|
论文题目 |
作者 |
刊物名称 |
年/卷/页 |
|
Characteristics of asphalt pavement damage in degrading permafrost regions: Case study of the Qinghai-Tibet Highway, China |
Chai Mingtang |
Journal of Cold Regions Engineering |
2018, 32(2): 1-12 |
|
A method for calculating unfrozen water content of silty clay with consideration of freezing point |
Chai Mingtang |
Applied Clay Science |
2018, 161: 471-481 |
|
Impacts of warming and nitrogen addition on soil autotrophic and heterotrophic respiration in a semi-arid environment |
Chao Fang |
Agricultural and Forest Meteorology |
2018, 248, 449-457 |
|
Changes of soil properties regulate the soil organic carbon loss with grassland degradation on the Qinghai-Tibet Plateau |
Fei Peng |
Ecological Indicators |
2018, 93:572-580 |
|
Evaluation of thermokarst lake water balance in the Qinghai–Tibet Plateau via isotope tracers |
Gao Zeyong |
Science of The Total Environment |
2018, 636,1-11 |
|
Root-induced changes to soil water retention in permafrost regions of the Qinghai-Tibet Plateau, China |
Gao Zeyong |
Journal of Soils and Sediments |
2018, 18(3):791-803 |
|
Consumption of atmospheric methane by the Qinghai–Tibet Plateau alpine steppe ecosystem |
Hanbo Yun |
The Cryosphere |
2018, 12 (9): 2803-2819 |
|
Numerical simulation of efficient cooling by coupled RR and TCPT on railway embankments in permafrost regions |
Hou Yandong |
Applied Thermal Engineering |
2018, 133, 351-360 |
|
Experimental study on the freezing–thawing deformation of a silty clay |
Jianguo Lu |
Cold Regions Science and Technology |
2018, 151, 19-27 |
|
A new model to determine the thermal conductivity of fine-grained soils |
Jun Bi |
International Journal of Heat and Mass Transfer |
2018, 123, 407-717 |
|
Stability analysis of transmission tower foundations in permafrost equipped with thermosiphons and vegetation cover on the Qinghai-Tibet Plateau |
Lei Guo |
Heat and Mass Transfer |
2018, 121,367-376 |
|
The impacts of climate change and human activities on alpine vegetation and permafrost in the Qinghai-Tibet Engineering Corridor |
Lihui Luo |
Ecological Indicators |
2018, 93:24:35 |
|
PIC v1.3: comprehensive R package for computing permafrost indices with daily weather observations and atmospheric forcing over the Qinghai–Tibet Plateau |
Lihui Luo |
Geoscientific Model Development |
2018, 11:2475-2491 |
|
Thermal performance of a novel crushed rock embankment structure for expressway in permafrost regions |
Liu Minghao |
International Journal of Heat and Mass Transfer |
2018, 127:1178- 1188 |
|
Variations in the northern permafrost boundary over the last four decades in the Xidatan region, Qinghai–Tibet Plateau |
Luo Jing |
Journal of Mountain Science |
2018,15(4):765-778 |
|
Field experimental study on long-term cooling and deformation characteristics of crushed-rock revetment embankment at the Qinghai–Tibet Railway |
Luo Jing |
Applied Thermal Engineering |
2018,139:256-263 |
|
Field experimental study on long-term cooling performance of sun-shaded embankments at the Qinghai-Tibet Railway, China |
Luo Jing |
Cold Regions Science and Technology |
2018, 145:14-20 |
|
