reflec-
tance curves. The reflectance curve for limonite shows several broad and medium-width absorption features. The sharp fall-off in reflectance
vibrational processes in these minerals. Because most geologists are unfamiliar with these effects, we present
by some of the
in Fig. 2. The figure
the weathering
of the
weathered
from two unweathered
between
indicative
produced
is
of a rock
composition
a mixture
features
which may dominate
are shown
the visible
to discriminate
reflectance
minerals
of
field techniques
properties
of the spectrum types.
depends
major
over conventional
the use of reflectance rock
coverage
spectra
4 0.8 ir--T---TI
1.2
1.6
2.0
2.4
from Hunt
et al. (1974) and Hunt
include transfer
three types: and crystal
confield
effects. The first two phenomena are manifested by a pronounced decrease in reflectivity at wavelengths shorter than about 0.6 pm. The most likely source for such effects in igneous rocks is charge transfer in the Fe-O bond, as minerals containing this bond are ubiquitous on natural rock surfaces. Crystal field effects in the ions of transition metals give rise to several broad absorption bands, whose positions are a function of the metal involved. In this study,
iron ions are probably
all the detectable
bands.
responsible
The presence
for
of ferrous
iron (Fe”) can produce absorptions centred at about 0.65 pm, 1.0-1.1 pm, 1.8-1.9 pm, and 2.2-2.3 pm, depending on its lattice environment. Ferric iron (Fe3’) can produce absorptions at
HARZBURGITE
about 0.65 pm and 0.87 pm. The vibrational processes which cause visibleand short-wavelength infrared absorptions are bending and stretching vibrations of bonds within radicals or molecules. On igneous rock surfaces, the most important are due to Al-OH and Mg-OH in clays, micas, amphiboles and serpentine. Al-OH produces absorptions centred at about 2.2 pm, whereas Mg-OH produces features at about 2.3 pm. There are also features in the infrared due to vibrations within molecular water.
ABSORPTION Fe3+ -----I
Fe2+ H OH
wFe3+
I
I
CO3
% +P
Hz0
Hz0 1
I
I
0.8
4
FEATURES
Fez+
Fe3+ CI
I.2
I
I
I
I.6
2.0
1
2.4
WAVELENGTH, urn Fig. 2. Laboratory minerals lites,
reflectance
and rocks of importance
showing
obtained
spectral
the
Landsat
from coarse
and serpentinite
TM
particulate
are our own data;
(1971); and harzburgite
measurements
in remote band
passes.
samples: limonite
is from Hunt
sensing
of some of ophio-
Spectra
haematite,
were chlorite
is from Hunt et al.
et al. (7974).
390
short of 0.7 pm is due to a charge-transfer band in ferric iron, and the deep, broad band centred at about 0.9 ym is a ferric ion crystal field effect. The two small absorption bands at 1.4 pm and 1.9 pm are due to adsorbed water. The distinctive natural red-brown colour of limonite is caused by the relatively high reflectance in the red part of the spectrum near 0.7 pm. The chlorite spectrum shows characteristics of many hydrous minerals. The absorptions at 1.4 and 1.9 pm and the series of features between 2.0 and 2.4 pm are hydroxyl bands. The absorptions at 0.7 and 0.9 pm are due to ferric iron. The reflectance spectrum of haematite is dominated by ferric iron features; a strong fall-off in reflectance short of 0.55 pm due to charge transfer and a crystal field absorption near 0.9 I-Lm. Serpentinite shows a relatively flat spectral response. The shallow feature at 0.45 pm is due to ferric iron and the broader absorption centred near 1.0 pm is due to ferrous iron. The rather sharp band at 2.3 pm is due to vibrational processes of Mg-OH, and hydration effects are shown by the absorption near 1.4 pm. The hanburgite spectrum has a broad feature attributable to ferrous iron in pyroxene and olivine, centred near 1.0 pm. Remote sensing TM data
Our remote sensing data are from the Thematic Mapper scanner carried by Landsat(Barker, 1985). This instrument records data in seven spectral bands; six channels in the visible and reflected infrared part of the spectrum and one channel in the thermal infrared (Table 1). The reflected data are recorded with ground resolution cells (pixels) 30 x 30 m in size. Each scene covers an area 180 km wide and 180 km along track. Because the data are recorded in digital form, they can be handled on a computer using image processing techniques to extract, enhance and display that subset of information most appropriate to the problem being investigated.
TABLE Thematic
1 Mapper
bands
Channel
Wavelength (I.rm)
1
0.45-
0.52
2
0.52-
0.60
3
0.63-
0.69
4
0.76-
0.90
5
1.55-
1.75
6 7
10.4 -12.5 2.08-
2.35
The TM data used for this study are from scene number 50340-06140 acquired on February 4, 1985. Two sub-scenes are discussed here: a 25 x 42 km area in the east of the Salahi Block (Plate 1); and a 13 X 19 km area around Jebel Shaykh in the Fizh Block (Plate 4). Image processing
The image processing technique employed is to manipulate TM band triplets using “decorrelation stretching” (Soha and Schwartz, 1978). Decorrelation stretching is becoming a widely used technique, and has been discussed by Gillespie et al. (1986) and Rothery (1987a,b). This technique is based on a principal component transformation of the acquired data. Such transformed channels can themselves be contrast stretched and arbitrarily assigned primary colours for display as a colour composite image. Decorrelation stretch&g differs in that after contrast stretching, the statistically independent (decorrelated) principal component channels are subjected to the inverse transformation into the original coordinate system for display, with one decorrelation stretched band in red, one in green and one in blue. Generally, this enhancement causes little distortion in the perceived hues, but colour saturation is exaggerated which makes it possible to distinguish very subtle spectral reflectance differences. The effect of this is that interpretation is relatively straightforward, since colours can be interpreted in terms of the three TM bands used and related to the differences between the spectral reflectances of the materials in the scene (Plates 2 and 5). A compari-
son
between
decorrelation-stretched
simply processed ophiolite
respectively, nels,
was
reflectance minerals parison
of the three
7, 5 and 4) displayed partly
curves
for
infrared
on
4 contains
bands
(TM
seven TM chan-
analysis
of spectral
representative
ophiolitic
on interactive
other band combinations.
information
relating
as a similar tle, and dotite
in red, green and blue,
and rocks and partly of various
more
(1987a).
out of the possible based
and
of part of the Oman
was made by Rothery
The choice bands
TM imagery
purple
intrusions
text. Where the
colour
cumulate
mantle
the
man-
late-stage
peri-
of geological
peridotite
sequence,
con-
rests directly
two
are
best
on dis-
tinguished by their different characteristic drainage patterns. Trondhjemites, due to their acidic composition,
most
often
appear
show a variety
of colours
Band
of iron
oxide
and
ferences
in primary
of
from
on the basis
com-
to the presence
to the uppermost
is distinguishable
typically magenta.
orange Areas
as pink
areas
due to variable
hydroxide
coating
mineralogy.
