Pinbain Block - an excursion

Key details

Itinerary

Locality 1. South end of Kennedy's Pass [NX 146 928]

Lavas and breccias (Figure 25.7), (Figure 25.8). Park cars south of Kennedy's Pass, walk 50 m to the north to dark-looking rocks on the foreshore; for coaches there is a larger car park on the seaward side of the road north of Kennedy's Pass. Beneath the unconformity which divides the Ordovician clastic sequence to the north from the Ballantrae complex to the south (see Excursion 30), are a series of tough, brittle, dark grey, orange and red lavas and breccias which form the local top to the Pinbain block. The Pinbain block comprises mainly albite-bearing altered basalts (spilites) most of which are pillowed.

The wave-washed surfaces at this outcrop are very polished and on them the dark lavas show indistict flow banding and occasional viscous, flow-banded folding. Some of the flow-banded lavas contain quartz, which in part is secondary; but some have >60% silicon dioxide, which is considerably higher than for an average basalt. The rocks are probably a mixture of dacitic and basaltic lavas which have been considerably altered by their contact with sea water. Acidic and intermediate lavas often brecciate when extruded into water, and this is a likely reason for the intense brecciation seen here.

Locality 2. [NX 143 923]: Interfingering lavas and sediments

This locality can be identified by the presence of an unofficial car park which is sited on the west side of the road, opposite the milestone 'Girvan 5; Ballantrae 8' (Figure 25.9). The outcrops are only barely seen at low tide. There are two types of lava exposed, the lower one is porphyritic, the upper is dark and aphyric. The dark lava is mainly massive, very fine grained and is partly replaced upwards (to the north) by conglomerates and breccias with a fine tuff matrix. Two thin units of pillow lava occur within these clastic rocks. Also, within the breccia unit there are layers of conglomerate, some having well rounded clasts which may be red in colour.

This locality shows the interaction between the sea and the lavas which flow into it. When lavas reach water they often brecciate, and the thick unit of breccia-conglomerate was probably produced in this way. The rounded clasts were produced during intervals when lava flowage had ceased and waves had time enough to work on the clast population before its burial. Some of these clasts are red because the lavas from which they have been derived have almost certainly been subject to sub-aerial weathering. During periods of strong lava flowage fragmentation of the lava flow takes place at the water's edge, and this may produce clasts so quickly that the waves have insufficient time to work on them and produce more rounded clasts. But if the extrusion is particulary rapid, then the lava extends beyond the water's edge and produces pillowed or massive lava flows (see (Figure 25.13) for explanation). This locality shows all of these features with respect to the dark, massive lavas.

The red tops to the lavas are almost certainly the result of subaerial weathering, having been eroded during a period of coastal retreat. Associated with these lavas are tuffs containing accretionary lapilli (Smellie 1984).

Locality 3. Slockenray headland [NX 149 919]: Hyalotuff deltas (Figure 25.10)

Park cars on the headland just above Slockenray Bay, at a bend in the road. Slockenray Bay is one of the most significant outcrops in the Pinbain Block. It was previously regarded as an Arenig vent, but is now thought to be a hyalotuff delta as it is clearly interstratified with the other lavas in the block and can be traced for some distance inland (Bluck 1981; (Figure 25.8)).

A detailed map of this headland is given (Figure 25.10), where the position of the car park is marked. From the car park the following may be observed; a steeply dipping distinctly porphyritic lava forms the headland: beneath this lava, and in the low ground of the bay to the south is the hyalotuff deposit which underlies the lava. The contact beween the two is within the low ground beneath the southern end of the headland. The lavas are replaced to the SSW by conglomerates, and they probably wedge out in this direction. The whole sequence is upward coarsening and is terminated by the porphyritic lava.

To the north of the headland (Figure 25.11) hyalotuff deposits overlie the porphyritic lavas, and interfinger with a dark aphyric lava-type.

Locality 4. Lavas (best seen at low tide). (Figure 25.10)

There are two lava types in this sequence, each of which comprises multiple flows. The main one is porphyritic with abundant phenocrysts >1 cm long of plagioclase (now mainly albite) arranged in a swirling fashion and suggesting alignment during turbulent viscous flow of the lava. The other is dark, aphyric and sometimes abundantly vesicular. This lava has also behaved in a plastic way; it has contorted margins against the porphyritic lava, which are lined with abundant vesicles left by the trapped gases; sometimes long deformed finger-like projections, and even detached irregular masses are totally enclosed in the porphyritc lava. It is clear that both lavas were extruded at the same Time at the boundary between them and (whilst they were flowing), each has injected into the other.

With Slockenray being near the contact between the two different types of lava, there must have existed on either side of this locality magma chambers each yielding a different lava. However, since both magma chambers were repeatedly producing lavas at the same time, they may have been responding to the same event-which is likely to have been structural.