Integration of terrestrial laser scanning and soil sensors for deformation and hydrothermal monitoring of frost mounds |
Luo Lihui |
Measurement |
2018, 131:513-523 |
|
The impacts of climate change and human activities on alpine vegetation and permafrost in the Qinghai-Tibet Engineering Corridor |
Luo Lihui |
Ecological Indicators |
2018, 93, 24-35 |
|
Variations in the northern permafrost boundary over the last four decades in the Xidatan region, Qinghai–Tibet Plateau |
Luo, J. |
Journal of Mountain Science |
2018, 15(4): 765-778 |
|
Field experimental study on long-term cooling and deformation characteristics of crushed-rock revetment embankment at the Qinghai–Tibet Railway |
Luo, J. |
Applied Thermal Engineering |
2018,139:256-263. DOI: 10.1016/j.applthermaleng |
|
Thermal performance of a novel crushed-rock embankment structure for expressway in permafrost regions |
Minghao Liu |
International Journal of Heat and Mass Transfer |
2018, 127:1178-1188 |
|
Characteristics of Asphalt Pavement Damage in Degrading Permafrost Regions: Case Study of the Qinghai–Tibet Highway, China |
Mingtang Chai |
Journal of Cold Regions Engineering |
2018, 32(2). DOI: 10.1061/(ASCE)CR.1943-5495.0000165 |
|
Variation of the thermal conductivity of a silty clay during a freezing-thawing process |
Mingyi Zhang |
International Journal of Heat and Mass Transfer |
2018,124:1059-1067 |
|
Evaluation of calculation models for the thermal conductivity of soils |
Mingyi Zhang |
International Communications in Heat and Mass Transfer |
2018, 94:14-23 |
|
Impacts of supra-permafrost water ponding and drainage on a railway embankment in continuous permafrost zone, the interior of the Qinghai-Tibet Plateau |
Mu Yanhu |
Cold Regions Science and Technology |
2018, 154:23-31 |
|
Long-Term Thermal Effects of Air Convection Embankments in Permafrost Zones: Case Study of the Qinghai–Tibet Railway, China |
Mu Yanhu |
Journal of Cold Regions Engineering |
2018, 32(4): 05018004 |
|
Permafrost Distribution along the Qinghai-Tibet Engineering Corridor, China Using High-Resolution Statistical Mapping and Modeling Integrated with Remote Sensing and GIS |
Niu Fujun |
Remote Sensing |
2018, 10(2):215 |
|
Hydrological insights from hydrogen and oxygen isotopes in Source Area of the Yellow River, east-northern part of Qinghai-Tibet Plateau |
Peng Yi |
Journal of Radioanalytical and Nuclear Chemistry |
2018, 317 (1): 131-144 |
|
A novel refrigerant system to reduce refreezing time of cast-in-place pile foundation in permafrost regions |
Shang Yunhu |
Applied Thermal Engineering |
2018, 128:1151-1158 |
|
Permafrost Presence/Absence Mapping of the Qinghai-Tibet Plateau Based on Multi-Source Remote Sensing Data |
Shi Yaya |
Remote Sensing |
2018, 10(2):309 |
|
An effective way to estimate the Poisson's ratio of silty clay in seasonal frozen regions |
Shufeng Chen |
Cold Regions Science and Technology |
2018,154:74-84 |
|
Characteristics of thawed interlayer and its effect on embankment settlement along the Qinghai-Tibet Railway in permafrost regions |
Sun Zhizhong |
Journal of Mountain Science |
2018, 15(5): 1090-1100 |
|
Embankment Stability of the Qinghai-Tibet Railway in Permafrost regions |
