Da̧bski and Tittenbrun tests are performed on surfaces overgrown by Rhizo- carpon lichen thalli. However, they obtained no clear decrease of R-values on lichen-free surfaces. Etienne (2002) argues that exfoliation of basaltic surfaces deposited by Sólheimajökull (S Iceland) commences c. 150 years after glacier release. It is possible that exfoliation rejuvenates the surface of basaltic boulders found on Fláajökull moraines de- posited at the beginning of the 20th century and ear- lier (sites II–Ia). Closer examination of micro-cracks developed parallel to the rock surface (Figure 5) re- veal that they could create relatively flat surface after flake detachment from the rock. Therefore, we are inclined to explain relative stabilization of the micro- roughness parameters on old moraines by the process of rock exfoliation. However, this issue calls for fur- ther studies on micro-roughness of basaltic surfaces of various age, preferably on moraines unambiguously dated for 18th century and older. The results of this study do not support results of Chenet et al. (2010) that the historical maximum ex- tent of Fláajökull dates to a period older than the clas- sic LIA (i.e. late 19th century), as the indices of rel- ative age for the oldest moraine do not differ signifi- cantly from the second oldest moraine ridge (compare test sites Ia and Ib). On the other hand, we did not ob- tained unequivocal arguments that the LIA maximum occurred at the end of the 19th century. Furthermore, it is possible that the furthest moraine ridge does not represent LIA glacier maximum, because of erosion which could have erased older moraines (Kirkbridge and Winkler, 2012). CONCLUSIONS This study presents the innovative use of the Handy- surf E-35B electronic profilometer for distinguishing between landforms created due to post-LIA deglacia- tion. Initial, discrete increase in rock surface micro- roughness following first decades after deglaciation is registered. It can be inferred that micro-roughness of basaltic surfaces, previously abraded and polished by a glacier, increases for about 80 years and then sta- bilises at an elevated level, probably due to exfolia- tion. The development of micro-depressions on sur- faces of basaltic boulders, as well as micro-cracks and micro-cavities within weathering rinds, testifies to ad- vancing surface deterioration, which, in the case of the basalts studied here, seems dominated by physi- cal weathering. At this stage, it is difficult to explain the lack of visible chemical alternation of the rock. There are statistically significant correlations between the age-dependent study site range, selected param- eters of micro-roughness (Ra, Rz, Rzmax), weath- ering rind thickness, and Schmidt hammer R-values. We inferred that there is a time-dependent increase in weathering rind thickness which causes decrease in R-values. Given homogenous petrographic conditions and rock with a fine-grained texture (e.g. basalts or lime- stones), which is a very crucial condition due to lim- itation of the instrument (limited range of measur- able amplitude), the Handysurf E35-B electronic pro- filometer can be successfully used in studies on the development rate of initial weathering micro-relief, and thus on the relative age of glacier landforms de- veloped since the LIA maximum. However, this study represents only a first attempt to use this instrument and different methodologies (e.g. evaluation length, sample size) should be exercised. Results of this study do not support the notion of an early 19th century age for the LIA maximum extend of Fláajökull, as calculated by Chenet et al. (2010). On the other hand, the age indices used in this study seem to be robust only within first 80–110 years of weathering, given the type of rock and cli- mate of the study area. Further comparative studies within different glacial marginal zones are required. Acknowledgements We would like to thank Agnieszka Burakowska and Piotr Dzierżanowski for microscopic analysis and comments, as well as Marek Jastrzȩbski for assistance in statistical treatment of the data. We are grateful to Barbara Woronko for discussions on frost weath- ering. Comments from Ívar Örn Benediktsson, an anonymous reviewer and Bryndís Brandsdóttir sig- nificantly improved the paper. Permissions from the Icelandic Institute of Natural History and Vatnajökull National Park are kindly acknowledged. This study has been funded by the National Science Centre in Poland, project N N306 034440. 66 JÖKULL No. 63, 2013

Síða 1
Síða 2
Síða 3
Síða 4
Síða 5
Síða 6
Síða 7
Síða 8
Síða 9
Síða 10
Síða 11
Síða 12
Síða 13
Síða 14
Síða 15
Síða 16
Síða 17
Síða 18
Síða 19
Síða 20
Síða 21
Síða 22
Síða 23
Síða 24
Síða 25
Síða 26
Síða 27
Síða 28
Síða 29
Síða 30
Síða 31
Síða 32
Síða 33
Síða 34
Síða 35
Síða 36
Síða 37
Síða 38
Síða 39
Síða 40
Síða 41
Síða 42
Síða 43
Síða 44
Síða 45
Síða 46
Síða 47
Síða 48
Síða 49
Síða 50
Síða 51
Síða 52
Síða 53
Síða 54
Síða 55
Síða 56
Síða 57
Síða 58
Síða 59
Síða 60
Síða 61
Síða 62
Síða 63
Síða 64
Síða 65
Síða 66
Síða 67
Síða 68
Síða 69
Síða 70
Síða 71
Síða 72
Síða 73
Síða 74
Síða 75
Síða 76
Síða 77
Síða 78
Síða 79
Síða 80
Síða 81
Síða 82
Síða 83
Síða 84
Síða 85
Síða 86
Síða 87
Síða 88
Síða 89
Síða 90
Síða 91
Síða 92
Síða 93
Síða 94
Síða 95
Síða 96
Síða 97
Síða 98
Síða 99
Síða 100
Síða 101
Síða 102
Síða 103
Síða 104
Síða 105
Síða 106
Síða 107
Síða 108
Síða 109
Síða 110
Síða 111
Síða 112
Síða 113
Síða 114
Síða 115
Síða 116
Síða 117
Síða 118
Síða 119
Síða 120
Síða 121
Síða 122
Síða 123
Síða 124
Síða 125
Síða 126
Síða 127
Síða 128
Síða 129
Síða 130
Síða 131
Síða 132
Síða 133
Síða 134
Síða 135
Síða 136
Síða 137
Síða 138
Síða 139
Síða 140
Síða 141
Síða 142
Síða 143
Síða 144
Síða 145
Síða 146
Síða 147
Síða 148
Síða 149
Síða 150
Síða 151
Síða 152