Locality 5. Cross stratified hyalotuffs (Figure 25.10)

These deposits comprise rounded and angular clasts of dark basalt with a texture identical to the porphyritic lavas which immediately overlie them. Some of the clasts are whole pillows, some are very angular vesiculated fragments and both contain abundant phenocrysts. The clasts range in size from >80 cm to sand sized grains and have a matrix which is a brown coloured mass of chloritised volcanic glass with isolated long phenocrysts of labradorite and by townite. Some of these crystals have been broken and then welded by the glass implying explosive activity which fragmented the grains and the rapid invasion of the broken mass by the hot lava. From the extreme angularity of many of the clasts and the pristine nature of the crystals, it is clear that this tuff has suffered the minimum of reworking since it was produced by explosive activity.

As with the tuff crystals, the clasts also contain unaltered plagiocase of labradorite-bytownite type, despite being sourced from the overlying lava which contains phenocrysts of identical shape but composed of albite.

This deposit is clearly the product of the explosive breakdown of the overlying porphyritic lava. When the lava reached the sea it disintegrated into breccia and pillows, but at the same time its surface chilled to yield abundant glassy basaltic fragments. These were then transported into deeper water where they formed a platform over which the lavas could prograde see (Figure 25.11), (Figure 25.13). The sediment was probably laid down sometimes in a series of mass flows and sometimes as normal tractive currents. The former mechanism is evident in the abundant, poorly sorted deposits some of which have boulders strewn through the tuff; the latter is seen in the poorly developed large-scaled cross strata. By comparison with present day examples of hyalotuff deltaic deposits, sediment pro gradations were probably very rapid when lavas entered the sea. Pauses in sedimentation took place between periods of lava activity and are marked by the beds of clast supported (well sorted) conglomerates on the foreshore.

The breccia beds (Figure 25.10) resemble the deposits already described, but differ in that they contain only clasts of dark aphyric lavas. These have had a provenance in the dark lavas which interfinger with the porphyritic ones at Locality 3, where evidence also suggests that both lavas were extruded at the same time. A possible explanation of this interstratification is given in (Figure 25.11).

Locality 6. Graded hyalotuffs (Figure 25.10)

Graded and ungradedbeds of tuffs, some containing large clasts of vesicular lava, can be traced north into the coarse grained deposits already described. These are considered to be the deeper water, distal equivalents of the breccias and conglomerates. They sometimes have breccia bands amongst them, suggesting periods when coarse sediments by-passed the delta into deeper water, maybe as coarse-grained grain-flows. Some of the large clasts are thought to have been fragments of pumice which floated out into deeper water where they became water-logged and dropped into the regions where finer sediment was accumulating. The graded beds are probably turbidites generated in the delta region by slumping during periods of lava extrusion and rapid development of tuff.

These finer tuffs are in contact with underlying prophyritic lavas which form the floor to this sequence and make up the higher part of Pinbain Hill to the NE where they are thicker and comprise more massive flows with little interbedded tuff.

Locality 7. Red conglomerates (only at low tide; (Figure 25.10))

A thin, well stratified and sometimes cross stratified conglomerate containing clasts of basalt and spilite occurs at the very top of this sedimentary sequence. The clasts are often well rounded and are either dark grey or red in colour. The red basalt clasts have almost certainly been derived from the tops of lava flows (as seen at Locality 2), having been oxidised in subareal conditions. The matrix of this conglomerate is volcanic sand with a calcite cement: the glassy tuffs which characterize most of the other rudaceous rocks are conspicuously absent.

Seemingly, the conglomerate formed during a period when lava extrusion had ceased in this particular locality and the sea was transgressing over an inactive and subsiding stack of lavas, which were being eroded at the sea margin. Clasts derived from these lavas were rounded and assembled in fairly high energy conditions, probably at the shoreline. Within this and other volcanic blocks, similar thin conglomerates with well rounded clasts can often be seen to truncate the underlying lava sequence: they probably formed on marine erosion platforms cut into lavas which were slightly tilted before or during the marine transgression. At this locality, the porphyritic lava flow appears to be eroded by such a surface beneath the conglomerate and at locality 2 the conglomerate rests on the dark lava.

Locality 8. Sediments on top of the lavas (Figure 25.12)

Unless the tide is very low it is easier to return to the car park and then descend the cliff again to examine the upper part of this sequence exposed to the north of the headland. Although the lower part of the porphyritic lava sequence is massive, it is capped by a unit where large pillows of lava are enclosed in tuff. The top of the lava can be traced along the headland (Figure 25.10) and in the bays to the north (Figure 25.12). They are red in colour.