Sheeted
but
degrees and
dif-
dykes are
to red, and lavas appear mostly which are especially affected by
iron; band 5 serves to characterize the general albedo of the materials and to highlight certain altered (ferric iron bearing) rocks which have par-
chloritic-epidotic
ticularly high reflectances near 1.6 pm, whereas ferrous iron can cause depression of the reflec-
sheeted dykes and upper parts of the gabbros) tend to appear orange, due to strong ferric iron
tance curve in this region. Band 7 responds to the presence of hydroxyl-bearing minerals by a reduc-
absorption
tion in reflectance due to various hydroxyland H,O-related features. Images using other band combinations proved less satisfactory overall for discriminating rock types in the study areas. Image interpretation The decorrelation-stretched images to make preliminary revisions to
enabled us lithological
alteration
in band
(notably
4, resulting
within
in a degree
of
ambiguity in lithological interpretation. Field traverses were undertaken to check some of the numerous discrepancies between the published maps and our image interpretation. Field observations revealed that in almost every case the geological maps were in error, and that the images properly depicted the geological relations. In addition to correctly allowing identification of erroneously mapped rock types and identifying subdivisions, the images allowed interpretation
new and
boundaries and structures shown on the existing geological maps prior to going into the field (Abrams, 1986; Rothery, 1987a). Colours of rock
mapping at more detailed scales than the published 1 : 100,000 mapping. Our final interpretation maps for the two areas are shown in Plates 3
types on the images and our interpretation of them in terms of the minerals and species whose
maps
absorption
images (Plates
features
we think
the decorrelation-stretched shown in Table 2. Almost
likely
to dominate
spectral response, are all the rock types are
distinct in colour and are separable on the images. The mantle sequence (harzburgite) appears in two distinct colour units: the upper part, for about 1 km below the Moho, is usually a purple colour; most of the rest of the mantle sequence appears as a dark green-yellow colour. Cumulate gabbro ranges
from cyan
through
to greenish-yellow,
re-
flecting differences in mafic content, whereas the high-level gabbros are most often yellow. The petrologic Moho, is usually a sharp boundary between purple mantle (tectonized harzburgite) and cyan cumulate gabbro. Cumulate peridotite, which is much less common than gabbro, appears
and
6 for comparison (Plates
1 and
with the Open 4) and
the
University
enhanced
TM
2 and 5).
Discussion
Following our fieldwork, we are now confident that the colour distinctions revealed by decorrelation stretching of the TM data. correlate with bedrock lithology and are only occasionally controlled by exposure effects such as screen slopes. Almost always they have direct meaning in terms of the petrology of the rocks and the surfaces, enabling us to revise boundaries and structures on previous maps and to subdivide certain previously mapped units, for example by discriminating between more mafic and less mafic gabbros.
392
Within the cumulate gabbros of the Sahthi Block we are readily able to distinguish many previously unmapped ultramafic pods only a few tens of metres thick (Plate 3). There is no clear reflectance difference between concordant peridotites (on-axis lenses within the axial cumulates) and discordant peridotites which we interpret as off-axis, intrusions (Browning and Smewing, 1981). The latter are distinguished on the imagery by their shape and occasional association with late-stage gabbro and/or trondhjemite bodies. We note that recent detailed studies (Juteau et al. 1988a,b) suggest that many concordant peridotite bodies of the type which we have mapped as cumulate peridotite, may in fact be off-axis intrusions. We have also detected many previously unmapped trondhjemites, several of which we confirmed in the field. Structural features within the crustal’ section of the Salahi Block are clarified by the recognition that the northwestwards-trending fault zone on the eastern side of the Salahi Block, which was mapped as a discontinuous feature by Lippard (1980) (Plate l), is in fact continuous for more than 30 km as shown by its prominence as a topographic lineament, juxtaposition of different ophiolite lithologies on either side, and the occurrence of late-stage peridotite, gabbro and trondhjemite intrusions often associated with epidotic alteration along its length. The strike of this feature is at an angle of 40” to the roughly N-S spreading axis demonstrated by sheeted dyke orientation. Unless the fault and associated zone of intrusion were diachronous and propagated as spreading progressed, then intrusions at the further end from the axis must have been at a minimum of about 15 km off-axis. The localization of
intrusive activity along the fault makes it clear that this is a seafloor- rather than emplacement-related fault. In the field there is no obvious and consistent difference between the two types of mantle sequence revealed as green and purple on the enhanced imagery. The Open University work revealed no major variations in primary mantle composition throughout the thickness of the nappe (Lippard et al., 1986), and our two types of mantle do not match the harzburgites (opx > 15%) and depleted harzburgites (opx 5-15s) or fit, except in a gross way, the variation in the degree of hydrothermal alteration of orthopyroxene mapped by Ceuleneer (1986). The general correlation between the “purple” mantle and depth below the Moho suggests that the cause may be related to subseafloor hydrothermal alteration or serpentinization. Nehlig and Juteau (this issue) provide evidence that in the Oman ophiolite, hydrothermal alteration extends at least as deep as the base of the crust though this is fraeture-controlled rather than pervasive. Whatever the cause of the mantle subdivision on our imagery, it is consistent throughout the length of the ophiolite. We await laboratory studies of material collected in the field to identify the compositional and spectral causes of this distinction. The purple colour shown by the mantle near the Moho is similar to the much narrower zones of purple colour running along late-stage fractures in the mantle which are interpreted as a post-emplacement serpentinization effect (Rothery, 1984a,b). The location of the petrological Moho is very clear where, as usual in the Salahi Biock, the mantle sequence passes upwards sharply into an
Plate 1. Geological map of the Salahi Block, based on previous Open University work (Lippard, 1980; Lippard and Rothery, 1981). See Fig. 1 for location. Units are as follows: L= basal serpentinite; MS = mantle sequence (tectonized harzburgite); Cp = cumulate peridotite; Cpg = cumulate peridotite and gabbro; Cg = cumulate gabbro; HLG = high-level (isotropic) gabbro; Df = 30-70s sheeted dykes in gabbro; 02 = > 70% sheeted dykes; 03 = 30-70s sheeted dykes in lava; Eu = upper lavas; El = lower lavas; P’ = late-intrusive peridotite; G’ = late-intrusive gabbro; Tr’ = late-intrusive trondhjemite (plagiogranite); HS = Hawasina sediments. Plate 2. Decorrelation stretched Landsat TM bands 7, 5, 4 (red, green and blue, respectively) colour composite of the area shown in Plate 1. Plate 3. Revised geological map of the area in Plate 1 based on interpretation of enhanced Landsat TM imagery supported by limited new field data. Units are as for Plate 1 except the mantle sequence has been divided into MS1 which appears green in Plate 2 and MS2 which appears purple in Plate 2 and occurs only near the Moho. Colour changes in the mantle sequence due to serpentinization along late-stage fractures have been ignored.
