scholarly journals Hot-water drilling for exploration of the Antarctic subglacial environments

2021 ◽  
Vol 83 (1) ◽  
pp. 13-25
Author(s):  
Shin SUGIYAMA ◽  
Masahiro MINOWA ◽  
Masato ITO ◽  
Shiori YAMANE
Keyword(s):  
Hot Water ◽  
The Antarctic ◽  
Subglacial Environments

The effectiveness of Virkon® S disinfectant against an invasive insect and implications for Antarctic biosecurity practices

2020 ◽  
pp. 1-9 ◽  
Author(s):  
Jesamine C. Bartlett ◽  
Richard James Radcliffe ◽  
Pete Convey ◽  
Kevin A. Hughes ◽  
Scott A.L. Hayward
Keyword(s):  
Salt Water ◽  
Hot Water ◽  
Antarctic Region ◽  
Invasive Insect ◽  
Signy Island ◽  
Antarctic Treaty ◽  
Biosecurity Practices ◽  
Water Treatments ◽  
The Antarctic ◽  
Maximum Threshold

Abstract The flightless midge Eretmoptera murphyi is thought to be continuing its invasion of Signy Island via the treads of personnel boots. Current boot-wash biosecurity protocols in the Antarctic region rely on microbial biocides, primarily Virkon® S. As pesticides have limited approval for use in the Antarctic Treaty area, we investigated the efficacy of Virkon® S in controlling the spread of E. murphyi using boot-wash simulations and maximum threshold exposures. We found that E. murphyi tolerates over 8 h of submergence in 1% Virkon® S. Higher concentrations increased effectiveness, but larvae still exhibited > 50% survival after 5 h in 10% Virkon® S. Salt and hot water treatments (without Virkon® S) were explored as possible alternatives. Salt water proved ineffective, with mortality only in first-instar larvae across multi-day exposures. Larvae experienced 100% mortality when exposed for 10 s to 50°C water, but they showed complete survival at 45°C. Given that current boot-wash protocols alone are an ineffective control of this invasive insect, we advocate hot water (> 50°C) to remove soil, followed by Virkon® S as a microbial biocide on ‘clean’ boots. Implications for the spread of invasive invertebrates as a result of increased human activity in the Antarctic region are discussed.

scholarly journals Hot-Water Drilling in the Antarctic Peninsula (Abstract)

1988 ◽  
Vol 11 ◽  
pp. 215
Author(s):  
S. Cooper
Keyword(s):  
Antarctic Peninsula ◽  
Temperature Sensors ◽  
Back Pressure ◽  
Hot Water ◽  
Ice Shelves ◽  
Pilot Hole ◽  
Fast Ice ◽  
Drilling System ◽  
The Antarctic ◽  
Practical Field

The British Antarctic Survey has developed a hot-water drilling system used chiefly for installing temperature sensors through ice shelves and for retrieving oceanographic equipment tethered through thick fast ice. The specification, design and operation of the drill for these two activities will be discussed and practical field problems will be highlighted. A novel aspect of the design is the use of reaming nozzles to enlarge a pilot hole. These nozzles eject water upwards along the surface of the nozzle cone, and drill most efficiently when they hang free and unsupported by the sides of the pilot hole. The nozzles incorporate a nozzle-mounted valve, activated when the nozzle cone contacts the ice, thus increasing the back pressure of the water flow. The pressure increase is monitored at the surface and the winch speed is reduced accordingly in order to ensure an efficient drilling operation.

scholarly journals Modeling hole size, lifetime and fuel consumption in hot-water ice drilling

2014 ◽  
Vol 55 (68) ◽  
pp. 115-123 ◽  
Author(s):  
L. Greenler ◽  
T. Benson ◽  
J. Cherwinka ◽  
A. Elcheikh ◽  
F. Feyzi ◽  
...  
Keyword(s):  
Water Flow Rate ◽  
Hot Water ◽  
Hole Size ◽  
South Pole ◽  
Neutrino Detector ◽  
Water Ice ◽  
Fuel Savings ◽  
Highly Sensitive ◽  
The Antarctic ◽  
Drill System

