Introduction
The climate of the Cairngorm Mountains resembles Reference Tricart,Tricart’s (1967) “mountainous variety” of the “humid periglacial climates with a marked winter”, i.e. the mean annual temperature is about 2-5°C,Footnote * annual precipitation is about 1 600-2 400 mm, there is no permafrost and most freeze-thaw oscillations, which do not penetrate deep into the soil, are equinoctial. The area could also be ascribed to Tricart’s Kerguelen tundra morphogenetic province, since there is considerable frost shattering, high humidity, strong winds affecting and limited by the vegetation and frequent pipkrake. Although many periglacial features are found (Reference King,King, unpublished), the amount of patterned ground, other than lobes, is disappointing, which seems to be due to three factors: vegetation, ground slope and parent material. In order to observe polygons and stripes, the ground must be completely or selectively denuded, a situation which is only extensively found above 900 m. Furthermore, polygons are not found on slopes greater than 5°. Stripes are found on slopes up to 18° but above 10° the lobate form is more common (Reference KingKing, in press). Polygons and stripes are therefore largely restricted to the plateau over 900 m. The higher parts of the plateau consist of fields of well-rounded granitic boulders. The lower parts consist of coarse feldspathic sand. Polygons are found at the boundary between these two parent materials and also where boulders occur amongst the feldspathic sand, especially if the latter is waterlogged. At the former environment, polygons consist of pockets of sand amongst the felsenmeere, here called coarse polygons (Fig. 1), and at the latter they consist of boulder rings surrounding feldspathic sand, here called fine polygons (Fig. 2). The basic difference between these two types is the ratio of boulders to sand. The centres of most coarse polygons are vegetated but, in one shallow valley bottom (on the plateau), polygons with the same form and about the same size as coarse polygons contain bare centres and very few stones or boulders.
There are also two different types of stripe. Coarse stripes display alternate bare and vegetated stripes (Fig. 3). The bare stripes possess very little soil and contain coarser stones and boulders than the vegetated ones. Fine stripes are lines (in the direction of strongest declivity) of mostly angular stones in a feldspathic sandy matrix (Fig. 4).
The boulders in the centres of coarse polygons and those forming the vegetated coarse stripes appear to be smaller than their bare borders (Fig. 5) and a χ2 test, using a probability criterion of 0.005, showed this to be so.
Sizes
25 widths or diameters were measured from each of four sample sites of each patterned ground type. Polygon measurements were restricted to level ground in order to avoid down-slope polygon elongation, and in all measurements the shortest diameter was recorded. The distributions were found to fit logarithmic normal curves (Figs. 6 and 7). Means and standard deviations are shown in Table I. There are not enough bare coarse polygons or fine stripes to do an analysis.
A χ2 test was applied to the polygon-size distributions to ascertain whether there is justification in dividing them into two types: coarse and fine. Using a probability criterion of 0.005, the distributions were found to be statistically different and are therefore probably produced by different processes and not merely due to age, when the types would probably be more transitional.
Movement Investigation
Attempts were made to observe the movement of both fine and coarse polygons. Some of the former were photographed and mapped on 9 October 1965. The polygons were then disturbed to three different depths (surficially, 15 cm and 30 cm) in three adjacent areas. The whole area was then photographed and mapped, and photographed and mapped again, in the following spring and autumn. In the spring of 1966 (29 June), there was no sign of polygon re-formation but there was evidence of some movement, the amount of which is shown in Table II. The amount of movement between 29 June and 7 October 1966 is shown in Table III. It seems that the process of polygon formation (in the Cairngorm Mountains) is too slow to be able to see in what directions movement takes place. Nevertheless, it can be seen that not only boulders but soil also moves and that, in general, there is more movement over the period covered by Table II than that of Table III, which is also the period over which there are more fluctuations across the freezing point.
Coarse polygons were disturbed in two different ways. In one area, the boulders and soil were thoroughly mixed up, and in the other the soil and vegetation were removed but the boulders were left. A third area was recorded and left unchanged. The disturbance look place on o, October 1965. There were no changes when the areas were investigated again on 20 June and 7 October 1966, except for some aeolian removal of vegetation.