pp.393-395
CJ CJ
•
•
p'
EI
Hs Tr'
G' P'
EI
Eu
Eu
03
03
02
02
01
01
HLG
HLG
Cg
Cg
Cpg
Cp
Cp
MS2
MS
MS1
E
E Fault
- - Fault
Boundary Imprecise boundary ••••••• Trace of layering
Plate 1
Plate 2
Plate 3
pp. 396-398
Hs
D
Hs
D
Tr'
•
D
••
G'
Tr'
G' P'
EI
03
EI
02
03
01
02
HLG
01
Cg2
HLG
Cg1
Cg
- - Fault - - Fault
- - Boundary ____ Imprecise boundary ••••••• Trace of layering
Plate 4
Plate 5
Plate 6
399
TABLE
2
Colours
of rocks on decorrelation
stretched
TM images
(modified
Colour
Rock type
Main ophiolite
from Rothery.
1987a)
’
TM bands
Mineralogical
4B
5G
7R
explanation
sequence
Upper lava (Eu)
Magenta
M
L
M
Magnetite
Lower lava (El)
Dark magenta
M
L
M
Magnetite,
Dykes and lava (D3)
Dark red
L
L
M
Mixture
Dark orange
L
M
M
Fe.’ + (chlorite,
(Dl)
Orange
M
H
M
Mixture
Sheeted dykes (D2) Dykes and gabbro
epidote of El and D2 epidote)
of D2 and HLG
High-level
gabbro
(HLG)
Yellow-green
L
H
M
OH, limonite,
Cumulate
gabbro
(Cg)
Cyan-green-(yellow)
M
M-H
L-M
OH, Fe’
epidote
’
Dark purple
L-M
L
L
Serpentine,
mafic minerals
Mantle:
top (MS2)
Purple
M
L
M
Serpentine,
magnetite?
Mantle:
lower (MSl)
Green-yellow
L
M
L-M
Serpentine,
hematite?
Purple
L
M
L
Serpentine.
magnetite?
Cumulate
peridotite
Serpentinite
(Cp)
(e)
Late-rntrusives Pink, lilac
H-M
M-L
H
Low in OH and Fe
Gabbro
(G’) felsic
Yellow
L
H
H
Limonite.
hematite
Gabbro
(G’) mafic
Cyan-green
L
M-H
L
Limonite,
mafic minerals
Dark purple
M-L
L
L
Serpentine,
TrondhJemite
Peridotite
(T’)
(P’)
’ L = low; M = moderate;
essentially thus more it is now mensional
H = high; B = blue; G = green;
R = red.
scale layering seen on the imagery. The colour change from yellow through green to cyan on the enhanced imagery represents increasing mafic content. An area previously mapped as late-stage gabbro (the large area of G’ in the northeast of
gabbroic crustal sequence. The Moho is tightly constrained than previously, and feasible to attempt to map the three-direlief of the crust-mantle boundary.
The Jebel Shaykh area demonstrates of enhanced TM imagery for mapping
mafic minerals
the utility on a more
Plate ) on the basis of a dark tonal anomaly on 1 : 80,000 black-and-white air photographs did not
local scale. Jebel Shaykh is a region of high ground consisting of gabbros and dykes, separated from the gabbros and mantle sequence of the main part of the Fizh Block to the west by the low lying lava-filled “Alley” region (Smewing et al., 1977). The imagery (Plate 5) revealed colour variations within the gabbros which do not correlate with
consist of ratio-layered (cumulate) and unlayered (high-level) gabbro and a hitherto unrecognized belt of sheeted dykes. Many acidic, gabbroic and ultramafic late-intrusive bodies ranging in size
boundaries shown on the Open University maps (Smewing, 1979; Lippard, 1980) (Plate 4) and suggested the presence of layering in many places.
from about 1 km long to less than 100 m across were identified within the Jebel Shaykh massif, none of which had previously been recognized
Fieldwork showed that 2-20 cm-scale ratio and phase layering occurs parallel to the 30-100 m-
(Plate 6). The ability of yellow-red-magenta
Plate 4. Geological
Open
map of the Jebel Shaykh
correlate with colour boundaries on the enhanced TM imagery. In the field, this area was found to
area, based on previous
University
to map offsets between belts colours representing differ-
work (Smewing,
1979; Lippard.
1980). Units
are as for Plate 1. Plate 5. Decorrelation
stretched
Landsat
TM bands
7, 5, 4 (red, green and blue. respectively)
colour
composite
of the area shown in
Plate 4. Plate 6. Revised geological
map of the area in Plate 4 based on interpretation
new field data. Units are as for Plate 1 except that the cumulate blue on Plate 5. and Cg2. a less mafic member
appearing
gabbro
green-yellow
of enhanced
has been divided on Plate 5.
