Multi-methodological three-dimensional investigation of open- and closed-system Pingos in northwestern Canada (Pingo3D)

Régions: Inuvialuit Settlement Region, Gwich'in Settlement Area

étiquettes: physical sciences, geological mapping, ground penetrating radar, pingo, Inuvialuit Settlement Region

chercheur principal: Kneisel, Christof (2)
Nᵒ de permis: 17329
Organisation: University of Wuerzburg
Année(s) de permis: 2023
Délivré: août 01, 2023
Équipe de projet: Christof Kneisel, Julius Kunz, Tim Wiegand, Saskia Eppinger

Objectif(s): To investigate the three-dimensional internal structure of pingos in the Mackenzie Delta Region.

Description du projet: This licence has been issued for the scientific research application No. 5654. This research project aims to investigate the three-dimensional internal structure of pingos in the Mackenzie Delta Region. The focus is on small-scale heterogeneities and a detailed delineation of ice-rich or unfrozen areas within, underneath and in close proximity to different pingos. High-resolution, three-dimensional information gathered by geophysical surveying will help to understand the formation and further development of pingos throughout their typical lifecycle. Especially surface-subsurface interactions during the process of permafrost aggradation in drained lake basins as well as during the development of pingos should be investigated in detail using a combined methodological approach of geophysical surveying, satellite- and drone-based remote sensing and various in-situ data. Also the development of taliks during the lifecycle of pingos but also independent from pingo formation should be investigated to gain further knowledge about water pathways within permafrost and their future development, especially in the context of ongoing global warming. Minimally-invasive electrical resistivity tomography (ERT) will be conducted at each field site. Seventy-two small steel rods with a diameter of about 0.8 cm and a length of 40 cm will be pushed into the ground at intervals of 3 meters. These rods will be connected with a cable; the electrical resistivity of the ground at various depths will then be measured. This method allows for the investigation of active layer thickness, subsurface moisture conditions, ground-ice content, and permafrost table topography. Especially for delineation of frozen and unfrozen areas the method is quite common. All probes placed in the ground are non-permanent and will be removed from the ground once measurements are taken. The electrical currents used by the system are low voltage and will have no impact on plants or animals. Non-invasive ground penetrating radar (GPR) data will be recorded at each field site. The GPR system will be pulled over the ground surface along individual transects. The system works by actively sending electromagnetic pulses into the ground at frequencies of 100 and 200 MHz (i.e. microwaves). The pulses reflect and scatter at layers in the ground that have different physical properties. For example, reflections of the GPR signal will be returned at the permafrost table. GPR allows for a highly detailed measurement of active layer thickness within the upper soil layers (i.e. properties of the subsurface) without the need for digging, thus leaving soils and plants undisturbed. Minimally-invasive steel rod probing of the active layer thickness will be conducted at intervals of 3 meters at each sampling location. A steel rod with a diameter of about 1 cm and a length of 120 cm will be pushed into the ground until the permafrost table is reached. This technique allows for the quick measurement of active layer thickness without the need for digging. Each field site will be photographed using a small (under 2 kg), battery-powered, unmanned aerial vehicle (UAV) or a photo-pole. The in-air-time of this UAV will be approximately 20 minutes for each plot and the UAV will be raised to a maximum elevation of 60 meters (200 ft). The UAV will carry standard photographic equipment (i.e. a camera). The images recorded by the UAV will allow for the creation of a digital representation of the terrain surface and will support the vegetation mapping efforts. The low altitude, small airframe size, and minimal flying time will be minimally disruptive to local wildlife. Further, the UAV will not be used in the presence of wildlife, nor will it be used to photograph or harass wildlife. The drone operator has a valid RPAS certificate. In cooperation with the Geological Survey of Canada, drillings will be performed at several pingo sites. The drillings will allow a validation of the multi-dimensional geophysical data sets and, in addition, the installation of thermistor strings to monitor the ground temperatures within and below the pingos. The boreholes will be about 5 cm in diameter and up to 10 m deep. To investigate spatial variabilities in ground thermal regime, small temperature loggers (2 cm x 10 cm) will be installed at several sites. The data loggers will measure the ground surface temperature in an hourly interval over the entire project period. To prevent direct solar radiation, the sensors will be slightly pushed into the ground or below cushions of moss, so that the sensor is located a few centimetre below the surface. After the project, the loggers will be collected and nothing will be left behind in the field. The research team plans to contact and inform every NWT stakeholder and community organization, who are involved in this field work, prior to the campaign. During the stay in the field, the research team will communicate the exact plans and any changes to the contact persons at Aurora Research Institute in Inuvik. Following the fieldwork, an annual report is created in which all conducted research activities and the results are described. The research team will shortly apply for a Land Use Permit at the Inuvialuit Land Administration (ILA) via the LUAS system. The research team received ILA licenses in a previous project using the same approach in 2018, 2019 and 2022. The fieldwork for this study will be conducted from August 12, 2023 to September 15, 2023.