Jónsdóttir et al. Around 1450 CE there are changes in the record. The estimated bottom water temperature drops down to ca. 2◦C, with a change in the foraminiferal fauna. Cibicides lobatulus decreases and C. reniforme be- comes the dominant species in the fjord. This is also the time when other proxy records in the fjord start to become more unstable. The MS record shows fluc- tuating values and the X-rays higher abundance of coarse grained material in the core. There is a peak in the coarse grained material at ca. 1450–1500 CE which lines up with a drop in the bottom water tem- perature estimations. At approximately 1500 CE the bottom water temperature increases again, with a de- crease in the Arctic species E. excavatum. There is no coarse grained material detected in the core but the MS shows fluctuating values. The interval between ca. 1650–1750 CE (Figure 6) shows defined changes towards harsher conditions in Arnarfjörður with a drop in the bottom water tem- perature (temperature changes of 1◦C), TC and the carbonate values and at the same time the Arctic wa- ter species indicators E. excavatum, Q. stalkeri and C. reniforme increase. Elphidium excavatum adapts easily to a wide range of environmental conditions, but often blooms during extremely cold and unstable conditions (Hald et al., 1994). In this interval the bot- tom water current indicator C. lobatulus has its low- est values and the diversity of the foraminifera fauna also reaches a low. Colder conditions in the fjord are also evident by an increase in both density and MS values as well as increased amount of coarse grained material. The coarser grained material found in Arn- arfjörður after 1200 CE is not believed to have a dis- tal source. Quantitative XRD analysis of the sedi- ments in Arnarfjörður found no or little quartz (Fig- ure 6). Icelandic bedrock consists of basalts with quartz only found in low abundances, whereas sed- iment from western Greenland contains quartz (An- drews and Jennings, 2014). The most likely explana- tion of those coarse grained material peaks are thus eroded material from the coast of Arnarfjörður. Comparison to other areas Comparing the results from Arnarfjörður to other proxy records from the same region reveals consid- erable similarities in climate variability. The oldest part of Arnarfjörður core indicates the lowest bottom water temperature during the Dark Ages cooling period at ca. 450 CE and ca. 750 CE (Figure 7). That is in good agreement with records from the Malagen fjord in Norway which show tem- perature minimum around 400 CE and 600–800 CE (Hald et al., 2011). The warmest interval in the Arn- arfjörður record is during the MWP. Proxy-based tem- perature reconstruction from Haukadalsvatn, north- west Iceland, for the past 2000 years, characterized medieval times between ca. 900 and 1200 CE as a rel- atively warm period with higher productivity than be- fore or after (Geirsdóttir et al., 2009). The DACP- MWP boundary is not as evident in the lake record like in Arnarfjörður (Figure 7), but the onset of colder conditions is similar, around 1200 CE and two of the most severe temperature drops in Arnarfjörður during the LIA coincide with similar drops in the lake record. The second interval of LIA cooling in the lake record, between 1450 and 1500 CE, lines up with a drop in the estimated BWT in Arnarfjörður. More unstable con- ditions in Arnarfjörður after 1450 CE with estimated bottom water temperature dropping down to ca. 2◦C coincides with a major environmental shift detected in records from sediment cores on each side of the Den- mark Strait based on weight% of calcite and quartz (Andrews and Jennings, 2014). In North Iceland a number of high-resolution stud- ies have been carried out on core MD99-2275 (Eiríks- son et al., 2006; Knudsen et al., 2012; Massé et al., 2008; Sicre et al., 2008), located on the shelf northeast of Iceland. One of these studies used IP25 biomarker produced by sea ice loving algae to reconstruct sea ice over the last millennium (Massé et al., 2008). The sea ice proxy shows no or little sea ice until ca. 1300 CE (MWP-LIA) when there is a small rise which lines up with a BWT decrease in Arnarfjörður (Figure 7). There is a second increase in IP25 and decrease in Arnarfjörður BWT around 1500 CE. The biggest IP25 peak is around 1600–1800 CE, which coincides with the coldest time in Arnarfjörður for the time pe- riod ca. 350–1850 years CE. The sea surface temper- atures (SSTs) for core MD99-2275 was warmer be- tween 1000 and 1350 CE, suggested to represent en- hanced heat transport across the Denmark Strait (Sicre 82 JÖKULL No. 65, 2015

Page 1
Page 2
Page 3
Page 4
Page 5
Page 6
Page 7
Page 8
Page 9
Page 10
Page 11
Page 12
Page 13
Page 14
Page 15
Page 16
Page 17
Page 18
Page 19
Page 20
Page 21
Page 22
Page 23
Page 24
Page 25
Page 26
Page 27
Page 28
Page 29
Page 30
Page 31
Page 32
Page 33
Page 34
Page 35
Page 36
Page 37
Page 38
Page 39
Page 40
Page 41
Page 42
Page 43
Page 44
Page 45
Page 46
Page 47
Page 48
Page 49
Page 50
Page 51
Page 52
Page 53
Page 54
Page 55
Page 56
Page 57
Page 58
Page 59
Page 60
Page 61
Page 62
Page 63
Page 64
Page 65
Page 66
Page 67
Page 68
Page 69
Page 70
Page 71
Page 72
Page 73
Page 74
Page 75
Page 76
Page 77
Page 78
Page 79
Page 80
Page 81
Page 82
Page 83
Page 84
Page 85
Page 86
Page 87
Page 88
Page 89
Page 90
Page 91
Page 92
Page 93
Page 94
Page 95
Page 96
Page 97
Page 98
Page 99
Page 100
Page 101
Page 102
Page 103
Page 104
Page 105
Page 106
Page 107
Page 108
Page 109
Page 110
Page 111
Page 112
Page 113
Page 114
Page 115
Page 116
Page 117
Page 118
Page 119
Page 120