The presence of massive lava, pillowed lava and tuff can be explained by the rates of lava extrusion (see (Figure 25.13)). If the rate of flow is slow, then the lava will not advance seaward beyond the intertidal zone as its outer skin will be continously converted into glass which then cools and fragments into tuff and breccia. With increasing rates of extrusion, the lava will advance beyond the intertidal zone and when the outer skin of glass forms, zones of weakness in this carapace will inflate by the pressure of the lava, much like balloons, to form pillows. If the rate of extrusion is slow enough, then the whole of the lava may be converted to pillows or pillow-like feeder tubes (Figure 29.13) B. However, if the rate of lava extrusion is quite high then only the outer margin of the complete flow becomes pillowed: the interior remains massive (Figure 25.13) C.

It is thought therefore that the massive flows at Pinbain are the product of very rapid extrusion of lava, and this outcrop at the top of the lava sequence is a record of the chilling on the outer parts of the lava flow. Above these pillows is a thick sequence of hyalotuffs and conglomerates and breccias, with mixed clasts of porhyritic and aphyric lavas. This abundance of hyalotuff, as with that below the lavas, is the produced at times of low rates of lava extrusion. The fact that many of the clasts are complete pillows, suggests that the lavas occasionally advanced beyond the strand line into the subtidal zone to generate pillows which then detached and rolled out in front of the migrating lava flow.

Locality 9. Lava tubes (Figure 25.12)

Thin finger-like units of aphyric lava occur within the hyalotuff. The origin of these is not readily apparent, but they are possibly the solidified tubes of lava which have advanced rapidly ahead of the migrating lava front and out over the platform or plinth of hyalotuff. They have mamilliferous outer chilled surfaces which may represent the incipient development of pillow buds on the skin of the lava. These features are thought to be similar to the lava tubes described from hyaloclas tic deltas seen forming at the present-day.

Locality 10. Contact with the overlying porphyritic lavas (Figure 25.12)

Porphyritic lavas with red and white phenocrysts are seen to rest on the hyaloclastic deposits. These lavas are massive with some zones of pillows. They represent rapid lava extrusions, probably once again at the strand-line.

Origin of the Slockenray sequence

The Slockenray sequence is considered to be the product of migration of a hyaloclastic or hyalotuff delta (Figure 25.11). There are two lava types present on the headland at Slockenray: a dark aphyric lava and a distinctive porphyritic lava. They were both extruded at the same time. This simultaneous extrusion is confirmed by the presence of dark as well as porphyritic lava clasts in the breccias and conglomerates of the hyaloclastic deltas, suggesting that the two types of lavas were hot and being broken up at the shoreline to produce their distinctive debris. In this way two cones of tuff from distinctive lava types overlapped each other and produced the interstratified sequence as seen at Slockenray.

The sequence at Slockenray is therefore significant in that it demonstrates that part, at least, of the Pinbain lava pile formed in intertidal conditions. However the whole of the Pinbain sequence is made up of lavas and breccia-conglomerates. These have been seen at Localities 1–9 and continue down the sequence to the Pinbain Fault, where they can be seen on the north outcrops of (Figure 25.15). Well over 50% of the Pinbain sequence comprises volcanogenic sediment, and throughout the sequence there are clasts which are well rounded. This implies that the complete thickness of about 1.5 km was deposited in fairly shallow water, and therefore that accumulation kept pace with subsidence.

Not only at Slockenray, but also elsewhere in the Pinbain sequence, there is evidence for advances and retreat of the lava. Conglomerate with the well rounded clasts (as seen at Localities 2 and 7 for example) probably represents an initial transgression on a subsiding block of lava (Figure 25.14). With increasing water depth the conglomerate is replaced by tuff and then by cherts, but when the lavas begin to advance again the cherts are replaced by tuffs and then by breccias and then by lavas (Figure 25.14). The cherts and tuffs associated with the deepening of the trough can be seen at the base of the sequence near the Pinbain Fault.

Locality 11. [NX 137 916]: Pinbain Fault and associated features ((Figure 25.15) a, b, c, d, e, )

The section begins at the north end of the beach to the north of Pinbain Burn (Figure 25.15). Lavas and associated sediments of the Pinbain Block strike NE-SW but are truncated at the base by the Pinbain Fault which, at the coast near Pinbain Burn is an almost E–W, 30–60 m wide fault zone. This zone contains sheared serpentinite, spilite, gabbro and a variety of other rocks. To the south of this shear belt lie the olistostromes and mass flow deposits of Pinbain.

