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Development of Observation Techniques for Inaccessible and Extremely Acidic Crater Lakes: Installation of Temperature Telemetry Buoys, Dredging of Lake Sediments, and Sampling of Lake Waters
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- TERADA Akihiko
- Aso Volcanological Laboratory, Kyoto University
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- YOSHIKAWA Shin
- Aso Volcanological Laboratory, Kyoto University
Bibliographic Information
- Other Title
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- 接近困難な強酸性火口湖における観測技術-水温モニタリング・湖水および湖底泥の採取-
- セッキン コンナン ナ キョウサンセイ カコウコ ニ オケル カンソク ギジュツ スイオン モニタリング コスイ オヨビ コ テイデイ ノ サイシュ
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Description
We describe direct observation techniques for inaccessible and extremely acidic crater lakes surrounded by steep crater walls. Observation equipment and an attached weight suspended beneath a pulley are lowered to the lake surface or lake bottom under gravity along a rope stretched between opposite sides of the crater rim. The weight is tied to the observation equipment using paper string that dissolves in the lake water. This enables the rapid descent of the system from the top of the crater rim to the lake, the automatic deployment of the weight from the observation equipment once the system reaches the lake, and the simple manual retrieval of the system from the lake to the crater rim following the completion of observations.<br>Using the above technique, we deployed two temperature telemetry buoys, including wireless thermometers, upon the crater lake of Aso volcano, Japan, to monitor water temperature. We manually ran a 400 m polypropylene rope (8 mm diameter) between opposite sides of the crater rim. The strength of the rope was sufficient to lower 3-5 kg of equipment to the lake surface. The protective buoy housing the wireless thermometer is made of expanded polystyrene (EPS), enabling it to float on the lake surface. The buoy has a 1-mm-thick coating of polyurethane resin to prevent UV damage. The buoys were fixed at the lake bottom using anchors and 18 m fluororesin ropes initially tied to the system using paper string, enabling the system to readily descend to the lake surface along the stretching rope. The paper strings dissolved several minutes after the equipment had landed on the lake surface, at which point the anchor descended to the lake bottom.<br>To obtain samples of lake sediments, we developed a mud sampler that consists of a stainless steel frame covered by a polyester mesh net. A doughnut-shaped fluororesin block, designed to prevent chemical contamination of the dredged sample, was used as a weight inside the net. The mud sampler and an attached weight suspended beneath two pulleys were lowered to the lake bottom under gravity along the polypropylene rope. The attached weight was tied to the sampler using paper string. We also obtained a sample of lake water using a polypropylene bottle with a weight tied beneath the bottle using paper string.<br>These techniques are expected to contribute to the monitoring of active crater lakes and the underlying hydrothermal system.
Journal
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- Journal of the Geothermal Research Society of Japan
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Journal of the Geothermal Research Society of Japan 31 (2), 117-128, 2009
THE GEOTHERMAL RESEARCH SOCIETY OF JAPAN
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Keywords
Details 詳細情報について
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- CRID
- 1390001206129273344
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- NII Article ID
- 130004551418
- 10024926720
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- NII Book ID
- AN00333995
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- ISSN
- 18835775
- 03886735
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- NDL BIB ID
- 10326008
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- Text Lang
- en
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- Data Source
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- JaLC
- NDL Search
- CiNii Articles
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- Abstract License Flag
- Disallowed