Your search keyword '"Nozomu Naito"' showing total 9 results

1. Application to glacier observation of high-precision three-dimensional position measurement using cameras.

Author

Hiroaki Ota, Takeshi Hashimoto, Yohei Nagakura, Shuhei Takamura, Akira Fukuda, Masamu Aniya, Nozomu Naito, Hiroyuki Enomoto, Shin Sugiyama, and Pedro Skvarca

Published

2010

2. Thermal structure of proglacial lakes in Patagonia

Author

Kazuhisa A. Chikita, Pedro Skvarca, Daiki Sakakibara, Yoshihiko Ohashi, Shin Sugiyama, Takanobu Sawagaki, Masahiro Minowa, and Nozomu Naito

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ice field, Front (oceanography), Sediment, Glacier, Fjord, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Oceanography, Upwelling, Glacial period, Meltwater, Geomorphology, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Calving glaciers are rapidly retreating in many regions under the influence of ice-water interactions at the glacier front. In contrast to the numerous researches conducted on fjords in front of tidewater glaciers, very few studies have been reported on lakes in which freshwater calving glaciers terminate. To better understand ice-water interactions at the front of freshwater calving glaciers, we measured lakewater temperature, turbidity, and bathymetry near Glaciar Perito Moreno, Upsala, and Viedma, large calving glaciers of the Southern Patagonia Icefield. The thermal structures of these lakes were significantly different from those reported in glacial fjords. There was no indication of upwelling subglacial meltwater; instead, turbid and cold glacial water discharge filled the region near the lake bottom. This was because water density was controlled by suspended sediment concentrations rather than by water temperature. Near-surface wind-driven circulation reaches a depth of similar to 180 m, forming a relatively warm isothermal layer (mean temperature of similar to 5-6 degrees C at Perito Moreno, similar to 3-4 degrees C at Upsala, and similar to 6-7 degrees C at Viedma), which should convey heat energy to the ice-water interface. However, the deeper part of the glacier front is in contact with stratified cold water, implying a limited amount of melting there. In the lake in front of Glaciar Viedma, the region deeper than 120 m was filled entirely with turbid and very cold water at pressure melting temperature. Our results revealed a previously unexplored thermal structure of proglacial lakes in Patagonia, suggesting its importance in the subaqueous melting of freshwater calving glaciers.

Published

2016

3. Ice speed of a calving glacier modulated by small fluctuations in basal water pressure

Author

Shin Sugiyama, Shun Tsutaki, Pedro Skvarca, Hiroyuki Enomoto, Kenta Tone, Sebastián Marinsek, Nozomu Naito, and Masamu Aniya

Subjects

Glacier ice accumulation, geography, geography.geographical_feature_category, Ice stream, Glacier, Antarctic sea ice, Glacier morphology, Arctic ice pack, General Earth and Planetary Sciences, Cryosphere, Ice sheet, Geomorphology, Geology

Abstract

Ice flow acceleration has played a crucial role in the rapid retreat of calving glaciers in Alaska, Greenland and Antarctica. High-frequency measurements of ice speed and basal water temperatures from a calving glacier in Patagonia show that changes in basal water pressure by a few per cent can significantly affect ice flow speed. Ice flow acceleration has played a crucial role in the rapid retreat of calving glaciers in Alaska1,2, Greenland and Antarctica3,4. Glaciers that calve in water flow much faster than those that terminate on land, as a result of enhanced basal ice motion where basal water pressure is high5. However, a scarcity of subglacial observations in calving glaciers limits a mechanistic understanding. Here we present high-frequency measurements of ice speed and basal water pressures from Glaciar Perito Moreno, a fast-flowing calving glacier in Patagonia. We measured water pressure in boreholes drilled at a site where the glacier is 515±5 m thick, and where more than 60% of the ice is below the level of proglacial lakes. We found that the mean basal water pressure was about 95% of the pressure imposed by the weight of the overlying ice. Moreover, changes in basal water pressure by a few per cent drove nearly 40% of the variations in ice flow speed. The ice speed was strongly correlated to air temperature, suggesting that glacier motion was modulated by water pressure changes as meltwater entered the system. We conclude that basal water pressure in calving glaciers is important for glacier dynamics, and closely connected to climate conditions.

Published

2011

4. Applications of High-Precise Three-Dimensional Measurement System

Author

Akira Fukuda, Hiroyuki Enomoto, Takeshi Hashimoto, Mitsuo Kaneko, Pedro Skvarca, András Rövid, Nozomu Naito, Masamu Aniya, and Hiroaki Ohta

Subjects

geography, Accuracy and precision, geography.geographical_feature_category, business.industry, System of measurement, Global warming, General Engineering, Glacier, Three dimensional measurement, Close relationship, Measuring instrument, Global Positioning System, business, Geology, Remote sensing

Abstract

To reveal the influence of global warming on glaciers, highly accurate observations of glacier movement must continue every year. It is thought that there is a close relationship between glacier moving speed and global warming. Thus, there have been precise, detailed observations of the movement of the Perito Moreno glacier in Patagonia of the Argentine Republic over the past five years. The measurement method of using GPS and an optical measuring instrument is generally used to monitor glacier movement, but the measurement accuracy attained is not optimal because of the huge size of the glacier. The measurement system used for the Perito Moreno observations, however, could realize high accuracy measurement over long distance. The measurement system is based on the principle of stereo measurement using cameras. This paper describes the results of the Perito Moreno glacier observations of this year and considers the effectiveness of glacier observation using cameras.