(a). The sequence to the immediate north of the Pinbain Fault (a on (Figure 25.15)) contains tuffs, Ethic arenites, cherts and black shales which are overlain by breccias and agglomerates with accretionary lapilli. The cherts sometimes contain thin light-coloured laminae of feldspar grains; these are crystal tuffs and are probably of air-fall origin. The cherts are interstratified with thin black mudstones and shales from which, on the roadside above this exposure, Rushton et al (1986) have recovered fragments of trilobites, brachiopods and graptolites suggesting a Lower Arenig age. They are interstratifed with graded and ungraded beds, about 10–20 cm thick, which are probably the result of turbidity currents and grain-flows.

In terms of the fluctuating coastline shown in (Figure 25.14), these beds are thought to represent the deeper water or more tranquil part of the basin. The overlying breccias are recording the seaward advance of the lavas.

(b). Exposures of a sheared gabbro-breccia faulted against a sheared serpentinite breccia which occupies most of the sandy foreshore. This breccia zone marks the position of the Pinbain Fault.

(c, d, e). The olistostromes (isolated clasts in a fine grained matrix) and breccia-conglomerates of Pinbain are exposed in the raised-beach cliff sections to the east side of the road, and are seen to interfinger with black mudstones along the middle and upper foreshore, but are almost totally replaced by black mudstones on the lower foreshore (c, d, e of (Figure 25.15)) and in the sub-tidal outcrops. This whole outcrop is therefore at the interfingering boundary between breccia-conglomerate/olistostromes and the black mudstones.

The boundaries between the fingers of breccia-conglomerate and the mudstones (d) of (Figure 25.15)) are nearly always sheared: the former may have dark zones adjacent to the black mudstones, where mud from the mudstone unit has invaded their fabric. In some instances flames of dark mudstone have penetrated into the brecciaconglomerate, thus adding further evidence for the view that the mudstone was not dewatered when the breccia-conglomerate was deposited.

A prominent outcrop at low tide at (c), (Figure 25.15), comprises folded black shales made up of an early sequence of small, pyrite-bearing folds which are refolded by a later large-scale fold. The folding took place when the shale was ductile and it seems probable that both these phases of folding took place when the sediment was still plastic. In the outcrops surrounding (c), the black shales are often well exposed showing the sometimes quite intensive ductile shearing. The nature of the shearing is particularly well seen at (e) (Figure 25.15), where siliceous beds are interstratified with cherty shale beds and light grey, silicic tuffs.

The following important points can be drawn from an examination of this outcrop:

1. The shales are made up of black and light grey tuffs which are sheared into each other, producing a feather-like contact between the two lithologies.

2. The black shales are often tightly folded into cm scale folds, and the light grey tuffs are sometimes sheared up the cleavages, resembling flame structures.

3. Black cherry shales have either resisted deformation or have been brecciated, with mud infilling the breccia matrix.

4. Pyrite growth in the shales pre-dates the deformation in some instances, but appears to have overgrown the deformation in others.

It is concluded that the deformation in the shale sequence took place when it was unconsolidated. Clasts in the breccia-conglomerate are sometimes quite large; some of the blocks of pillow lava exceed 20 m in diameter (Locality 12; a of (Figure 25.16)), forming boulders. There are clasts up to boulder size of the following types: pre-existing conglomerate, carbonates, turbidites comprising dark volcanic rich lithic arenites, various sized clasts of granite (including trondhjemite), sheared rocks rich in epidote, serpentinite, amphibolites. Some of the fine conglomerates contain clasts of blue-schist.

Locality 12. [NX 1372 9145]: Olistostromes and their contact with the serpentinite (Figure 25.16)

The olistostromes are exposed on the rock platform at (b) (Figure 25.16), where boulders are surrounded by sheared shales. Some of the shale beds are siliceous, fairly well stratified and contain microscopic radiolaria: they are normally tougher than the unsilicified shales and have consequently resisted the otherwise pervasive shearing.

The following points are thought to be significant in an interpretation of the outcrops of sedimentary rocks described at Localities 11 & 12:

1. Large clasts were displaced into quiet waters where the shales accumulated; this in turn implies that steep slopes developed on the side of the basin in which muds formed, in order to displace repeatedly the blocks into it.

2. Considerable shearing took place during and immediately after the deposition of the sediments, shears which can now be seen in the shale-chert sequences. The shales probably acted as detachment horizons for major shears created on the basin margins: or at least during episodes of tectonic activity within the basin.

3. The abundant tuff bands suggest that the shale basin was relatively proximal to an area of volcanic activity, but not so close that pyroclastic flows entered the basin. The considerable exposures of pillow lava may have been intruded into the wet muds of the basin but could also have been detached from cliff-like faces in older lava flows and then slid into the basin of deposition. Those clasts of pillow lava which are rounded to varying degrees, probably acquired this rounding at a shoreline and were then displaced into deeper water.

