Holocene sediment- and paleo-magnetic characteristics from the Iceland and E-Greenland margins Because of the numerous adjustments that have to be made to derive a single declination record (Stoner et al., 2007)we use only the inclination data. In this case the assumption that is universally made in marine pa- leomagnetic studies is that the core was truly vertical when collected. Usually there is no instrumentation on the corer to test this assertion, but in most instances it is a reasonable assumption (Stoner and St-Onge, 2007). In our study the results from JM96-1216 may indicate that the core penetrated the sediment at an an- gle. During the Holocene the gradual compaction of the sediment (Andrews et al., 2002a) might lead to a decrease in inclination, however, no such trend was noticed. RESULTS 1. Magnetic susceptibility The three measures of magnetic susceptibility are whole-core (WCMS, 10"5 SI), u-channel (10"5 SI), and mass (dry sediment) magnetic susceptibility (massMS 10"7 m3 kg"1). In JM96-1232 (NW Ice- land) the correlation between the whole-core and u- channel median values is only r = 0.02 whereas the WCMS versus the massMS has r = 0.96. An error in the u-channel measurements is considered the cul- prit. Spatially the massMS data show a distinct differ- ence between the two margins (Figure 2A). The Ice- land data has a range in median values between 20 and!55"10"7 m3 kg"1. Values within the Vestfirðir main fjord and trough system (Djúpáll) are higher than data to the north (cores #317, #321, and #330), or south (#347). The median East Greenland values are much higher with a range between 65 and 82"10"7 m3 kg"1. The median wt% of magnetite, determined by XRD, varies linearly (r = 0.82) with median massMS for the 5 Iceland sites with an increase of 22.5"10"7 m3 kg"1 per unit wt% (not shown). However, the three East Greenland sites showed the opposite trend (r= -0.98). Some of the differences in magnetic sus- ceptibility are probably associated with dilution by diamagnetic minerals such as quartz, carbonate and carbon, and the amount of volcanic glass in the sed- iment (Appendix 2). Quartz has much higher wt% values off East Greenland, whereas carbonate and car- bon are significantly higher around Iceland (Andrews et al., 2002a) (Appendix 2). The Saksunarvatn tephra can be detected in most cores by a pronounced re- duction in massMS (Andrews et al., 2002b). Our data (Appendix 2) indicates a strong negative associa- tion (r2 = 0.74, n=8) between wt% volcanic glass and massMS; 95% of the variance in the massMS is ex- plained by the combined effects of carbonate, quartz, and glass. The CV% of massMS data clearly indicates a low level of variability at East Greenland sites (CV% <10), close to the major glacial sediment inputs (An- drews et al., 1994). On the Iceland margin the CV% values are generally >25% except for one site off North Iceland (#317) and one inner fjord site from Vestfirðir (#342). 2. ARM susceptibility There is a strong correlation between the median massMS and kARM with r2=0.83 (Figure 3A) indicat- ing that the dominantmagneticminerals are magnetite of a consistent grain size. For individual cores the cor- relation between these two parameters is often r2 >0.8 but in three cores there is little association. The spa- tial distribution of the medianmass data (Figure 2B) is similar to bothWCMS andmassMS.MedianmassMS and kARM are strongly correlated (Figure 3A). The scatter plot of massMS versus kARM indicates that the two regions plot along a common regression line, but are distinct in terms of their values, with East Green- land sites having higher values. Part of this might be associated with the higher sediment densities off East Greenland versus Iceland (Andrews et al., 2002a). 3. Magnetic ratios The progressive demagnetization of samples in the AF field allows a variety of ratios to be obtained (Maher and Thompson, 1999), which represent dif- ferent responses associated with coercivity, magnetic grain-size, and mineralogy (Heider et al., 2001). For each core, least squares regression equations were calculated for each ARM demagnetization step, e.g. ARM(J10) versus ARM(J0). The slope of the rela- tionship expresses the proportional reduction in ARM intensity after each demagnetization step. The re- JÖKULL No. 59 55

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