Bannister 110

Buried wood in arctic and subarctic North America, preserved in diverse depositional settings, provide glimpses of past landscapes and environmental change. In the Yukon and Alaska, ancient forest remains exposed in mining cuts and river bluffs help us understand how permafrost behaved during persistent warming of the last interglaciation ~125,000 years ago.

In the face of current societal, public health, and environmental challenges, the use of science in public policy is more critical than ever. Understanding the process and practicalities of how environmental systems work is critical for predicting and managing systems in an ever-changing climate. Similarly, understanding the process and practicalities of local, state, and federal policy allows scientists and science-policy professionals to effectively engage in the policy process.

Like other dryland regions around the world, the U.S. Southwest is on a steep trajectory towards a hotter and drier climate. Among the most conspicuous effects of this drying are large-scale vegetation transitions towards sparser systems and lower growth forms. Such structural transformations will have far-reaching consequences for ecosystem functioning and for the climate feedbacks of dryland vegetation. These feedbacks remain undervalued and understudied in a climate mitigation context, because drylands sequester less carbon per area compared to more mesic systems.

In this talk, I will introduce the idea that ecosystems located near glaciers can serve as natural laboratories for global change biology and paleoclimate studies. This is because they have experienced climate changes that were amplified by nearby ice-margin fluctuations. I will report on results from one of these natural experiments in the old-growth temperate rainforest near La Perouse Glacier in Southeast Alaska. We used dendrochronology to observe how tree growth responded to a shift from “normal” to accentuated rates of summer temperature change that occurred in the mid 1800s.