Sensitivity analysis of ice dynamics to climate forcing scenarios in David Glacier, East Antarctica
학위논문 (석사)-- 서울대학교 대학원 : 자연과학대학 지구환경과학부, 2018. 2. 이강근. As global mean temperature rises, there has been a growing interest in how much sea level would rise occurred due to polar glacial discharge to ocean. Currently, West Antarctica has been spotlighted due to ice discharge from the glaciers, compare...
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서울대학교 대학원
2018
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| Online Access: | http://hdl.handle.net/10371/142462 |
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ftseoulnuniv:oai:s-space.snu.ac.kr:10371/142462 |
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ftseoulnuniv:oai:s-space.snu.ac.kr:10371/142462 2023-05-15T13:48:54+02:00 Sensitivity analysis of ice dynamics to climate forcing scenarios in David Glacier, East Antarctica 기후 변화 시나리오에 따른 데이비드 빙하 빙상 거동 민감도 분석 박인우 이강근 자연과학대학 지구환경과학부 2018 application/pdf 4223757 bytes http://hdl.handle.net/10371/142462 en eng 서울대학교 대학원 000000150582 http://hdl.handle.net/10371/142462 David Glacier Sea level equivalent Floating ice melting rate Ice front position Shallow Shelf Approximation model 550 Thesis 2018 ftseoulnuniv 2018-06-01T00:26:30Z 학위논문 (석사)-- 서울대학교 대학원 : 자연과학대학 지구환경과학부, 2018. 2. 이강근. As global mean temperature rises, there has been a growing interest in how much sea level would rise occurred due to polar glacial discharge to ocean. Currently, West Antarctica has been spotlighted due to ice discharge from the glaciers, compared to sea level contribution in East Antarctic glaciers. Bed elevation at East Antarctica is largely lying above sea level, which is likely to stable compared to West Antarctica. However, East Antarctic regions contain 10 times large sea level rise potential than West Antarctica. David Glacier, located in East Antarctica, is a region of fjord-like valley glacier, and ice drains into ocean through Drygalski Ice Tongue, which of length is about 80 km. To understand what mechanism modulates sea level rise, it is necessary to identify key factors affecting the acceleration of mass discharge in David glacier. Based on current knowledge, ice shelf buttressing effect, basal melting, and SMB (surface mass balance) are the components that have been known to affect glacier speed. Here, 2D Shallow Shelf Approximation model of the Ice Sheet System Model was used to predict response of glacier velocity distribution and contribution of sea level equivalent change depending on various forcing scenarios. Firstly, friction coefficient beneath glacier and ice rigidity on floating ice were estimated through inversion method, which constructed the initial condition of the regional model. Then, changing SMB, floating ice melting rate, and ice front position retreat could alter the sea level rise contribution and ice velocity. In the results, basal drag stress obtained through inversion method was largely calculated in the ice fall area where the subglacial ridge existed. Sea level equivalent for control model was -2.0 mm equivalent to ice mass gain of 15 Gt/yr during 50 years, and relatively stable than other fast flow regions, such as Pine Island Glacier. Ice front retreat over threshold, which was about 90 km from ice front, accelerated the ice velocity near grounding line larger than twofold floating ice melting rate. This ice velocity acceleration influenced increase in sea level equivalent of -1.95 mm in case of furthermost ice front retreat. However, ice tongue and 8 km region of ice shelf position did not affect the ice velocity acceleration. 1. INTRODUCTIONS 1 1.1. Background 1 1.2. David Glacier 4 1.3. Objectives 8 2. METHODS 9 2.1. Stress Balance Models 11 2.1.1. Full Stokes Model (FS) 11 2.1.2. Higher Order Model (HO) 13 2.1.3. Shallow Shelf Approximation Model (SSA) 14 2.1.4. Boundary Conditions 15 2.1.5. Friction Coefficient Parameterization at Grounding Line 17 2.2. Mass Transport Model 19 2.3. Initialization 20 2.3.1. Input Data 20 2.3.2. Basal Friction and Ice Rigidity 36 2.3.3. Relaxation 42 2.4. Climate Forcing Scenarios 44 3. RESULTS AND DISCUSSION 48 3.1. Initialization 48 3.1.1. Inversion Results 48 3.1.2. Relaxation Results 54 3.2. Results of Climate Forcing Scenarios 58 4. CONCLUSIONS 69 5. REFRENCES 71 Master Thesis Antarc* Antarctic Antarctica David Glacier East Antarctica Ice Sheet Ice Shelf Pine Island Pine Island Glacier West Antarctica Seoul National University: S-Space Antarctic David Glacier ENVELOPE(160.000,160.000,-75.333,-75.333) Drygalski ENVELOPE(-61.000,-61.000,-64.717,-64.717) Drygalski Ice Tongue ENVELOPE(163.500,163.500,-75.400,-75.400) East Antarctica Pine Island Glacier ENVELOPE(-101.000,-101.000,-75.000,-75.000) West Antarctica |
| institution |
Open Polar |
| collection |
Seoul National University: S-Space |
| op_collection_id |
ftseoulnuniv |
| language |
English |
| topic |
David Glacier Sea level equivalent Floating ice melting rate Ice front position Shallow Shelf Approximation model 550 |
| spellingShingle |
