Imaging of the Internal Structure of Permafrost in the Tibetan Plateau Using Ground Penetrating Radar

Imaging of the Internal Structure of Permafrost in the Tibetan Plateau Using Ground Penetrating Radar

The distribution of the permafrost in the Tibetan Plateau has dramatically changed due to climate change, expressed as increasing permafrost degradation, thawing depth deepening and disappearance of island permafrost. These changes have serious impacts on the local ecological environment and the sta...

Full description

Bibliographic Details
Main Authors: Yao Wang, Zhihong Fu, Xinglin Lu, Shanqiang Qin, Haowen Wang, Xiujuan Wang
Format: Article
Language:English
Published: MDPI AG 2019-12-01
Series:Electronics
Subjects:
ground penetrating radar
reverse time migration
tibetan plateau
permafrost active layer
internal structure
Online Access:https://www.mdpi.com/2079-9292/9/1/56
id doaj-40140369afd044648527716db472b34a
record_format Article
spelling doaj-40140369afd044648527716db472b34a2020-11-25T02:40:04ZengMDPI AGElectronics2079-92922019-12-01915610.3390/electronics9010056electronics9010056Imaging of the Internal Structure of Permafrost in the Tibetan Plateau Using Ground Penetrating RadarYao Wang0Zhihong Fu1Xinglin Lu2Shanqiang Qin3Haowen Wang4Xiujuan Wang5State Key Laboratory of Power Transmission Equipment and System Security and New Technology, Chongqing University, Chongqing 400044, ChinaState Key Laboratory of Power Transmission Equipment and System Security and New Technology, Chongqing University, Chongqing 400044, ChinaState Key Laboratory of Power Transmission Equipment and System Security and New Technology, Chongqing University, Chongqing 400044, ChinaState Key Laboratory of Power Transmission Equipment and System Security and New Technology, Chongqing University, Chongqing 400044, ChinaState Key Laboratory of Power Transmission Equipment and System Security and New Technology, Chongqing University, Chongqing 400044, ChinaState Key Laboratory of Power Transmission Equipment and System Security and New Technology, Chongqing University, Chongqing 400044, ChinaThe distribution of the permafrost in the Tibetan Plateau has dramatically changed due to climate change, expressed as increasing permafrost degradation, thawing depth deepening and disappearance of island permafrost. These changes have serious impacts on the local ecological environment and the stability of engineering infrastructures. Ground penetrating radar (GPR) is used to detect permafrost active layer depth, the upper limit of permafrost and the thawing of permafrost with the season’s changes. Due to the influence of complex structure in the permafrost layer, it is difficult to effectively characterize the accurate structure within the permafrost on the radar profile. In order to get the high resolution GPR profile in the Tibetan Plateau, the reverse time migration (RTM) imaging method was applied to GPR real data. In this paper, RTM algorithm is proven to be correct through the groove’s model of forward modeling data. In the Beiluhe region, the imaging result of GPR RTM profiles show that the RTM of GPR makes use of diffracted energy to properly position the reflections caused by the gravels, pebbles, cobbles and small discontinuities. It can accurately determine the depth of the active layer bottom interface in the migration section. In order to prove the accuracy of interpretation results of real data RTM section, we set up the three dielectric constant models based on the real data RTM profiles and geological information, and obtained the model data RTM profiles, which can prove the accuracy of interpretation results of three-line RTM profiles. The results of three-line RTM bears great significance for the study of complex structure and freezing and thawing process of permafrost at the Beiluhe region on the Tibetan Plateau.https://www.mdpi.com/2079-9292/9/1/56ground penetrating radarreverse time migrationtibetan plateaupermafrost active layerinternal structure
collection DOAJ
language English
format Article
sources DOAJ
author Yao Wang
Zhihong Fu
Xinglin Lu
Shanqiang Qin
Haowen Wang
Xiujuan Wang
spellingShingle Yao Wang
Zhihong Fu
Xinglin Lu
Shanqiang Qin
Haowen Wang
Xiujuan Wang
Imaging of the Internal Structure of Permafrost in the Tibetan Plateau Using Ground Penetrating Radar
Electronics
ground penetrating radar
reverse time migration
tibetan plateau
permafrost active layer
internal structure
author_facet Yao Wang
Zhihong Fu
Xinglin Lu
Shanqiang Qin
Haowen Wang
Xiujuan Wang
author_sort Yao Wang
title Imaging of the Internal Structure of Permafrost in the Tibetan Plateau Using Ground Penetrating Radar
title_short Imaging of the Internal Structure of Permafrost in the Tibetan Plateau Using Ground Penetrating Radar
title_full Imaging of the Internal Structure of Permafrost in the Tibetan Plateau Using Ground Penetrating Radar
title_fullStr Imaging of the Internal Structure of Permafrost in the Tibetan Plateau Using Ground Penetrating Radar
title_full_unstemmed Imaging of the Internal Structure of Permafrost in the Tibetan Plateau Using Ground Penetrating Radar
title_sort imaging of the internal structure of permafrost in the tibetan plateau using ground penetrating radar
publisher MDPI AG
series Electronics
issn 2079-9292
publishDate 2019-12-01
description The distribution of the permafrost in the Tibetan Plateau has dramatically changed due to climate change, expressed as increasing permafrost degradation, thawing depth deepening and disappearance of island permafrost. These changes have serious impacts on the local ecological environment and the stability of engineering infrastructures. Ground penetrating radar (GPR) is used to detect permafrost active layer depth, the upper limit of permafrost and the thawing of permafrost with the season’s changes. Due to the influence of complex structure in the permafrost layer, it is difficult to effectively characterize the accurate structure within the permafrost on the radar profile. In order to get the high resolution GPR profile in the Tibetan Plateau, the reverse time migration (RTM) imaging method was applied to GPR real data. In this paper, RTM algorithm is proven to be correct through the groove’s model of forward modeling data. In the Beiluhe region, the imaging result of GPR RTM profiles show that the RTM of GPR makes use of diffracted energy to properly position the reflections caused by the gravels, pebbles, cobbles and small discontinuities. It can accurately determine the depth of the active layer bottom interface in the migration section. In order to prove the accuracy of interpretation results of real data RTM section, we set up the three dielectric constant models based on the real data RTM profiles and geological information, and obtained the model data RTM profiles, which can prove the accuracy of interpretation results of three-line RTM profiles. The results of three-line RTM bears great significance for the study of complex structure and freezing and thawing process of permafrost at the Beiluhe region on the Tibetan Plateau.
topic ground penetrating radar
reverse time migration
tibetan plateau
permafrost active layer
internal structure
url https://www.mdpi.com/2079-9292/9/1/56
work_keys_str_mv AT yaowang imagingoftheinternalstructureofpermafrostinthetibetanplateauusinggroundpenetratingradar
AT zhihongfu imagingoftheinternalstructureofpermafrostinthetibetanplateauusinggroundpenetratingradar
AT xinglinlu imagingoftheinternalstructureofpermafrostinthetibetanplateauusinggroundpenetratingradar
AT shanqiangqin imagingoftheinternalstructureofpermafrostinthetibetanplateauusinggroundpenetratingradar
AT haowenwang imagingoftheinternalstructureofpermafrostinthetibetanplateauusinggroundpenetratingradar
AT xiujuanwang imagingoftheinternalstructureofpermafrostinthetibetanplateauusinggroundpenetratingradar
_version_ 1724783204375724032

Similar Items