4. The source of the conglomerates comprised a wide variety of ophiolitic rocks which were formed in quite disparate environments; fragments of blue-schist from high pressure, low temperature conditions: sepentinites from the mantle: amphibolites from fairly high temperature metamorphic regimes: and trondhjemites, gabbros and dolerites from quite high in the oceanic lithosphere. Some rocks were already deformed by the time they entered the conglomerate. All this implies that a great deal of the ophiolite, including rocks which have a provenance deep within the lithosphere and the mantle such as blue-schists, amphibolite and serpentinite, were exposed at the time, and had all been mixed before arriving at the basin of sedimentation.

Since black shale sedimentation accompanied tuff accumulation, it is reasonable to assume that the basin opened during extension accompanied by volcanicity and that the conglomerates are associated with normal rather than compressional faults. The faults probably detached within the black shale and chert horizons, causing the intense ductile-style deformation there. The acidic-intermediate tuffs together with the pillow lavas, indicate accumulation in a submarine to subareal volcanic regime and the presence of ophiolitic debris and the absence of terrigenous detritus suggest a volcanic complex founded on pre-existing oceanic crust.

The whole exposure at Pinbain is terminated in the south by a prominent dyke (Figure 25.16), possibly of Tertiary age, south of which there is a sandy beach with a few exposures of breccias and serpentinite, seen only at low-tide. The breccias which outcrop for a few metres to the immediate south of the dyke (Figure 25.16) are associated with sheared black shales and sheared blocks of ophiolitic rock and at this point probably constitute a mélange. To the south of the breccia there is a wide outcrop of normal serpentinite, which makes up most of the low ground extending to Lendalfoot.

There is clearly major displacement between the serpentinite and the breccia-olistostrome sequence, as each formed at totally different crustal levels. The sediments formed on the surface; the serpentinite has been brought up from depths exceeding 10 km. The timing of the juxtaposing of these two lithological units is uncertain: the serpentinite may have been uplifted before the deposition of the sedimentary units so providing a source for the conglomerates.

These sediments are not typical of layer1, ocean basin sediments in the ocean crust sequence. They are clearly deposited in basins where there was a copious supply of coarse clas tic sediment. For this reason they are not thought to be associated with an ocean ridge, although it is possible that they are part of a fracture-zone sequence; also they are not likely to have formed as part of a hot-spot, as the composition of the conglomerates indicates a source which included metamorphic rocks and serpentinite which are not found in hot-spot oceanic islands; but in all details they resemble the sediments produced during arc-rifting and marginal basin formation (see Introduction).

Locality 13. Bonney's Dyke [NX 1347 9113]: Gabbro pegmatite (Figure 25.17)

Bonney's Dyke was named by Balsillie (1932) after the famous petrologist T.G.Bonney. The feature is not a dyke but a steeply dipping, sill-like sheet intruded into serpentinite, comprising a coarse gabbro pegmatite of altered diallage and feldspar, most of the latter being replaced by white prehnite and pectolite. The following points should be noted: the sheet thins towards the west: it is sinistrally shifted by a number of faults and as such provides an excellent strain marker within the serpentinite: it has a hydrogrossular northern margin and contains rafts of serpentinite. The serpentinite to the immediate south of the sheet contains large crystals of diallage: to the immediate north is a norite with enstatite crystals enclosed in plagioclase; the norite is only visible at low tide.

Locality 14. Albite diabase sheets and rodingite

The serpentinite to the south of Bonney's Dyke is intruded by many diabase sheets which can be examined at most tides along the shoreline to Lendalfoot (see Balsillie 1932). These sheets are mostly altered but detailed work on their chemistry and mineralogy has now demonstrated that there are at least two types of sheets present (Holub et al 1984); group 1 have mainly amphibole and plagioclase and a provenance in a depleted mantle source; group 2 have clinopyroxene and plagioclase present, and a source in a less depleted mantle. Group 1 sheets were intruded during elevated temperature, possibly when the serpentinite-peridotite was at greenschist facies; group 2 were intruded into colder rocks. Both have been, in places, altered to a white massive hydrogarnet rock (rodingite) and both therefore were intruded during the period of serpentinization.

Many of these intrusions are pod-like. It is often possible to trace chilled margins over entire exposed surfaces. The sheets have large xenoliths of serpentinite within them and may have a very irregular, flame-like contact with the serpentinite which encloses them.

References

BAILEY, E.B., and McCALLIEN, W.J. 1957. The Ballantrae serpentinite, Ayrshire. Trans. Edinb. Geol. Soc. 17, 33–53.

BALSIL LIE, D. 1932. The Ballantrae Igneous complex, south Ayrshire. Geol. Mag. 69, 107–131.