Landsat
TM imagery
supported
into Cgl, a more mafic member
by limited appearmg
400
ent proportions of gabbros, dykes and lavas, together with fault-controlled late-intrusive bodies, convinced us that there is much more faulting within the Jebel Shaykh region than has previously been recognised. We now know that Jebel Shaykh consists essentially of axial ophiolite lithologies with no large masses of late-intrusive or ambiguous high-level gabbro. This shows that the fault forming the western edge of Jebel Shaykh is probably an emplacement-related structure rather than a major seafloor feature. The Jebel Shaykh massif is therefore a normal ophiolite sequence repeated by a major normal fault near the trailing edge of the ophiolite nappe. Wider applications
The level of map revision described here can be performed throughout the ophiolite on the basis of similarly processed TM images. Our preliminary interpretation was greatly aided by the quality of the geological maps of the area and previous experience of the terrain. In the absence of such preexisting known information, it is unlikely that data with such coarse spectral resolution as Landsat TM will ever be sufficient for unequivocal identification of lithologies, although the data are sufficient for lithological discrimination under such circumstances. However, recent work (Pontual, 1988) shows that decorrelation stretched TM band 7, 5, 4 images similar to those used in this study can distinguish previously unmapped layering and reveal the hitherto unrecognized composite intrusive nature of the Cerro Colorado anorthositic gabbro massif in northern Chile. This shows that the experience gained from our Oman study may be applicable to well-exposed arid and semi-arid igneous terrains worldwide. We are less confident about extrapolation to terrestrial wellexposed temperate and polar regions or to the surfaces of other planets, where the effects of weathering may be very different. In vegetated terrains, the spectral response of the rocks may be completely masked by that of vegetation and soil. Conclusions
ophiolite lithologies. Using this imagery and with only a relatively small amount of field control, it is possible to map with a high degree of confidence, especially within the plutonic lithologies of the ophiolite. From the top of the gabbros upwards, alteration effects become more important and there are some ambiguities. It is especially easy to pick out ultramafic and trondhjemitic intrusions within the cumulate sequence and intrusions of all compositions within the dykes and lavas. Their prevalence shows that off-axis plutonism was more dispersed throughout the ophiolite than was previously appreciated. Such bodies cannot be detected in the field without detailed traverses, nor are they always identifiable on black-and-white air photographs. We recommend the use of enhanced shortwavelength infrared imagery for revision and refinement of lithological maps in Oman and similarly well-exposed semi-arid terrains elsewhere. Acknowledgements
We are grateful to the Sultanate of Oman Ministry of Petroleum and Minerals, particularly Mr Mohammad Kassim, for permission to work in Oman, and to Rachel Haymon and Mike Hughes-Clarke for logistical help. Work by Abrams was performed at the Jet Propulsion Laboratory, California Institute of Technology, under contract with the National Aeronautics and Space Administration. Rothery was funded by NERC Grant GR3/6388. Pontual is supported by a NERC Research Studentship. We thank the referees whose comments enabled us to improve the clarity of the text. References Abrams, M.J., 1986. Mapping the Oman ophiolite using TM data. In: Proc. Thematic Conf., Sth, Remote Sensing for Exploration Geology (Reno, Nevada, 29 September-2 85-95. Bailey, E.H., 1981. Geologic Map of the Muscat-Ibra
area,
Sultanate of Oman. J. Geophys. Res., 86: (pocket map). Barker, J.L. (Editor),
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Oc-
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Can.
3x7
151 (1988) 387-401
Elsevier Science Publishers
B.V.. Amsterdam
Mapping
- Printed
in The Netherlands
in the Oman ophiolite using enhanced Thematic Mapper images M.J. ABRAMS ‘, D.A. ROTHERY
Landsat
’ and A. PONTUAL ’
’ Jet Propulsion Lahorufor3;. California Institute of Technology, 4NO0 Ouk Grow Driw. Pasudenu, CA 91 100 (ti. S.A.) ’ Department
MK7 frAA (Great RriruinJ
of Earth Sciences, The Open C’nicersr(v. Milton Kqvnes, Butkinghum.~hire (Received
July 3. 1987: revised version
accepted
December
8, 1987)
Abstract Ahrams,
M.J., Rothery.
Mapper
images.
D.A. and Pontual,
In: F. Boudier
The large area1 extent programmes changes
and minor
images
ophiolite
outcrops
mapping.
the capacity products,
and complex
in the Oman
exhaustive
ultramafic
it is possible
intrusions.
to delineate
gossans
the area of a lo x lo
mapping
areas
across
dispersed
than
previously
appreciated.
provided
by the imagery.
Such data
semi-arid
regions,
even where already
infrared
in gabbro mantle
The significance
alteration. of certain
The Oman ophiolite is the largest and complete example of well-exposed ocean
mapping
faults
field-based. Recognition
Thematic
rock
types
stretching
to identify mantle.
Off-axis
Thematic
15 1: 387-401.
mapping of subtle
in the field only by unrealistically
Decorrelation
composition,
largely quality.
Landsat
of different
from the deeper
be a valuable
mapped
spectrum.
reflectances
to chloritic-epidotic could
inconsistent
Landsat
Tectonophyxicr.
that previous,
of internally
the whole ophiolite.
variations
the uppermost
subject
has meant
using enhanced
of Oman.
map sheet is possible
in the spectral
to recognize
to discriminate and
maps
ophiolite
The Ophiolites
of the terrain
of the short-wavelength
on distinctions
and to allow consistent in which
nature
in the Oman
(Editors),
have produced
across
By using parts
to capitalize
A., 1988. Mapping
and A. Nicolas
Mapper
and
their
data
of these data produces
small acidic.
gabbroic
to locate the Mohn precisely.
plutonism
is reassessed
tool in similarly
have
weathering
is more
widespread
and and and
in the light of new insights exposed
terrains
in arid
and
at the 1 : 100,000 scale.
