02141nas a2200181 4500000000100000008004100001100001900042700001600061700001200077700001500089700001400104700001900118245014700137856006500284300002400349490000700373520157900380 2016 d1 aJames Channell1 aR. Harrison1 aI Lascu1 aI.N McCave1 aF Hibbert1 aWilliam Austin00aMagnetic record of deglaciation using FORC-PCA, sortable-silt grain size, andmagnetic excursion at 26 ka, fromthe Rockall Trough (NE Atlantic) uhttp://onlinelibrary.wiley.com/doi/10.1002/2016GC006300/full a1823\textendash18410 v173 a

Core MD04-2822 from the Rockall Trough has apparent sedimentation rates of \~ 1 m/kyr during the last deglaciation (Termination I). Component magnetization directions indicate a magnetic excursion at 16.3 m depth in the core, corresponding to an age of 26.5 ka, implying an excursion duration of \~350 years. Across Termination I, the mean grain size of sortable silt implies reduced bottom-current velocity in the Younger Dryas and Heinrich Stadial (HS)-1A, and increased velocities during the B\olling-Aller\od warm period. Standard bulk magnetic parameters imply fining of magnetic grain size from the mid-Younger Dryas (\~12 ka) until \~ 8 ka. First-order reversal curves (FORCs) were analyzed using ridge extraction to differentiate single domain (SD) from background (detrital) components. Principal component analysis (FORC-PCA) was then used to discriminate three end members corresponding to SD, pseudo-single domain (PSD), and multidomain (MD) magnetite. The fining of bulk magnetic grain size from 12 to 8 ka is due to reduction in concentration of detrital (PSD + MD) magnetite, superimposed on a relatively uniform concentration of SD magnetite produced by magnetotactic bacteria. The decrease in PSD+MD magnetite concentration from 12 to 8 ka is synchronized with increase in benthic $δ$13C, and with major (\~70 m) regional sea-level rise, and may therefore be related to detrital sources on the shelf that had reduced influence as sea level rose, and to bottom-water reorganization as Northern Source Water (NSW) replaced Southern Source Water (SSW).