BERGSTROM, S. M. 1990. Biostratigraphic and biogeographic significance of Middle and Upper Ordovician conodonts in the Girvan succession, south-west Scotland. Courier Forsch.-Inst. Senckenberg., 118, 1–43, 4 pls.

BLOXAM T.W and ALLEN, J.B. 1960. Glaucophane schist, eclogite and associated rocks from Knockormal in the Girvan-Ballantrae Complex, south Ayrshire. Trans. R. Soc. Edinb. 64, 1–27.

BLUCK, B.J. 1982. Hyalotuff deltaic deposits in the Ballantrae ophiolite of S.W. Scotland: evidence for the crustal position of the lava sequence. Trans R. Soc. Edinb. Earth Sci. 72, 217–228.

BLUCK, B.J. 1983. Role of the Midland Valley of Scotland in the Caledonian Orogeny. Trans. R. Soc. Edinburgh: Earth Sciences, 74, 119–136.

BLUCK, B.J. 1985. The Scottish paratectonic Caledonides. Scott .J. Geol. 21, 437–464.

BLUCK, B.J. and HALLIDAY, A.N. 1981. Comment and reply on age and origin of the Ballantrae ophiolite and its significance to the Caledonian Orogeny and the Ordovician time-scale. Geology, 10, 331–333.

BLUCK, B.J. HALLIDAY, A.N., AFTALION, M., and MACINTYRE, R.M. 1980. Ageand origin of the Ballantrae Complex and its significance to the Caledonian orogeny and the Ordovician time scale . Geology 8, 492–495.

CHATTERTON, B. D. E and LUDVIGSEN, R. 1976. Silicified Middle Ordovician trilobites from the South Nahanni River area, District of Mackenzie, Canada. Palaeontogr., Abt. A, 167, 77–119, pls 9–24.

CHURCH, W.R. and GAYER, R.A. 1973. The Ballantrae ophiolite. Geol. Mag. 110, 497–510.

COCKS, L. R. M. and TOGHILL, P. 1973. The biostratigraphy of the Silurian rocks of the Girvan district, Scotland. Geol. Soc. London, 129, 209–243.

DEMPSTER, T.J. and BLUCK, B.J. 1991. The age and tectonic significance of the Bute amphibolite, Highland Border Complex, Scotland. Geol. Mag. 128, 77–80.

DEWEY, J.F. 1969. Evolution of the Appalachian/Caledonian orogen. Nature 222, 124–129.

COCKS, L. R. M. 1974. The geology of the southern terminations of the Caledonides, in Nairn, A, (ed) The ocean basins and their margins. Vol. 2 The North Atlantic. 205–231. New York

DONOVAN, S. K. and CLARK, N. D. L.1992. Unusual crinoid columnals from the Llandovery of England and Wales. Palaeontology 35 (in press).

DUNNING, G.R. and KROGH, T.E. 1985. Geochronology of ophiolites of the Newfoundland Appalachians. Canadian bourn. Earth. Sci. 22, 1659–1670.

HARPER, D. A. T. 1981. The stratigraphy and faunas of the Upper Ordovician High Mains Formation of the Girvan district. Scott. J. Geol., 17, 247–255.

DONOVAN, S. K. 1982. The stratigraphy of the Drummuck Group (Ashgill), Girvan. Geol. J., 17, 251–277.

DONOVAN, S. K. 1984. Brachiopods from the upper Ardmillan succession (Ordovician) of the Girvan district, Scotland. Part I. Palaeontogr. Soc. [Monogr.J, London. 178, pls 1–11.

DONOVAN, S. K. 1989. Brachiopods from the upper Ardmillan succession (Ordovician) of the Girvan district, Scotland. Part 2. Palaeontogr. Soc. [Monogr.], London. 79128, pls 12–22.

HENDERSON, S. M. K. 1935. Ordovician submarine disturbances in the Girvan district. Trans. R. Soc. Edinburgh, 58, 487–509, 4 pls.

HOWELLS, Y. 1982. Scottish Silurian trilobites. Palaeontogr. Soc. [Monogr.J, London. 1–76, 15 pls.

HOLUB, F.V., KLAPOVA, H. BLUCK, B.J. and BOWES, D.R. 1984. Petrology and geochemistry of post-obduction dykes of the Ballantrae complex, SW Scotland. Trans R.Soc. Edinb. Earth Sci. 75, 211–223.

HUGHES, C. P., INGHAM, J. K. and ADDISON, R. 1975. The morphology, classification and evolution of the Trinucleidae (Trilobita). Phil. Trans. R. Soc. London, B, 272, 537–604.