contains a complete ophiolite sequence from tectonized and variably serpentinized harzburgite (the mantle sequence), passing upwards into
most floor
rocks now outcropping on land. Knowledge of its structure and petrology can cast much light on our understanding of processes occurring at and near modern-day oceanic spreading axes. It was formed by sea-floor spreading at about 95 Ma and had
layered cumulate gabbro and peridotites and isotropic or ‘high-level’ gabbro (and occasional less mafic differentiates) which formed in axial magma chambers, and sheeted dykes and pillow lavas fed from these magma chambers. Off-axis magmatism is manifested by a later series of lavas and ultra-
been emplaced over the Arabian continental margin by about 70 Ma. The ophiolite forms a sheet-like nappe covering an area of about 20,000 km2 (Fig. 1). Much of the recent work on the Oman ophiolite was synthesized by Lippard et al. (1986). It
mafic to acidic late-intrusive complexes. The ophioiite has virtually no soil or vegetation cover and forms rugged mountainous terrain at elevations mostly between 500 and 1500 m. Exposure of the rocks is excellent, though there is often a large amount of virtually in situ debris
O~O-1951/88/%03.50
@ 1988 Elsevier Science
Publishers
B.V
5WE
58%
ophiolite nappe)
24*1
L 58*E
Fig. 1. Generalized map of the northern part of tbc Oman ophiolite indicating the areas shown in more detail in Plates l-3 and 4-6. The area illustrated by Rothery (1987a) is on the south side of the Plate l-3 box.
which hinders precise mapping of specific contacts. The only map showing the whole of the Oman ophiolite in any detail is that produced by Glennie et al. (1974) at 1: 500,000. Thiswasproduced by interpretation of black and white air photographs backed up by a limited rmmber of field traverses. It was an excellent piece of work but contained many errors, omissions and oversimplifications, and was on too small a scale to i&&ate many important relationships. Subsequently, the northcentral part of the ophioiite (from the U.A.E. border to the Sumail Gap) was mapped at 1: lOtI, by the Open University Oman Ophiolite Project using extensive fiddwork tog&&r with p~t~t~~tat~~n (Smewing, 1979; Lippard, 1980; Lippard and Rothxy,1981; Browning and Lippard, 1982). Because of the nature of this project, during which eleven Ph.D. theses were
produced, parts of the sequence in certain areas were mapped in very great detail at much larger scale while several areas were covered on a reconnaissance-only basis. Other 1: 100,000 maps include a 35 km strip running south from Muscat based on the work of a U.S. team (Bailey, 1981), and thirteen sheets which cover the southeastern part of the ophiolite published in 19861987 by the Sultanate of Oman Ministry of Petroleum and Minerals Directorate of Minerals, based on field mapping by geologists from the French Bureau de Recherches C%ologiques et Mini&es. In this paper we show how enhanced imagee from the Landsat Thematic Mapper (TM) can provide coverage of the whole ophiolite to a consistent standard by taking advantage of the shortwavelength infrared reflectance properties of the ophiolite Cthologies. By way of example, we illustrate two areas (in different degrees of detail) which were mapped some years earlier by the Open University Oman Ophiolite Project. These are representative of the several areas of the opbiolite which we revisited in 1987 in order to investigate incompatibilities between the existing maps and our interpretation of the satellite images. In almost all cases, our new fieldwork showed the remote sensing imagery to be showing real lithological information which the earlier field and air photograph mapping had either misinterpreted, oversimplified or simply been unable to detect. We have previously outlined the level of apparent lithological discrimination possible with TM images in the Oman (Abrams, 1986; Rothery, 1987a), but now we are able to substantiate and refine this by incorporation of our new field observations. We are confident that the lithological discrimination revealed by the imagery is sufficiently uniform throughout the ophiolite to be used as a reliable mapping criterion. The TM date are adequate for producing lithological maps at 1: 100,000 scale and can show many details more appropriate to mapping at 1: SO,000 or better. Because of the large area and rugged nature of the terrain, it would be extremely difficult to map the ophiolite consistently and in such detail by conventional techniques alone. Map revision of a further area of the Oman ophiolite is presented in Rothery et al. (1988).
389
Spectral response of igneous rocks
Spectra of ophiolite lithologies
Spectral absorption features
Laboratory
reflectance
range of spectral In addition by remote
to the synoptic
sensing,
this method
another
range
surface,
The
provided
advantage
beyond spectrum
on the mineralogical which is usually
ophiolite
amples
of the idealized
spectral
reality
is partly
of its
of the whole-
rock mineralogy and weathering minerals. Absorption bands in the visible- and short-wavelength infrared can arise from either electronic or
covered
the following
and Salisbury
(1970)
review derived
Hunt
(1977). Electronic processes duction bands, charge
spectra
lithologies response,
or completely minerals.
surfaces
includes
masked
as exwhich in
by that of
The wavelength
by the TM are indicated
regions
above the reflec-
tance curves. The reflectance curve for limonite shows several broad and medium-width absorption features. The sharp fall-off in reflectance
vibrational processes in these minerals. Because most geologists are unfamiliar with these effects, we present
by some of the
in Fig. 2. The figure
the weathering
of the
weathered
from two unweathered
between
indicative
produced
is
of a rock
composition
a mixture
features
which may dominate
are shown
the visible
to discriminate
reflectance
minerals
of
field techniques
properties
of the spectrum types.
depends
major
over conventional
the use of reflectance rock
coverage
spectra
4 0.8 ir--T---TI
1.2
1.6
2.0
2.4
from Hunt
et al. (1974) and Hunt
include transfer
three types: and crystal
confield
effects. The first two phenomena are manifested by a pronounced decrease in reflectivity at wavelengths shorter than about 0.6 pm. The most likely source for such effects in igneous rocks is charge transfer in the Fe-O bond, as minerals containing this bond are ubiquitous on natural rock surfaces. Crystal field effects in the ions of transition metals give rise to several broad absorption bands, whose positions are a function of the metal involved. In this study,
iron ions are probably
all the detectable
bands.
responsible
The presence
for
of ferrous
iron (Fe”) can produce absorptions centred at about 0.65 pm, 1.0-1.1 pm, 1.8-1.9 pm, and 2.2-2.3 pm, depending on its lattice environment. Ferric iron (Fe3’) can produce absorptions at
HARZBURGITE
about 0.65 pm and 0.87 pm. The vibrational processes which cause visibleand short-wavelength infrared absorptions are bending and stretching vibrations of bonds within radicals or molecules. On igneous rock surfaces, the most important are due to Al-OH and Mg-OH in clays, micas, amphiboles and serpentine. Al-OH produces absorptions centred at about 2.2 pm, whereas Mg-OH produces features at about 2.3 pm. There are also features in the infrared due to vibrations within molecular water.