AbstractIceCube, a cubic-kilometer neutrino detector, was built at the South Pole using a hot-water drill system. Deep holes were drilled into the Antarctic ice sheet and filled with highly sensitive optical instrumentation. For the hot-water drilling, a computer model was developed to predict the hole sizes and hole lifetimes during construction. The goal was to predict ultimate size and freezeback rates based on water flow rate and temperature, drill speed, ice temperature and ream parameters (for a secondary operation where hot water continues to flow as the drill is withdrawn). This model proved to be very successful. It increased confidence that the holes would remain open long enough after drilling to allow the deployment of the necessary instrumentation. It also allowed for a decrease, over the course of the project, in the amount of overdrilling that was used as a margin against a too-rapid freeze-in. This resulted in significant fuel savings.

scholarly journals Clean subglacial access: prospects for future deep hot-water drilling

2016 ◽  
Vol 374 (2059) ◽  
pp. 20140304 ◽  
Author(s):  
Keith Makinson ◽  
David Pearce ◽  
Dominic A. Hodgson ◽  
Michael J. Bentley ◽  
Andrew M. Smith ◽  
...  
Keyword(s):  
Ice Sheet ◽  
Field Testing ◽  
Lessons Learned ◽  
Hot Water ◽  
Water Recovery ◽  
Subglacial Lake ◽  
Comprehensive Plan ◽  
Recovery System ◽  
Hydrological System ◽  
The Antarctic

Accessing and sampling subglacial environments deep beneath the Antarctic Ice Sheet presents several challenges to existing drilling technologies. With over half of the ice sheet believed to be resting on a wet bed, drilling down to this environment must conform to international agreements on environmental stewardship and protection, making clean hot-water drilling the most viable option. Such a drill, and its water recovery system, must be capable of accessing significantly greater ice depths than previous hot-water drills, and remain fully operational after connecting with the basal hydrological system. The Subglacial Lake Ellsworth (SLE) project developed a comprehensive plan for deep (greater than 3000 m) subglacial lake research, involving the design and development of a clean deep-ice hot-water drill. However, during fieldwork in December 2012 drilling was halted after a succession of equipment issues culminated in a failure to link with a subsurface cavity and abandonment of the access holes. The lessons learned from this experience are presented here. Combining knowledge gained from these lessons with experience from other hot-water drilling programmes, and recent field testing, we describe the most viable technical options and operational procedures for future clean entry into SLE and other deep subglacial access targets.

scholarly journals Microbiology: lessons from a first attempt at Lake Ellsworth

2016 ◽  
Vol 374 (2059) ◽  
pp. 20140291 ◽  
Author(s):  
D. A. Pearce ◽  
I. Magiopoulos ◽  
M. Mowlem ◽  
M. Tranter ◽  
G. Holt ◽  
...  
Keyword(s):  
Local Environment ◽  
Hot Water ◽  
Critical Question ◽  
Ongoing Research ◽  
Subglacial Lake ◽  
Scientific Instrumentation ◽  
Signy Island ◽  
The Antarctic ◽  
Microbiological Analyses

During the attempt to directly access, measure and sample Subglacial Lake Ellsworth in 2012–2013, we conducted microbiological analyses of the drilling equipment, scientific instrumentation, field camp and natural surroundings. From these studies, a number of lessons can be learned about the cleanliness of deep Antarctic subglacial lake access leading to, in particular, knowledge of the limitations of some of the most basic relevant microbiological principles. Here, we focus on five of the core challenges faced and describe how cleanliness and sterilization were implemented in the field. In the light of our field experiences, we consider how effective these actions were, and what can be learnt for future subglacial exploration missions. The five areas covered are: (i) field camp environment and activities, (ii) the engineering processes surrounding the hot water drilling, (iii) sample handling, including recovery, stability and preservation, (iv) clean access methodologies and removal of sample material, and (v) the biodiversity and distribution of bacteria around the Antarctic. Comparisons are made between the microbiology of the Lake Ellsworth field site and other Antarctic systems, including the lakes on Signy Island, and on the Antarctic Peninsula at Lake Hodgson. Ongoing research to better define and characterize the behaviour of natural and introduced microbial populations in response to deep-ice drilling is also discussed. We recommend that future access programmes: (i) assess each specific local environment in enhanced detail due to the potential for local contamination, (ii) consider the sterility of the access in more detail, specifically focusing on single cell colonization and the introduction of new species through contamination of pre-existing microbial communities, (iii) consider experimental bias in methodological approaches, (iv) undertake in situ biodiversity detection to mitigate risk of non-sample return and post-sample contamination, and (v) address the critical question of how important these microbes are in the functioning of Antarctic ecosystems.