INCE, D.M. 1984. Sedimentation and tectonism in the middle Ordovician of the Girvan district, SW Scotland. Trans R.Soc.Edinb. Earth Sci. 75, 225–237. INGHAM J. K. 1968. British and Swedish Ordovician species of Cybeloides (Trilobita). Scott. J. Geol., 4, 300–316, 2 pls.

INCE, D.M. 1974. The Upper Ordovician trilobites from the Cautley and Dent districts of Westmorland and Yorkshire . Part 2. Palaeontogr. Soc. monogr.1 , 5987, pls 10–18.

INCE, D.M. 1978. Geology of a continental margin 2: middle and late Ordovician transgression, Girvan. In Bowes D. R. and Leake, B. E. (eds) Crustal evolution in northwestern Britain and adjacent regions. Geol. J. Special Issue 10, 163–176.

INCE, D.M. CURRY, G. B. and Williams, A. 1986. Early Ordovician Dounans Limestone fauna, Highland Border Complex, Scotland. Trans. R. Soc. Edinburgh: Earth Sciences, 76 (4) (for 1985, publ. Feb.1986). 481–513.

INCE, D.M. and TRIPP, R. P. 1991. The trilobite fauna of the Middle Ordovician Doularg Formation of the Girvan district, Scotland, and its palaeoenvironmental significance. Trans. R. Soc. Edinburgh: Earth Sciences, 82, 27–54.

KELLEY, S. and BLUCK, B.J. 1989. Detrital mineral ages from the Southern Uplands using 40 A–39 A laser probe. J. Geol. Soc. Lond. 146, 401–404.

KIELAN–JAWOROWSKA, Z., BERGSTROM, J. and AHLBERG, P. 1991. Cheirurina (Trilobita) from the Upper Ordovician of Vastergotland and other regions of Sweden. Geol. Toren. ; Stockholm Forhandl., 113, 219–244.

LANE, P. D. 1971. British Cheiruridae (Trilobita). Palaeontogr. Soc. [Monogr.], London. 1–95, 16 pls.

LEWIS, A.D and BLOXAM, T.W. 1977. Petrotectonic environments of the Girvan-Ballantrae lavas from rare-earth element distributions. Scott. J. Geol. 13, 211–222.

LONGMAN, C.D., BLUCK, B.J. and VAN BREEMEN, O. 1979. Ordovician conglomerates and the evolution of the Midland Valley. Nature, 280, 578–581.

LUDVIGSEN, R. 1978. Middle Ordovician trilobite biofacies, southern Mackenzie Mountains. In Stelck, C. R and Chatterton, B. D. E. [eds] Western and Arctic Canadian biostratigraphy. Geol Assoc. Can., Spec. Pap. 18.

OWEN, A. W. 1986. The uppermost (Hirnantian) trilobites of Girvan, SW Scotland with a review of coeval trilobite faunas. Trans. R. Soc. Edinburgh: Earth Sciences, 77, 231–239.

OWENS, R. M. 1973. British Ordovician and Silurian Proetidae (Trilobita). Palaeontogr. Soc. [Monogr.), London . 1–98, 15 pls.

PEACH, B.N. and HORNE, J. 1899. The Silurian rocks of Britain, 1: Scotland Metn Geol.Surv. U.K.

REED, F. R. C. 1903–6. The Lower Palaeozoic trilobites of the Girvan district, Ayrshire. Palaeontogr. Soc. [Monogr. ], London. Pt 1 (1903), 1–48, pls 1–6, Pt 2 (1904), 49–96, pls 7–13, Pt 3 (1906), 97–186, pls 14–20.

REED, F. R. C. 1914. The Lower Palaeozoic trilobites of Girvan. Supplement. Palaeontogr. Soc. IMonogr.J, London. 1–56, 8 pls.

REED, F. R. C. 1917. The Ordovician and Silurian brachiopods of the Girvan district. Trans. R. Soc. Edinburgh, 51, 795–998, 24 pls.

REED, F. R. C. 1931. The Lower Palaeozoic trilobites of Girvan. Supplement No 2. Palaeontogr. Soc. [Monogr], London. 1–30.

REED, F. R. C. 1935. The Lower Palaeozoic trilobites of Girvan. Supplement No 3. Palaeontogr. Soc. IMonogr.J, London. 1–64, 4 pls.

RUSHTON, A. W. A. and TRIPP, R. P. 1979. A fossiliferous lower Canadian (Tremadoc) boulder from the Benan Conglomerate of the Girvan district. Scott. J. Geol., 15, 321–327.

RUSHTON, A. W. A. , STONE, P., SMELLIE, J.L. and TUNNICLIFF, S.P. 1986. An early Arenig age for the Pinbain sequence of the Ballantrae Complex. Scott. J. Geol. 22, 41–54.