ABSORPTION Fe3+ -----I
Fe2+ H OH
wFe3+
I
I
CO3
% +P
Hz0
Hz0 1
I
I
0.8
4
FEATURES
Fez+
Fe3+ CI
I.2
I
I
I
I.6
2.0
1
2.4
WAVELENGTH, urn Fig. 2. Laboratory minerals lites,
reflectance
and rocks of importance
showing
obtained
spectral
the
Landsat
from coarse
and serpentinite
TM
particulate
are our own data;
(1971); and harzburgite
measurements
in remote band
passes.
samples: limonite
is from Hunt
sensing
of some of ophio-
Spectra
haematite,
were chlorite
is from Hunt et al.
et al. (7974).
390
short of 0.7 pm is due to a charge-transfer band in ferric iron, and the deep, broad band centred at about 0.9 ym is a ferric ion crystal field effect. The two small absorption bands at 1.4 pm and 1.9 pm are due to adsorbed water. The distinctive natural red-brown colour of limonite is caused by the relatively high reflectance in the red part of the spectrum near 0.7 pm. The chlorite spectrum shows characteristics of many hydrous minerals. The absorptions at 1.4 and 1.9 pm and the series of features between 2.0 and 2.4 pm are hydroxyl bands. The absorptions at 0.7 and 0.9 pm are due to ferric iron. The reflectance spectrum of haematite is dominated by ferric iron features; a strong fall-off in reflectance short of 0.55 pm due to charge transfer and a crystal field absorption near 0.9 I-Lm. Serpentinite shows a relatively flat spectral response. The shallow feature at 0.45 pm is due to ferric iron and the broader absorption centred near 1.0 pm is due to ferrous iron. The rather sharp band at 2.3 pm is due to vibrational processes of Mg-OH, and hydration effects are shown by the absorption near 1.4 pm. The hanburgite spectrum has a broad feature attributable to ferrous iron in pyroxene and olivine, centred near 1.0 pm. Remote sensing TM data
Our remote sensing data are from the Thematic Mapper scanner carried by Landsat(Barker, 1985). This instrument records data in seven spectral bands; six channels in the visible and reflected infrared part of the spectrum and one channel in the thermal infrared (Table 1). The reflected data are recorded with ground resolution cells (pixels) 30 x 30 m in size. Each scene covers an area 180 km wide and 180 km along track. Because the data are recorded in digital form, they can be handled on a computer using image processing techniques to extract, enhance and display that subset of information most appropriate to the problem being investigated.
TABLE Thematic
1 Mapper
bands
Channel
Wavelength (I.rm)
1
0.45-
0.52
2
0.52-
0.60
3
0.63-
0.69
4
0.76-
0.90
5
1.55-
1.75
6 7
10.4 -12.5 2.08-
2.35
The TM data used for this study are from scene number 50340-06140 acquired on February 4, 1985. Two sub-scenes are discussed here: a 25 x 42 km area in the east of the Salahi Block (Plate 1); and a 13 X 19 km area around Jebel Shaykh in the Fizh Block (Plate 4). Image processing
The image processing technique employed is to manipulate TM band triplets using “decorrelation stretching” (Soha and Schwartz, 1978). Decorrelation stretching is becoming a widely used technique, and has been discussed by Gillespie et al. (1986) and Rothery (1987a,b). This technique is based on a principal component transformation of the acquired data. Such transformed channels can themselves be contrast stretched and arbitrarily assigned primary colours for display as a colour composite image. Decorrelation stretch&g differs in that after contrast stretching, the statistically independent (decorrelated) principal component channels are subjected to the inverse transformation into the original coordinate system for display, with one decorrelation stretched band in red, one in green and one in blue. Generally, this enhancement causes little distortion in the perceived hues, but colour saturation is exaggerated which makes it possible to distinguish very subtle spectral reflectance differences. The effect of this is that interpretation is relatively straightforward, since colours can be interpreted in terms of the three TM bands used and related to the differences between the spectral reflectances of the materials in the scene (Plates 2 and 5). A compari-
son
between
decorrelation-stretched
simply processed ophiolite
respectively, nels,
was
reflectance minerals parison
of the three
7, 5 and 4) displayed partly
curves
for
infrared
on
4 contains
bands
(TM
seven TM chan-
analysis
of spectral
representative
ophiolitic
on interactive
other band combinations.
information
relating
as a similar tle, and dotite
in red, green and blue,
and rocks and partly of various
more
(1987a).
out of the possible based
and
of part of the Oman
was made by Rothery
The choice bands
TM imagery
purple
intrusions
text. Where the
colour
cumulate
mantle
the
man-
late-stage
peri-
of geological
peridotite
sequence,
con-
rests directly
two
are
best
on dis-
tinguished by their different characteristic drainage patterns. Trondhjemites, due to their acidic composition,
most
often
appear
show a variety
of colours
Band
of iron
oxide
and
ferences
in primary
of
from
on the basis
com-
to the presence
to the uppermost
is distinguishable
typically magenta.
orange Areas
as pink
areas
due to variable
hydroxide
coating
mineralogy.
Sheeted
but
degrees and
dif-
dykes are
to red, and lavas appear mostly which are especially affected by
iron; band 5 serves to characterize the general albedo of the materials and to highlight certain altered (ferric iron bearing) rocks which have par-
chloritic-epidotic
ticularly high reflectances near 1.6 pm, whereas ferrous iron can cause depression of the reflec-
sheeted dykes and upper parts of the gabbros) tend to appear orange, due to strong ferric iron
tance curve in this region. Band 7 responds to the presence of hydroxyl-bearing minerals by a reduc-
absorption
tion in reflectance due to various hydroxyland H,O-related features. Images using other band combinations proved less satisfactory overall for discriminating rock types in the study areas. Image interpretation The decorrelation-stretched images to make preliminary revisions to
enabled us lithological
alteration
in band
(notably
4, resulting
within
in a degree
of
ambiguity in lithological interpretation. Field traverses were undertaken to check some of the numerous discrepancies between the published maps and our image interpretation. Field observations revealed that in almost every case the geological maps were in error, and that the images properly depicted the geological relations. In addition to correctly allowing identification of erroneously mapped rock types and identifying subdivisions, the images allowed interpretation
new and
boundaries and structures shown on the existing geological maps prior to going into the field (Abrams, 1986; Rothery, 1987a). Colours of rock
mapping at more detailed scales than the published 1 : 100,000 mapping. Our final interpretation maps for the two areas are shown in Plates 3
types on the images and our interpretation of them in terms of the minerals and species whose
maps
absorption
images (Plates
features
we think
the decorrelation-stretched shown in Table 2. Almost
likely
to dominate
spectral response, are all the rock types are
distinct in colour and are separable on the images. The mantle sequence (harzburgite) appears in two distinct colour units: the upper part, for about 1 km below the Moho, is usually a purple colour; most of the rest of the mantle sequence appears as a dark green-yellow colour. Cumulate gabbro ranges
from cyan
through
to greenish-yellow,
re-
flecting differences in mafic content, whereas the high-level gabbros are most often yellow. The petrologic Moho, is usually a sharp boundary between purple mantle (tectonized harzburgite) and cyan cumulate gabbro. Cumulate peridotite, which is much less common than gabbro, appears
and
6 for comparison (Plates
1 and
with the Open 4) and
the
University
enhanced
TM
2 and 5).
