青藏高原土壤温湿度观测数据

本数据集是建立在青藏高原基础上的高原土壤水分和土壤温度观测数据,用于量化粗分辨率卫星和土壤水分和土壤温度模型产物的不确定性。青藏高原土壤温湿度观测数据(Tibet-Obs)由三个区域尺度的原位参考网络组成,包括寒冷半干旱气候的那曲网络,寒冷潮湿气候的玛曲网络和寒冷干旱的阿里网络。这些网络提供了对青藏高原不同气候和地表水文气象条件的代表性覆盖。

土壤湿度,土壤温度, 气候带, Tibet-Obs, 玛曲, 那曲, 阿里, 狮泉河
:Bob Su :Hengelosestraat 99, 7514 AE, Enschede
:z.su@utwente.nl :0031 53 4874311

数据内容:青藏高原土壤水分和土壤温度数据。

数据来源: University of Twente, the Netherlands

建设目的:水循环和气候变化

时间范围:14/05/2008 - 08/11/2016

空间范围: 25~40 °N, 74~104 °E

数据格式:* .txt

学科范围:陆地水面储存

- 时间分辨率:15分钟

- 空间分辨率:点测量

- 数据集尺寸:标称深度为5,10,20,40和80厘米的土壤水分和温度测量值

- 单位:土壤水分,cm ^ 3 cm ^ -3; 土壤温度, ℃

Su, Z., Wen, J., Dente, L., van der Velde, R., Wang, L., Ma, Y., Yang, K., & Hu, Z. (2011). The Tibetan Plateau observatory of plateau scale soil moisture and soil temperature (Tibet-Obs) for quantifying uncertainties in coarse resolution satellite and model products. Hydrology and Earth System Sciences, 15, 2303-2316

Su, Z., Wen, J., Dente, L., van der Velde, R., Wang, L., Ma, Y., Yang, K., & Hu, Z. (2011). The Tibetan Plateau observatory of plateau scale soil moisture and soil temperature (Tibet-Obs) for quantifying uncertainties in coarse resolution satellite and model products. Hydrology and Earth System Sciences, 15, 2303-2316

开放评估

1. Lv, S., Zeng, Y., Wen, J., & Su, Z. (2016). A reappraisal of global soil effective temperature schemes. Remote Sensing of Environment, 183, 144-153

2. Lv, S., Zeng, Y., Wen, J., Zeng, D. and Su, Z. (2016) Determination of the optimal mounting depth for calculating effective soil temperature at L-band : Maqu case. In: Remote Sensing : open access, 8 (2016)6article no. 476, 19 p.

3. Zeng, Y., Z. Su, R. van der Velde, L. Wang, K. Xu, X. Wang and J. Wen (2016). "Blending Satellite Observed, Model Simulated, and in Situ Measured Soil Moisture over Tibetan Plateau." Remote Sensing 8(3): 268.

4. Wang, Qiang., van der Velde, R., Su, Z. and Wen, Jun. (2016) Aquarius L-band scatterometer and radiometer observations over a Tibetan Plateau site. In: International Journal of Applied Earth Observation and Geoinformation : JAG, 45 (2016)Part B pp. 165-177.

5. Zheng, D., van der Velde, R., Su, Z., Booij, M.J., Hoekstra, A.Y. and Wen, J. (2015) Assessment of roughness length schemes implemented within the Noah land surface model for high - altitude regions. In: Journal of hydrometeorology : partly open access, 15 (2015)3 pp. 921-937.

6. Zheng, D., van der Velde, R., Su, Z., Wang, X., Wen, J., Booij, M.J., Hoekstra, A.Y. and Chen, Y. (2015) Augmentations to the Noah model physics for application to the Yellow River source area : part I : soil water flow. In: Journal of hydrometeorology : partly open access, 16 (2015)6 pp. 2659–2676.

7. Zheng, D., van der Velde, R., Su, Z., Wang, X., Wen, J., Booij, M.J., Hoekstra, A.Y. and Chen, Y. (2015) Augmentations to the Noah model physics for application to the Yellow River source area : part II : turbulent heat fluxes and soil heat transport. In: Journal of hydrometeorology : partly open access, 16 (2015)6 pp. 2677–2694.

8. Zheng, D., van der Velde, R., Su, Z., Wen, J., Booij, M.J., Hoekstra, A.Y. and Wang, X. (2015) Under - canopy turbulence and root water uptake of a Tibetan meadow ecosystem modeled by Noah - MP. In: Water resources research, 51 (2015)7 pp. 5735-5755.