Pipkrake
A large number of hypotheses have been put forward to explain patterned ground, most of which have been summarized by Reference Washburn,Washburn (1956), who pointed out that different hypotheses probably apply to different environments. He also suggested that, in any particular environment, the explanation is probably polygenetic.
There are three main groups of hypotheses: those embodying heave (e.g. Reference Hamburg,Hamburg, 1910), convection (e.g. Reference Bénard,Bénard, 1900; Reference Gripp,Gripp, 1926) and contraction (e.g. Reference FigurinFigurin, 1823; Reference Baer,Baer, 1837; Reference Cholnoky,Cholnoky, 1911). The surficial nature of the patterned ground in the Cairngorm Mountains. however, rules out convection. Nearly all of the hypotheses depend on freeze-thaw oscillations and some observations were therefore made during such a period.
Practically the whole surface of the ground (where denuded) was covered with pipkrake. In a small area (60 cm by 60 cm), the largest diameters of a hundred stones were measured and it was recorded whether they had been raised by pipkrake, which on the day of observation grew to a maximum of 4 cm, upturned or left in situ. The smallest diameter measured was 1.25 cm and the largest was 16.5 cm. It was found that 46 stones were uplifted, 38 left in situ and 16 upturned. The mean diameter of those raised was 2.79 cm; the mean of those left in situ was 6.27 cm and the mean of those upturned was 6.58 cm. Their respective standard deviations were 1.04, 2.79 and 3.58 cm. A χ2 test showed that there is a greater than 99.5% statistically significant difference between the distribution of raised stones and those left in situ.
Measurements were also taken of the movement of stones with an axial ratio greater than or equal to 2 : 1 to sec whether they have any propensity for upturning rather than uplifting in toto. The sizes of the stones ranged from 1.25 to 10 cm and the average size of the pipkrake was 2.5 cm. 17 stones were not moved at all, 41 were upturned and 42 were uplifted in toto. which suggests that elongated stones have an equal propensity for upturning as uplifting in toto. Nevertheless, if these figures are compared with the ones in the previous paragraph, it can be seen that a greater proportion of elongated stones is upturned than those of other shapes.
It was also noticed that pipkrake not only raised stones and fines vertically (lending support to the heave hypotheses) but also moved them away from the larger unmoved stones (supporting the contraction hypotheses). Some of the stones fell into the gaps formed between the unmoved stones and the soil, and after the pipkrake had melted stones were often seen surrounding larger stones or boulders.
Suggested Origin of Fine Polygons
Hollows can be seen around boulders of the size of those forming fine polygon borders, and smaller boulders or stones are seen lying in these hollows usually orientated parallel to the larger boulder’s periphery. In the borders of fine polygons, small boulders are also often found surrounding and orientated parallel to the periphery of the larger ones. Where the smaller boulders or stones lie touching the larger ones, they usually rest against the latter; but away from the boulder, the smaller boulders or stones tend to dip towards the larger ones as if they have been uplifted, while the larger ones remain stationary.
This observation was tested as follows: the angle of inclination of boulders in polygon borders was measured from the same four polygons as were used for the measurement of boulder diameters. Measurements were taken to the nearest degree of boulders with a minimal axial ratio of 3 : 2. The distribution is shown in Figure 8. The mean angle of dip was found to be 36° with a standard deviation of 21°.
Although pipkrake have been proposed as a cause of patterned ground (Reference Salomon,Salomon, 1929. p. 9), the largest recorded stones raised by pipkrake were only the size of hens’ eggs (Reference Philberth,Philberth, 1964, p. 166). However, larger stones can be raised by ice lenses (Reference Philberth,Philberth, 1964, p. 122; Reference Everett, Wilimovsky, and Wolfe,Everett, 1966, p. 217). Although ice lenses were not seen by the author in the Cairngorm Mountains, they have been observed by Reference Caine,Caine (1963, p. 174) in the Lake District, and there is therefore presumably no reason why they could not occur in the Cairngorm Mountains.