Discussion
Following our fieldwork, we are now confident that the colour distinctions revealed by decorrelation stretching of the TM data. correlate with bedrock lithology and are only occasionally controlled by exposure effects such as screen slopes. Almost always they have direct meaning in terms of the petrology of the rocks and the surfaces, enabling us to revise boundaries and structures on previous maps and to subdivide certain previously mapped units, for example by discriminating between more mafic and less mafic gabbros.
392
Within the cumulate gabbros of the Sahthi Block we are readily able to distinguish many previously unmapped ultramafic pods only a few tens of metres thick (Plate 3). There is no clear reflectance difference between concordant peridotites (on-axis lenses within the axial cumulates) and discordant peridotites which we interpret as off-axis, intrusions (Browning and Smewing, 1981). The latter are distinguished on the imagery by their shape and occasional association with late-stage gabbro and/or trondhjemite bodies. We note that recent detailed studies (Juteau et al. 1988a,b) suggest that many concordant peridotite bodies of the type which we have mapped as cumulate peridotite, may in fact be off-axis intrusions. We have also detected many previously unmapped trondhjemites, several of which we confirmed in the field. Structural features within the crustal’ section of the Salahi Block are clarified by the recognition that the northwestwards-trending fault zone on the eastern side of the Salahi Block, which was mapped as a discontinuous feature by Lippard (1980) (Plate l), is in fact continuous for more than 30 km as shown by its prominence as a topographic lineament, juxtaposition of different ophiolite lithologies on either side, and the occurrence of late-stage peridotite, gabbro and trondhjemite intrusions often associated with epidotic alteration along its length. The strike of this feature is at an angle of 40” to the roughly N-S spreading axis demonstrated by sheeted dyke orientation. Unless the fault and associated zone of intrusion were diachronous and propagated as spreading progressed, then intrusions at the further end from the axis must have been at a minimum of about 15 km off-axis. The localization of
intrusive activity along the fault makes it clear that this is a seafloor- rather than emplacement-related fault. In the field there is no obvious and consistent difference between the two types of mantle sequence revealed as green and purple on the enhanced imagery. The Open University work revealed no major variations in primary mantle composition throughout the thickness of the nappe (Lippard et al., 1986), and our two types of mantle do not match the harzburgites (opx > 15%) and depleted harzburgites (opx 5-15s) or fit, except in a gross way, the variation in the degree of hydrothermal alteration of orthopyroxene mapped by Ceuleneer (1986). The general correlation between the “purple” mantle and depth below the Moho suggests that the cause may be related to subseafloor hydrothermal alteration or serpentinization. Nehlig and Juteau (this issue) provide evidence that in the Oman ophiolite, hydrothermal alteration extends at least as deep as the base of the crust though this is fraeture-controlled rather than pervasive. Whatever the cause of the mantle subdivision on our imagery, it is consistent throughout the length of the ophiolite. We await laboratory studies of material collected in the field to identify the compositional and spectral causes of this distinction. The purple colour shown by the mantle near the Moho is similar to the much narrower zones of purple colour running along late-stage fractures in the mantle which are interpreted as a post-emplacement serpentinization effect (Rothery, 1984a,b). The location of the petrological Moho is very clear where, as usual in the Salahi Biock, the mantle sequence passes upwards sharply into an
Plate 1. Geological map of the Salahi Block, based on previous Open University work (Lippard, 1980; Lippard and Rothery, 1981). See Fig. 1 for location. Units are as follows: L= basal serpentinite; MS = mantle sequence (tectonized harzburgite); Cp = cumulate peridotite; Cpg = cumulate peridotite and gabbro; Cg = cumulate gabbro; HLG = high-level (isotropic) gabbro; Df = 30-70s sheeted dykes in gabbro; 02 = > 70% sheeted dykes; 03 = 30-70s sheeted dykes in lava; Eu = upper lavas; El = lower lavas; P’ = late-intrusive peridotite; G’ = late-intrusive gabbro; Tr’ = late-intrusive trondhjemite (plagiogranite); HS = Hawasina sediments. Plate 2. Decorrelation stretched Landsat TM bands 7, 5, 4 (red, green and blue, respectively) colour composite of the area shown in Plate 1. Plate 3. Revised geological map of the area in Plate 1 based on interpretation of enhanced Landsat TM imagery supported by limited new field data. Units are as for Plate 1 except the mantle sequence has been divided into MS1 which appears green in Plate 2 and MS2 which appears purple in Plate 2 and occurs only near the Moho. Colour changes in the mantle sequence due to serpentinization along late-stage fractures have been ignored.
pp.393-395
CJ CJ
•
•
p'
EI
Hs Tr'
G' P'
EI
Eu
Eu
03
03
02
02
01
01
HLG
HLG
Cg
Cg
Cpg
Cp
Cp
MS2
MS
MS1
E
E Fault
- - Fault
Boundary Imprecise boundary ••••••• Trace of layering
Plate 1
Plate 2
Plate 3
pp. 396-398
Hs
D
Hs
D
Tr'
•
D
••
G'
Tr'
G' P'
EI
03
EI
02
03
01
02
HLG
01
Cg2
HLG
Cg1
Cg
- - Fault - - Fault
- - Boundary ____ Imprecise boundary ••••••• Trace of layering
Plate 4
Plate 5
Plate 6
399
TABLE
2
Colours
of rocks on decorrelation
stretched
TM images
(modified
Colour
Rock type
Main ophiolite
from Rothery.
