World Water Day from Canmore, AB

Valuing Mountain Water: What Water Means to You

Watch online now!

https://youtu.be/4BbaXJtJZQA (english)
https://youtu.be/nRJFcwtgBa4 (french)

With special guests:

Mayor John Borrowman, Mayor of Canmore

Terry Duguid, Parliamentary Secretary for the Canada Water Agency

Anil Mishra, Chief of Hydrological Systems and Water Scarcity, United Nations Education, Science and Cultural Organisation, Paris

Berit Arheimer, Professor, Swedish Meteorological and Hydrological Institute & President, International Association of Hydrological Sciences

John Pomeroy, Director of Global Water Futures, Centre for Hydrology, Canmore

Caroline Aubry-Wake, Graduate Student, Centre for Hydrology, Canmore

Alain Pietroniro, Professor, University of Calgary & GWF Core Modelling Co-lead

Louise Arnal, Postdoctoral Fellow, Centre for Hydrology, Canmore

Bob Sandford, Global Water Futures Chair of Water & Climate Security, United Nations Institute for Water and Environmental Health

and

Martyn Clark, Professor, Centre for Hydrology, Canmore & GWF Core Modelling Co-lead

 

Western Canada AquaHacking tech startup information session

Calling all Global Water Futures and University of Saskatchewan students, post-docs or recent grads passionate about water issues!

On March 25, we’re co-hosting an information session about the Western Canada AquaHacking Challenge: a tech startup competition presented by the Okanagan Basin Water Board and Aqua Forum for solving freshwater issues.

As an AquaHacking competitor, you’ll receive training on how to transform an idea into reality so you and your team can make a real impact on water issues impacting communities and watersheds across Western Canada. Finalist teams are awarded with seed funding (up to $20K!) to launch their water tech startup.

Join GWF Director, Dr. John Pomeroy, and members of the AquaHacking Alumni network to hear how you can get involved in the Western Canada 2021 AquaHacking Challenge.

Click on the link to sign up for the information session: https://us02web.zoom.us/meeting/register/tZUqduqvqT8uHdN4SxuK1zAlWsAKaqhGWZ96

New Journal Publication – Atmospheric boundary layer dynamics over glaciers

Icefield Breezes: Mesoscale Diurnal Circulation in the Atmospheric Boundary Layer Over an Outlet of the Columbia Icefield, Canadian Rockies

Conway, J.P., Helgason, W.D., Pomeroy, J.W., Sicart, J.E.

Journal of Geophysical Research – Atmospheres, Volume 126, Issue 6
February 13, 2021
DOI: https://doi.org/10.1029/2020JD034225

Abstract
Atmospheric boundary layer (ABL) dynamics over glaciers mediate the response of glacier mass balance to large‐scale climate forcing. Despite this, very few ABL observations are available over mountain glaciers in complex terrain. An intensive field campaign was conducted in June 2015 at the Athabasca Glacier outlet of Columbia Icefield in the Canadian Rockies. Observations of wind and temperature profiles with novel kite and radio‐acoustic sounding systems showed a well‐defined mesoscale circulation developed between the glacier and snow‐free valley in fair weather. The typical vertical ABL structure above the glacier differed from that expected for “glacier winds”; strong daytime down‐glacier winds extended through the lowest 200 m with no up‐valley return flow aloft. This structure suggests external forcing at mesoscale scales or greater and is provisionally termed an “icefield breeze.” A wind speed maximum near the surface, characteristic of a “glacier wind,” was only observed during night‐time and one afternoon. Lapse rates of air temperature down the glacier centerline show the interaction of down‐glacier cooling driven by sensible heat loss into the ice, entrainment and periodic disruption and warming. Down‐glacier cooling was weaker in “icefield breeze” conditions, while in “glacier wind” conditions, stronger down‐glacier cooling enabled large increases in near‐surface temperature on the lower glacier during periods of surface boundary layer (SBL) disruption. These results raise several questions, including the impact of Columbia Icefield on the ABL and melt of Athabasca Glacier. Future work should use these observations as a testbed for modeling spatio‐temporal variations in the ABL and SBL within complex glaciated terrain.

Read the full article here.

News article – predicting mountain snowpack

USask model for predicting mountain snowpack provides clearer picture of spring runoff, impacts of climate change

USask News
march 9, 2021

After decades of research, a new model was developed by University of Saskatchewan (USask) researchers that for the first time successfully predicted mountain snowpack with a high degree of accuracy and detail—information of critical importance for water management, agriculture, mining, recreation, and flood forecasting worldwide. Snow cover in the mountains is the principal driver of spring runoff.

Read the article here: https://news.usask.ca/articles/research/2021/usask-model-for-predicting-mountain-snowpack-provides-clearer-picture-of-spring-runoff,-impacts-of-climate-change.php