scholarly journals Hot-Water Drilling in the Antarctic Peninsula (Abstract)

1988 ◽  
Vol 11 ◽  
pp. 215-215
Author(s):  
S. Cooper
Keyword(s):  
Antarctic Peninsula ◽  
Temperature Sensors ◽  
Back Pressure ◽  
Hot Water ◽  
Ice Shelves ◽  
Pilot Hole ◽  
Fast Ice ◽  
Drilling System ◽  
The Antarctic ◽  
Practical Field

The British Antarctic Survey has developed a hot-water drilling system used chiefly for installing temperature sensors through ice shelves and for retrieving oceanographic equipment tethered through thick fast ice. The specification, design and operation of the drill for these two activities will be discussed and practical field problems will be highlighted.A novel aspect of the design is the use of reaming nozzles to enlarge a pilot hole. These nozzles eject water upwards along the surface of the nozzle cone, and drill most efficiently when they hang free and unsupported by the sides of the pilot hole. The nozzles incorporate a nozzle-mounted valve, activated when the nozzle cone contacts the ice, thus increasing the back pressure of the water flow. The pressure increase is monitored at the surface and the winch speed is reduced accordingly in order to ensure an efficient drilling operation.

Turbulence Observations in the Grounding Zone Region of Thwaites Glacier

2020 ◽  
Author(s):  
Peter Davis ◽  
Keith Nicholls ◽  
David Holland
Keyword(s):  
Boundary Layer ◽  
Sea Level ◽  
Numerical Models ◽  
Ice Sheet ◽  
Hot Water ◽  
Antarctic Ice Sheet ◽  
Outlet Glacier ◽  
The Future ◽  
Basal Melting ◽  
The Antarctic

<p>Antarctic ice shelves restrain the flow of grounded ice into the ocean, and are thus an important control on Antarctica’s contribution to global sea level rise. West Antarctica represents the largest source of uncertainty in future sea level projections, and Thwaites Glacier has the potential to influence sea level more than any other outlet glacier in this region. The future behaviour of Thwaites Glacier is particular sensitive to basal melting in the grounding zone region. Basal melting is controlled by the turbulent transfer of heat through the ice shelf-ocean boundary layer. The physics of this boundary layer is poorly understood, however, and its inadequate representation in numerical models is hampering our ability to predict the future evolution of the Antarctic ice sheet. Using a hot-water drilled access hole, a turbulence instrument cluster was deployed in the grounding zone region of Thwaites Glacier in January 2020. By observing the momentum and scalar fluxes, these observations provide a unique opportunity to explore the important turbulent processes responsible for modulating the basal melt rate in this region. Ultimately, this observational effort will allow us to better constrain our parameterisations of the grounding zone region in large-scale numerical models, facilitating more accurate simulations of the Antarctic ice sheet in the changing climate.</p>

scholarly journals Developing a hot-water drill system for the WISSARD project: 2. In situ water production

2014 ◽  
Vol 55 (68) ◽  
pp. 298-302 ◽  
Author(s):  
Daren S. Blythe ◽  
Dennis V. Duling ◽  
Dar E. Gibson
Keyword(s):  
Waste Heat ◽  
Hot Water ◽  
Water Production ◽  
Initial Water ◽  
Diameter Hole ◽  
Water Heaters ◽  
Whillans Ice Stream ◽  
The Antarctic ◽  
Drill System

AbstractSuccessful hot-water drilling in the Antarctic is predicated on utilization of the abundant water supply available in the form of the Antarctic ice sheet. For WISSARD (Whillans Ice Stream Subglacial Access Research Drilling) field operations, a snowmelting system was developed that could adequately provide water for a 1000 kW hot-water drill. The system employs ∼100 kW of waste heat from a 225 kW generator to melt snow for initial water (known as seed water) to prime the drill’s high-pressure pumps and water heaters; once the water heaters can be engaged in snowmelting, enough water can be supplied directly to the WISSARD drill to successfully melt a 40 cm diameter hole through 800 m of ice.

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