The evidence seems to suggest that large boulders remain stationary while the soil and smaller boulders and stones are heaved. This hypothesis was tested as follows: in an area of fine polygon development, the sizes of 60 boulders displaying lichen (i.e. presumably immobile) were compared with the sizes of 60 boulders without lichen. The mean diameter of the lichen-covered boulders is 71.4 cm with a standard deviation of 34.8 cm, and the mean diameter of the bare boulders is 57.2 cm with a standard deviation of 26.2 cm. A χ2 test showed that there is a greater than 99.5% statistically significant difference between the two distributions.
The minimal size of stationary boulders is probably proportional to the amount of heave. Not only are polygon centres upheaved but they also contract away from large boulders, if the evidence of pipkrake observations can be applied to other types of heave. The contraction is probably due to soil desiccation, since the water content is largely extracted to form ice. Some stones will fall, as an immediate result of upheaval of the centre, into the gaps round the large boulders. Other boulders will slide radially down the domed surface of heave probably at the immediate onset of thawing when the surface will be most lubricated and before the centre has subsided.
In an area of uniform soil and boulder content, polygon sizes will be proportional to the spacing of stationary boulders; the greater the heave, the larger the size of stationary boulders and, in general, the larger the polygon size. This reasoning conforms with that of Reference Troll,Troll (1944), who pointed out that the size of patterned ground is roughly proportional to latitude. He stated that the large high-latitude forms have a larger period and greater amount of heave than the low-latitude forms.
Suggested Origin of Coarse Polygons
If the centres of coarse polygons were heaved, a radial orientation of the boulders found in the centre would be expected. Orientation measurements were therefore taken from the centres of four coarse polygons but no radial orientation was revealed.
The dips of the boulders in the polygon borders were also measured (Fig. 8). The mean angle of dip is 30° with a standard deviation of 22°. A x 2 test indicated a 90% statistically significant difference between the dips of boulders in the borders of fine and coarse polygons, suggesting that the borders of coarse polygons dip at a significantly lower angle than those of fine ones.
Coarse polygon sizes also have a higher relative dispersion (77.7%) compared with fine polygons (54.5%). A closer examination reveals that coarse polygons formed from porphyritic granite are not as well developed, contain smaller boulders and have greater diameters than those formed from the more widespread coarse-grained granite. The mean diameters of polygons formed from porphyritic and coarse-grained granite are 145.3 and 79.0 cm, respectively, with respective standard deviations of 87.7 and 34.3 cm, and a χ 2 test showed that there is a 99.5% statistically significant difference between the two distributions.
The lack of orientation and relatively low angle of boulder inclination suggest a different origin to that postulated for fine polygons and, in fact, suggest lack of movement. The hemispherical cross-section, high relative size dispersion (Reference Elton,Elton, 1927, p. 82) and lithological dependence could all be explained by selective weathering which has already been suggested elsewhere as a possible cause of patterned ground (Reference Meinardus,Meinardus, 1912, p. 254-55). Sorting can be explained by the probability that small boulders and stones will decrease in size as a result of frost shattering faster than large ones, because of their greater surface area to volume ratio. Boulders of fine-grained porphyritic granite are also more subject to frost shattering than those of coarse-grained granite (Reference Waters, and Simons,Waters, 1964, p. 79) and consequently are smaller and the polygons formed by them contain more fines and are therefore larger.
Mention has also been made of coarse polygons with bare centres. Figure 8 shows that their boulder-dip distribution can be fitted to a second-degree logarithmic curve, which suggests a force influencing smaller boulders parallel to the ground surface. Their topographic position (i.e. valley bottom) suggests that they may be part of a solifluction deposit, and the presence of polygons on this deposit indicates that coarse polygons can form with no pronounced boulder inclination, explicable under a weathering hypothesis. However, the steeper inclination than other solifluction features (i.e. stripes) suggests that there is probably some heaving, as may also be true, in the past, for vegetated polygons.