Sun Zhizhong |
Journal of Cold Regions Engineering |
2018, 32(1):04018001 |
|
Numerical analysis of ground motion characteristics in permafrost regions along the Qinghai-Tibet Railway |
Tuo Chen |
Cold Regions Science and Technology |
2018, 148:88-95 |
|
An estimation of ground ice volumes in permafrost layers in Northeastern Qinghai-Tibet Plateau |
Wang Shengting |
Chinese Geographical Science |
2018, 28(1):61-73 |
|
Thermal interaction between a thermokarst lake and a nearby embankment in permafrost regions |
Wen Zhi |
Cold Regions Science and Technology |
2018, 155: 214-224 |
|
Experimental study of the hydro-thermal characteristics and frost heave behavior of a saturated silt within a closed freezing system |
Xiyin Zhang |
Applied Thermal Engineering |
2018, 129, 1447-1454 |
|
Factors influencing the reliability of grounded and floating ice distinguishing based on ground penetrating radar reflection amplitude |
Yanhui You |
Cold Regions Science and Technology |
2018, 154, 1-8 |
|
Effects of a thaw slump on active layer in permafrost regions with the comparison of effects of thermokarst lakes on the Qinghai–Tibet Plateau, China |
YiBo Wang |
Geoderma |
2018, 314,47–57 |
|
Formation mechanism of longitudinal cracks in expressway embankments with inclined thermosyphons in warm and ice-rich permafrost regions |
Yuan Chang |
Applied Thermal Engineering |
2018,133, 21-32 |
|
Scientific concept and application of frozen soil engineering system |
Zhang Z |
Cold Regions Science and Technology |
2018, 146: 127-132 |
|
Characteristics of thawed interlayer and its effect on embankment settlement along the Qinghai-Tibet Railway in permafrost regions |
Zhizhong Sun |
Journal of Mountain Science |
2018, 15(5):1090-1100 |
|
Embankment Stability of the Qinghai–Tibet Railway in Permafrost Regions |
Zhizhong Sun |
Journal of Cold Regions Engineering |
2018, 32(1), DOI: 10.1061/(ASCE)CR.1943-5495.0000153. |
|
重复机车荷载作用下青藏铁路冻土路基累积塑性变形分析 |
陈拓 |
铁道科学与工程学报 |
2018, 6, 1430-1436 |
|
年西藏季节冻土最大冻结深度的时空变化 |
高思如 |
冰川冻土 |
2018, 40(2): 223-230 |
|
风积沙环境下高等级公路冻土块石路基降温性能分析 |
韩风雷 |
冰川冻土 |
2018, 40(03):528-538 |
|
青藏高原热融湖塘的水热过程及其对下伏多年冻土的热影响 |
胡晓莹 |
湖泊科学 |
2018,30(3): 825-835 |
|
青藏高原不同高寒生态系统类型下多年冻土活动层水热过程差异研究 |
蒋观利 |
冰川冻土 |
2018, 40(1): 7-17 |
|
多年冻土区线性工程的生态环境影响研究现状与展望 |
刘亚丽 |
冰川冻土 |
2018, 40(4):728-737 |
|
主动冷却路基:青藏铁路成功建成的科技支撑 |
马巍 |
前沿科学 |
2018, 3:63-65 |
|
北京-莫斯科高铁工程走廊寒区工程问题与防治对策研究 |
马巍 |
中国科学院院刊 |
2018, 33(S2):30-33 |
|
冻土蠕变特性研究现状及展望 |
美启航 |
灾害学 |
2018,33(S1):47-56 |
|
青藏高原多年冻土区热喀斯特湖环境及水文学效应研究 |
牛富俊 |
地球科学进展 |
2018, 33(4):335-342 |
|
青藏铁路沿线天然场地多年冻土变化 |
孙志忠 |
地球科学进展 |
2018,33(3): 248-256 |
|
风沙堆积对下伏多年冻土影响的数值模拟 |
王陆阳 |
冰川冻土 |
2018, 40(4): 738-747 |
|
气候变暖下青藏高原冻土路基地温场演化规律研究 |
杨凯飞 |
地震工程学报 |
2018, 40(04):734-744 |
|
天山胜利达坂地区积雪分布特征 |
赵静毅 |
山地学报 |
2018, 36(01): 98-106 |
|
Research on Bearing Capacity of Pile Foundation with Impact of Subpermafrost Water |
Shi X |
Proceedings of China-Europe Conference on Geotechnical Engineering |
2018; 1403-1406,(EI) |
|
Study on the stability of spread-footing foundations on permafrost regions |
Wen Zhi |
Proceedings of China-Europe Conference on Geotechnical Engineering |
2018,1429–1432,(EI) |