1987a)
’
TM bands
Mineralogical
4B
5G
7R
explanation
sequence
Upper lava (Eu)
Magenta
M
L
M
Magnetite
Lower lava (El)
Dark magenta
M
L
M
Magnetite,
Dykes and lava (D3)
Dark red
L
L
M
Mixture
Dark orange
L
M
M
Fe.’ + (chlorite,
(Dl)
Orange
M
H
M
Mixture
Sheeted dykes (D2) Dykes and gabbro
epidote of El and D2 epidote)
of D2 and HLG
High-level
gabbro
(HLG)
Yellow-green
L
H
M
OH, limonite,
Cumulate
gabbro
(Cg)
Cyan-green-(yellow)
M
M-H
L-M
OH, Fe’
epidote
’
Dark purple
L-M
L
L
Serpentine,
mafic minerals
Mantle:
top (MS2)
Purple
M
L
M
Serpentine,
magnetite?
Mantle:
lower (MSl)
Green-yellow
L
M
L-M
Serpentine,
hematite?
Purple
L
M
L
Serpentine.
magnetite?
Cumulate
peridotite
Serpentinite
(Cp)
(e)
Late-rntrusives Pink, lilac
H-M
M-L
H
Low in OH and Fe
Gabbro
(G’) felsic
Yellow
L
H
H
Limonite.
hematite
Gabbro
(G’) mafic
Cyan-green
L
M-H
L
Limonite,
mafic minerals
Dark purple
M-L
L
L
Serpentine,
TrondhJemite
Peridotite
(T’)
(P’)
’ L = low; M = moderate;
essentially thus more it is now mensional
H = high; B = blue; G = green;
R = red.
scale layering seen on the imagery. The colour change from yellow through green to cyan on the enhanced imagery represents increasing mafic content. An area previously mapped as late-stage gabbro (the large area of G’ in the northeast of
gabbroic crustal sequence. The Moho is tightly constrained than previously, and feasible to attempt to map the three-direlief of the crust-mantle boundary.
The Jebel Shaykh area demonstrates of enhanced TM imagery for mapping
mafic minerals
the utility on a more
Plate ) on the basis of a dark tonal anomaly on 1 : 80,000 black-and-white air photographs did not
local scale. Jebel Shaykh is a region of high ground consisting of gabbros and dykes, separated from the gabbros and mantle sequence of the main part of the Fizh Block to the west by the low lying lava-filled “Alley” region (Smewing et al., 1977). The imagery (Plate 5) revealed colour variations within the gabbros which do not correlate with
consist of ratio-layered (cumulate) and unlayered (high-level) gabbro and a hitherto unrecognized belt of sheeted dykes. Many acidic, gabbroic and ultramafic late-intrusive bodies ranging in size
boundaries shown on the Open University maps (Smewing, 1979; Lippard, 1980) (Plate 4) and suggested the presence of layering in many places.
from about 1 km long to less than 100 m across were identified within the Jebel Shaykh massif, none of which had previously been recognized
Fieldwork showed that 2-20 cm-scale ratio and phase layering occurs parallel to the 30-100 m-
(Plate 6). The ability of yellow-red-magenta
Plate 4. Geological
Open
map of the Jebel Shaykh
correlate with colour boundaries on the enhanced TM imagery. In the field, this area was found to
area, based on previous
University
to map offsets between belts colours representing differ-
work (Smewing,
1979; Lippard.
1980). Units
are as for Plate 1. Plate 5. Decorrelation
stretched
Landsat
TM bands
7, 5, 4 (red, green and blue. respectively)
colour
composite
of the area shown in
Plate 4. Plate 6. Revised geological
map of the area in Plate 4 based on interpretation
new field data. Units are as for Plate 1 except that the cumulate blue on Plate 5. and Cg2. a less mafic member
appearing
gabbro
green-yellow
of enhanced
has been divided on Plate 5.
Landsat
TM imagery
supported
into Cgl, a more mafic member
by limited appearmg
400
ent proportions of gabbros, dykes and lavas, together with fault-controlled late-intrusive bodies, convinced us that there is much more faulting within the Jebel Shaykh region than has previously been recognised. We now know that Jebel Shaykh consists essentially of axial ophiolite lithologies with no large masses of late-intrusive or ambiguous high-level gabbro. This shows that the fault forming the western edge of Jebel Shaykh is probably an emplacement-related structure rather than a major seafloor feature. The Jebel Shaykh massif is therefore a normal ophiolite sequence repeated by a major normal fault near the trailing edge of the ophiolite nappe. Wider applications
The level of map revision described here can be performed throughout the ophiolite on the basis of similarly processed TM images. Our preliminary interpretation was greatly aided by the quality of the geological maps of the area and previous experience of the terrain. In the absence of such preexisting known information, it is unlikely that data with such coarse spectral resolution as Landsat TM will ever be sufficient for unequivocal identification of lithologies, although the data are sufficient for lithological discrimination under such circumstances. However, recent work (Pontual, 1988) shows that decorrelation stretched TM band 7, 5, 4 images similar to those used in this study can distinguish previously unmapped layering and reveal the hitherto unrecognized composite intrusive nature of the Cerro Colorado anorthositic gabbro massif in northern Chile. This shows that the experience gained from our Oman study may be applicable to well-exposed arid and semi-arid igneous terrains worldwide. We are less confident about extrapolation to terrestrial wellexposed temperate and polar regions or to the surfaces of other planets, where the effects of weathering may be very different. In vegetated terrains, the spectral response of the rocks may be completely masked by that of vegetation and soil. Conclusions
ophiolite lithologies. Using this imagery and with only a relatively small amount of field control, it is possible to map with a high degree of confidence, especially within the plutonic lithologies of the ophiolite. From the top of the gabbros upwards, alteration effects become more important and there are some ambiguities. It is especially easy to pick out ultramafic and trondhjemitic intrusions within the cumulate sequence and intrusions of all compositions within the dykes and lavas. Their prevalence shows that off-axis plutonism was more dispersed throughout the ophiolite than was previously appreciated. Such bodies cannot be detected in the field without detailed traverses, nor are they always identifiable on black-and-white air photographs. We recommend the use of enhanced shortwavelength infrared imagery for revision and refinement of lithological maps in Oman and similarly well-exposed semi-arid terrains elsewhere. Acknowledgements
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