Published

2011

5. The Activities Perfomed by Jyoshi-Gakusei Career Design Center, Hiroshima Institute of Technology

Author

Nozomu Naito, Junji Kubokawa, Kaori Murakami, Yumiko Fukuda, Hiroshi Sugita, Koji Kakugawa, and Azuma Nakashima

Subjects

Engineering, business.industry, Center (algebra and category theory), Engineering ethics, business

Published

2011

6. Glaciological Research Project in Patagonia 2006-2009

Author

Gonzalo Barcaza, Hiroyuki Enomoto, Sebastián Marinsek, Masamu Aniya, Nozomu Naito, Pedro Skvarca, Keiko Konya, Kenta Tone, Shun Tsutaki, Ryo Anma, Kazuaki Hori, Shin Sugiyama, Tatsuto Aoki, Takayuki Nuimura, and Takane Matsumoto

Subjects

geography, geography.geographical_feature_category, Oceanography, Pleistocene, Peninsula, Moraine, Glacier, Last Glacial Maximum, Glacial period, Debris, Coring, Geology, Earth-Surface Processes

Abstract

The Glaciological Research Project in Patagonia (GRPP) 2006-2009 was carried out with several objectives at Glaciar Perito Moreno of the Hielo Patagonico Sur (HPS), in the area of the Hielo Patagonico Norte (HPN) and along the Pacific coast. At Glaciar Perito Moreno, hot water drilling was carried out at about 5km upstream from the terminus, reaching the glacier bottom at ca. 515m, in order to monitor subglacial water pressure. Good positive correlations among air temperature, subglacial water pressure and glacier flow speed were found. Based on 14C dating of tree and organic samples, it is proposed that Glaciar Perito Moreno made two Little Ice Age (LIA) advances at AD1600-1700 and ca. 130-100y BP (AD1820-50). Fan deltas located at the mouth of big rivers around Lago General Carrera (Buenos Aires) and Lago Cochrane (Pueyrredon), in the area east of the HPN, were investigated to elucidate their development. The variations of 21 outlet glaciers of the HPN elucidated from aerial surveys for 2004/05-2008/09 revealed an areal loss of 8.67km2 in four years. A general slowing down of retreats was observed with a few exceptions. Meteorological measurements at Glaciar Exploradores of the HPN from 2005 to 2009 indicate that air temperature ranged from 17.4°C to -10.5°C. The total annual precipitation was about 3000mm. Glacier surface melt was observed at two spots. Sediment and water discharges from the glacier showed that while water discharge fluctuated a lot, suspended sediment concentration was rather stable in summer. A single channel seismic profiling during the JAMSTEC MR08-06 cruise identified a probable submerged moraine formed before the last glacial maximum (LGM) in the Golfo de Penas, south of Taitao Peninsula. Piston coring along the Chilean coast further indicates that ice-rafted debris recorded the LGM and earlier Late Pleistocene events of the glacial advance.

Published

2011

7. Hot-water drilling at Glaciar Perito Moreno, Southern Patagonia Icefield

Author

Shin Sugiyama, Sebastián Marinsek, Nozomu Naito, Kenta Tone, Hiroyuki Enomoto, Kunio Shinbori, Masamu Aniya, and Pedro Skvarca

Subjects

Hydrology, geography, geography.geographical_feature_category, Drilling system, Borehole, Ice field, Drilling, Ice calving, borehole, パタゴニア, Glacier, Overburden pressure, Drainage system (geomorphology), Patagonia, カービング氷河, calving glacier, 掘削孔, 氷河底面水圧, 熱水掘削, subglacial water pressure, Geomorphology, Geology, hot water drilling, Earth-Surface Processes

Abstract

Glaciar Perito Moreno is one of the major freshwater calving glaciers in the Southern Patagonia Icefield. Its fast-flowing characteristic is probably due to high water pressure at the glacier bed, however, subglacial conditions have never been observed in Patagonia until our recent undertaking. To investigate the role of subglacial water pressure in the calving glacier dynamics, we performed hot-water drilling at Glaciar Perito Moreno from February to March 2010. This study represents the first attempt ever at hot-water glacier drilling in Patagonia. Two boreholes were drilled to the bed at 4.7km upglacier from the terminus, where the ice was revealed to be 515±5m thick and the bed located at about 330m below the proglacial lake level. The water levels in the boreholes were >100m above the lake level, which indicates that more than 90% of the ice overburden pressure was balanced out by the subglacial water pressure. Water in the boreholes had drained away before the drilling reached the bed, suggesting the existence of an englacial drainage system. These results provide crucial information for understanding the hydraulic and hydrological conditions of calving glaciers. In order to drill a 500m deep glacier, an existing hot-water drilling system was adapted by increasing the number of high-pressure hot-water machines. The drilling operation at Glaciar Perito Moreno confirmed the system's capacity to drill a 500-m-deep borehole at a rate of 50mh-1 with fuel consumption rates of 15.7lh-1 for diesel and 3.9lh-1 for petrol.

Published

2010

8. Recent glacier shrinkage in Nepal Himalayas

Author

Nozomu Naito

Subjects

Glacier ice accumulation, geography, Glacier mass balance, geography.geographical_feature_category, Glacier, Physical geography, Surge, Cirque glacier, Glacier morphology, Geomorphology, Geology, Shrinkage

Abstract

Significant glacier shrinkage has generally been observed among Nepal Himalayas in recent years. The shrinkage is probably accelerated in the 1990s among the small glaciers. Large debris-covered glaciers were also observed to shrink more significantly than expected before. In addition to the increasing observations, glacier fluctuation models which can account for the characteristics of glaciers in the Nepal Himalayas have gradually been developed, and numerical experiments with the models have been performed. New knowledges on the glacier shrinkage during about thirty years since the 1970s are introduced as reviews of both the observations and the numerical experiments.

Published

2001

9. Summer Accumulation Type Glaciers

Author

Nozomu Naito

Published

2011