David Glacier Sea level equivalent Floating ice melting rate Ice front position Shallow Shelf Approximation model 550 박인우 Sensitivity analysis of ice dynamics to climate forcing scenarios in David Glacier, East Antarctica |
| topic_facet |
David Glacier Sea level equivalent Floating ice melting rate Ice front position Shallow Shelf Approximation model 550 |
| description |
학위논문 (석사)-- 서울대학교 대학원 : 자연과학대학 지구환경과학부, 2018. 2. 이강근. As global mean temperature rises, there has been a growing interest in how much sea level would rise occurred due to polar glacial discharge to ocean. Currently, West Antarctica has been spotlighted due to ice discharge from the glaciers, compared to sea level contribution in East Antarctic glaciers. Bed elevation at East Antarctica is largely lying above sea level, which is likely to stable compared to West Antarctica. However, East Antarctic regions contain 10 times large sea level rise potential than West Antarctica. David Glacier, located in East Antarctica, is a region of fjord-like valley glacier, and ice drains into ocean through Drygalski Ice Tongue, which of length is about 80 km. To understand what mechanism modulates sea level rise, it is necessary to identify key factors affecting the acceleration of mass discharge in David glacier. Based on current knowledge, ice shelf buttressing effect, basal melting, and SMB (surface mass balance) are the components that have been known to affect glacier speed. Here, 2D Shallow Shelf Approximation model of the Ice Sheet System Model was used to predict response of glacier velocity distribution and contribution of sea level equivalent change depending on various forcing scenarios. Firstly, friction coefficient beneath glacier and ice rigidity on floating ice were estimated through inversion method, which constructed the initial condition of the regional model. Then, changing SMB, floating ice melting rate, and ice front position retreat could alter the sea level rise contribution and ice velocity. In the results, basal drag stress obtained through inversion method was largely calculated in the ice fall area where the subglacial ridge existed. Sea level equivalent for control model was -2.0 mm equivalent to ice mass gain of 15 Gt/yr during 50 years, and relatively stable than other fast flow regions, such as Pine Island Glacier. Ice front retreat over threshold, which was about 90 km from ice front, accelerated the ice velocity near grounding line larger than twofold floating ice melting rate. This ice velocity acceleration influenced increase in sea level equivalent of -1.95 mm in case of furthermost ice front retreat. However, ice tongue and 8 km region of ice shelf position did not affect the ice velocity acceleration. 1. INTRODUCTIONS 1 1.1. Background 1 1.2. David Glacier 4 1.3. Objectives 8 2. METHODS 9 2.1. Stress Balance Models 11 2.1.1. Full Stokes Model (FS) 11 2.1.2. Higher Order Model (HO) 13 2.1.3. Shallow Shelf Approximation Model (SSA) 14 2.1.4. Boundary Conditions 15 2.1.5. Friction Coefficient Parameterization at Grounding Line 17 2.2. Mass Transport Model 19 2.3. Initialization 20 2.3.1. Input Data 20 2.3.2. Basal Friction and Ice Rigidity 36 2.3.3. Relaxation 42 2.4. Climate Forcing Scenarios 44 3. RESULTS AND DISCUSSION 48 3.1. Initialization 48 3.1.1. Inversion Results 48 3.1.2. Relaxation Results 54 3.2. Results of Climate Forcing Scenarios 58 4. CONCLUSIONS 69 5. REFRENCES 71 Master |
| author2 |
이강근 자연과학대학 지구환경과학부 |
| format |
Thesis |
| author |
박인우 |
| author_facet |
박인우 |
| author_sort |
박인우 |
| title |
Sensitivity analysis of ice dynamics to climate forcing scenarios in David Glacier, East Antarctica |
| title_short |
Sensitivity analysis of ice dynamics to climate forcing scenarios in David Glacier, East Antarctica |
| title_full |
Sensitivity analysis of ice dynamics to climate forcing scenarios in David Glacier, East Antarctica |
| title_fullStr |
Sensitivity analysis of ice dynamics to climate forcing scenarios in David Glacier, East Antarctica |
| title_full_unstemmed |
Sensitivity analysis of ice dynamics to climate forcing scenarios in David Glacier, East Antarctica |
| title_sort |
sensitivity analysis of ice dynamics to climate forcing scenarios in david glacier, east antarctica |
| publisher |
서울대학교 대학원 |
| publishDate |
2018 |
| url |
http://hdl.handle.net/10371/142462 |
| long_lat |
ENVELOPE(160.000,160.000,-75.333,-75.333) ENVELOPE(-61.000,-61.000,-64.717,-64.717) ENVELOPE(163.500,163.500,-75.400,-75.400) ENVELOPE(-101.000,-101.000,-75.000,-75.000) |
| geographic |
Antarctic David Glacier Drygalski Drygalski Ice Tongue East Antarctica Pine Island Glacier West Antarctica |
| geographic_facet |
Antarctic David Glacier Drygalski Drygalski Ice Tongue East Antarctica Pine Island Glacier West Antarctica |
| genre |
Antarc* Antarctic Antarctica David Glacier East Antarctica Ice Sheet Ice Shelf Pine Island Pine Island Glacier West Antarctica |
| genre_facet |
Antarc* Antarctic Antarctica David Glacier East Antarctica Ice Sheet Ice Shelf Pine Island Pine Island Glacier West Antarctica |
| op_relation |
000000150582 http://hdl.handle.net/10371/142462 |
| _version_ |
1766249950097702912 |