Suggested Origin of Stripes
The inclinations of stones in four fine stripes were measured to the nearest degree. 25 stones were measured from each stripe. The mean inclination was found to be 11° and the distribution could be fitted to a second-degree logarithmic curve (Fig. 8) whose equation is log y = 1.77 — 0.881x+0.0574x 2, which has a high constant term and a low coefficient of x, both indicating a high proportion of stones with a low inclination. Many of the stones are, in fact, roughly parallel to the slope of the ground, suggesting laminar down-slope movement or solifluction. The orientation of stones in a horizontal plane was also measured and is represented by Figure 9, in which the only pattern that seems to exist (if any) is a decrease from 0° to 25°, a rise between 25° and 8o° and a low 80-90° value. This could possibly be explained by relative down-slope movement of soil and stone stripes. Any stone projecting out of the stone stripe by more than 25° in an up-slope direction will be affected by the down-slope movement of the soil stripe and possibly become wedged in a new orientation. Stones projecting at about 90° or any orientation in a down-slope direction will be reduced to low angles of deviation.
It would appear, therefore, that fine stripes are governed by solifluction, as suggested by Reference Nordenskjöld,Nordenskjöld (1909, p. 63), and that soil stripes move faster than stone ones because solifluction decreases with depth, and the stones which extend below the ground surface move more slowly than the soil. This might also explain why so few fine stripes were found, since they can only be found where all the stones are small, i.e. less than about 15 cm, because any larger boulders would extend below the present layer of active solifluction and thus the soil will be dammed up-slope behind them producing small terraces, which are indeed often found.
Stone orientations of bare coarse stripes were also measured from four localities. The dip distribution is shown in Figure 8 from which it can be seen that its curve is flatter than that for fine stripes, probably because of interactions between boulders of different sizes; nevertheless, the second-degree logarithmic rather than logarithmic normal shape suggests predominant down-slope rather than cross-slope influence. Movement of soil and boulders down-slope would obey the laws of viscosity so that movement is slowest at, and down-slope from, the larger stationary boulders and fastest as well as deepest midway between them. The effect of this is that coarse material is deposited both up-slope and down-slope from the stationary boulders and the stripe form is developed. Evidence to support this sorting by viscous flowage has been provided by the experiments of Reference Dzulynski, and Walton,Dzulynski and Walton (1963).
The correlation coefficient between altitude and width of vegetated coarse stripes is —0.976, which is 97.5% statistically significant. Altitude is most likely inversely proportional to age or movement periodicity. Thus there appears to be a correlation between movement periodicity and size. Low-altitude movement is likely to take place at climatic extremes when solifluction extends to considerable depth and large boulders will be moved, boulders which under a less arduous climate would extend below the active layer and remain immobile. It seems, therefore, as with fine polygons that large immobile or relatively slower-moving boulders form the coarser, now bare stripes, while the finer material flows past, to form the finer, now vegetated stripes.
Age
The technique of lichenometry was used to assess the age of coarse polygons and stripes. Using a similar method of measuring lichen to that used by Reference Sugden,Sugden (unpublished, p. 219) and assuming a growth rate of 46 mm per century, which Reference Bornfeldt, and Osterborg,Bornfeldt and Osterborg (unpublished) found in southern Norway, a climate approximating that of the Cairngorm Mountains, it was inferred that coarse polygons and stripes were active in the eighteenth or nineteenth centuries (Table IV). The results cannot be considered conclusive because of the likelihood of overcrowding and the probability that the lichen may be nth generation since the boulders were originally denuded or stabilized. Since some coarse polygons (the bare ones) appear to be active today, the vegetated ones were probably active in a climatic period not very much more extreme than today. Furthermore, if they were much older, they would probably be completely covered by vegetation as are the vegetation-covered lobes which are thought to date from zone IV (Reference KingKing, in press). Completely vegetated polygons may exist but, without excavation and boulder-diameter measurement, they are unrecognizable.
Acknowledgements
I should especially like to thank Dr J. B. Sissons of the Department of Geography, University of Edinburgh, for providing me with invaluable advice throughout my research. I am grateful to the Natural Environment Research Council for awarding me a grant towards my research. My thanks are also extended to the Aviemore Police for concerning themselves. about my welfare when I was camping.