Conflicting Values or Common Ground? : Some Concluding Thoughts

Peer reviewe

The Scale and Impact of Viking Settlement in Northumbria

Recent archaeological research, notably at the Viking winter camp at Torksey, has indicated that the armies that invaded Anglo-Saxon England in the late 9th century were much larger than has often been assumed and that a literal reading of the Anglo-Saxon Chronicle’s assessment of the size of Viking fleets may, after all, have been correct. Furthermore, study of the Torksey metalwork assemblage has allowed the identification of the archaeological signature of the Viking Great Army and, when applied to Cottam, it confirmed the identification of an initial phase of raiding by an element of the Army, followed shortly thereafter by settlement represented by the development of a hybrid Anglo-Scandinavian culture. Taken together, over 25 categories of non-ferrous artefacts are diagnostic of Viking or Anglo-Scandinavian activity in Northumbria. Applying this model to over 15 sites, largely known only from metal-detecting, we can observe a common pattern. At the majority of sites, a large and fairly standardised Middle Anglo-Saxon finds assemblage is succeeded by just a few Viking finds, which we attribute to raiding following Halfdan’s return to Northumbria with part of the Great Army in AD 876. At a much smaller number of sites there are also assemblages of Anglo-Scandinavian finds, relating to the establishment of new settlements by the new landowners. The overall picture is of major settlement disruption and dislocation of existing land holdings and populations in the late 9th century. This demonstrates, for the first time from archaeological evidence, the scale and impact of Viking activity in Northumbria

High activity enables life on a high-sugar diet: blood glucose regulation in nectar-feeding bats

High blood glucose levels caused by excessive sugar consumption are detrimental to mammalian health and life expectancy. Despite consuming vast quantities of sugar-rich floral nectar, nectar-feeding bats are long-lived, provoking the question of how they regulate blood glucose. We investigated blood glucose levels in nectar-feeding bats (Glossophaga soricina) in experiments in which we varied the amount of dietary sugar or flight time. Blood glucose levels increased with the quantity of glucose ingested and exceeded 25 mmol l(−1) blood in resting bats, which is among the highest values ever recorded in mammals fed sugar quantities similar to their natural diet. During normal feeding, blood glucose values decreased with increasing flight time, but only fell to expected values when bats spent 75 per cent of their time airborne. Either nectar-feeding bats have evolved mechanisms to avoid negative health effects of hyperglycaemia, or high activity is key to balancing blood glucose levels during foraging. We suggest that the coevolutionary specialization of bats towards a nectar diet was supported by the high activity and elevated metabolic rates of these bats. High activity may have conferred benefits to the bats in terms of behavioural interactions and foraging success, and is simultaneously likely to have increased their efficiency as plant pollinators