SMELLIE, J.L. 1984. Accretionary lapilli and highly vesiculated pumice in the Ballantrae ophiolite complex: ashfall products from subaerial eruptions. Rep.Br. Geol. Surv. 16, 36–40.

SPRAY, J.G. and WILLIAMS, G.D. 1980. The sub-ophiolite metamorphic rocks of the Ballantrae igneous complex, SW Scotland. J.Geol. Sociond. 137, 359–368. STONE, P.1984. Constraints on genetic models for the Ballantrae complex, SW Scotland. Trans. R.Soc.Edinb. Earth Sci. 75, 189–191.

SPRAY, J.G. , and RUSHTON, A.W.A. 1983. Graptolite faunas from the Ballantrae ophiolite complex and their structural implications. Scott. J. Geol. 19 297–310.

SPRAY, J.G. , and SMELLIE, J.L. 1988. Classical areas of British geology: The Ballantrae area: a description of the solid geology of parts of 1:25 000 sheets NX 08, 18 and 19. (London: HMSO for British Geological Survey.) B.G.S.

THIRLWALL, M.F. and BLUCK, B.J. 1984. Sr-Nd isotope and geological evidence that the Ballantrae "ophiolite", SW Scotland is polygenetic. in Gass, I.G., Lippard, S.J., and Shelton, A.W. (eds) Ophiolites and oceanic lithosphere. Spec. Pub. Geol. Soc. Lond. No 13, 215–230.

TOGHILL, P. 1970. Highest Ordovician (Hartfell Shales) graptolite faunas from the Moffat area, south Scotland. Bull. Brit. Mus. nat. Hist. (Geol.), 19, 1–26, 16 pls.

TRELOAR, P.J., BLUCK, B.J., BOWES, D.R. and DUDEK, A. 1980. Hornblende-garnet metapyroxenite beneath serpentinite in the Ballantrae complex of S.W.Scotland, and its bearing on the depth of provenance of obducted ocean lithosphere. Trans. R. Soc. Edinb. Earth Sci. 71, 201–212.

TRENCH, A., BLUCK, B. J. and WATTS D. R. 1988. Palaeomagnetic studies within the Ballantrae Ophiolite; southwest Scotland: magnetotectonic and regional tectonic implications. Earth and Planetary Science Letters, 90, 431–448. TRIPP, R. P. 1954. Caradocian trilobites from mudstones at Craighead Quarry, near Girvan, Ayrshire. Trans. R. Soc. Edinburgh, 62, 655–693, 4 pls.

TRENCH, A. 1962. Trilobites from the confinis Flags (Ordovician) of the Girvan district, Ayrshire. Trans. R. Soc. Edinburgh, 65, 1–40, 4 pls.

TRENCH, A. 1965. Trilobites of the Albany division (Ordovician) of the Girvan district, Ayrshire. Palaeontology, 8, 577–603, plc 80–83.

TRENCH, A. 1967. Trilobites of the upper Stinchar Limestone (Ordovician) of the Girvan district, Ayrshire. Trans. R. Soc. Edinburgh, 67, 43–93, 6 pls.

TRENCH, A. 1976. Trilobites from the basal superstes Mudstones (Ordovician) at Aldons Quarry, near Girvan, Ayrshire. Trans. R. Soc. Edinburgh, 69, 369–423, 7 pls.

TRENCH, A. 1979. Trilobites from the Ordovician Auchensoul and Stinchar Limestones of the Girvan district, Strathclyde. Palaeontology, 22, 37–40, plc 37–40.

TRENCH, A. 1980a. Trilobites from the Ordovician Balclatchie and lower Ardwell groups of the Girvan district, Scotland. Trans. R. Soc. Edinburgh: Earth Sciences, 71, 147–157, 1 pl.

TRENCH, A. 1980b. Trilobites from the Ordovician Ardw ell Group of the Craighead Inlier, Girvan district, Scotland. Trans. R. Soc. Edinburgh: Earth Sciences, 71, 123–145, 4 pls.

WILLIAMS, A. 1959. A structural history of the Girvan district, SW Ayrshire. Trans. R. Soc. Edinburgh, 63, 629–667.

WILLIAMS, A. 1962. The Barr and lower Ardmillan Series (Caradoc) of the Girvan District, south-west Ayshire, with description of the Brachiopoda. Men). Geol. Soc. London, 3, 1–267, 25 pls.

WILLIAMS, S. H. 1987. Upper Ordovician graptolites from the D. complanatus Zone of the Moffat and Girvan districts and their significance for correlation. Scott. J. Geol. 23, 65–92.

WILKINSON, J.M. and CANN, J.R. 1974. Trace elements and tectonic relationships of basaltic rocks in the Ballantrae igneous complex, Ayrshire. Geol Mag. 111, 35–41.