9. Dente, L., Ferrazzoli, P., Su, Z., van der Velde, R. and Guerriero, L. (2014) Combined use of active and passive microwave satellite data to constrain a discrete scattering model. In: Remote sensing of environment, 155 (2014) pp. 222-238. 

10. Su, Z., Fernández-Prieto, D., Timmermans, J., Chen, Xuelong., Hungershoefer, K., Roebeling, R., Schr?der, M., Schulz, J., Stammes, P., Wang, P. and Wolters, E. (2014) First results of the earth observation Water Cycle Multi - mission Observation Strategy (WACMOS) : open access. In: International Journal of Applied Earth Observation and Geoinformation : JAG, 26 (2014) pp. 270-285.

11. Lv, S., Wen, J., Zeng, Y., Tian, H. and Su, Z.(2014) An improved two - layer algorithm for estimating effective soil temperature in microwave radiometry using in situ temperature and soil moisture measurements. Remote sensing of environment, 152: 356-363.

12. Velde, R., Salama, M.S., Pellarin, T., Ofwono, M., Ma, Y., Su, Z., 2014, Long term soil moisture mapping over the Tibetan plateau using Special Sensor Microwave/Imager. Hydrology and Earth System Sciences 18 (4), 1323-1337

13. Zheng, D., Van Der Velde, R., Su, Z., Booij, M.J., Hoekstra, A.Y., 2013, Assessment of Roughness Length Schemes Implemented within the Noah Land Surface Model for High Altitude Regions. Journal of Hydrometeorology, doi: http://dx.doi.org/10.1175/JHM-D-13-0102.1 

14. Su, Z., de Rosnay, P., Wen, J., Wang, L. and Zeng, Y. (2013) Evaluation of ECMWF's soil moisture analyses using observations on the Tibetan Plateau : open access. In: Journal of geophysical research : D: Atmospheres, (2013),  118 (11), pp 5304–5318. Full text  

15. Dente, L., Vekerdy, Z., de Jeu, R. and Su, Z. (2013) Seasonality and autocorrelation of satellite - derived soil moisture products. In: International journal of remote sensing, 34 (2013)9-10 pp. 3231-3247.

16. van der Velde, R., Salama, M.S., van Helvoirt, M.D. and Su, Z. (2012) Decomposition of uncertainties between coarse MM5 - Noah - Simulated and fine ASAR - retrieved soil moisture over Central Tibet. In: Journal of hydrometeorology : partly open access, 13 (2012)6 pp. 1925-1938.

17. Dente, L., Vekerdy, Z., Wen, J. and Su, Z. (2012) Maqu network for validation of satellite - derived soil moisture products. In: International Journal of Applied Earth Observation and Geoinformation : JAG, 17 (2012) pp. 55-65. 

18. van der Velde, R., Su, Z., van Oevelen, P., Wen, J., Ma, Y. and Salama, M.S. (2012) Soil moisture mapping over the central part of the Tibetan Plateau using a series of ASAR WS images. In: Remote sensing of environment, 120 (2012) pp. 175-187. 

19. Dente, L., Su, Z. and Wen, J. (2012) Validation of SMOS soil moisture products over the Maqu and Twente regions. In: Sensors : journal on the science and technology of sensors and biosensors :12 (2012)8 pp. 9965-9986. 

数据只能用于学术研究。 禁止将数据用于其他目的(例如商业用途)。 不允许任何用户将数据传输到任何第三方。

 

建议用户参考以下出版物: 

Su, Z., Wen, J., Dente, L., van der Velde, R., Wang, L., Ma, Y., Yang, K., & Hu, Z. (2011). The Tibetan Plateau observatory of plateau scale soil moisture and soil temperature (Tibet-Obs) for quantifying uncertainties in coarse resolution satellite and model products. Hydrology and Earth System Sciences, 15, 2303-2316

Zeng, Y., Z. Su, R. van der Velde, L. Wang, K. Xu, X. Wang and J. Wen (2016). "Blending Satellite Observed, Model Simulated, and in Situ Measured Soil Moisture over Tibetan Plateau." Remote Sensing 8(3): 268.

Su, Z., de Rosnay, P., Wen, J., Wang, L. and Zeng, Y. (2013) Evaluation of ECMWF's soil moisture analyses using observations on the Tibetan Plateau :open access. In: Journal of geophysical research : D: Atmospheres, (2013)

Dente, L., Vekerdy, Z., Wen, J. and Su, Z. (2012) Maqu network for validation of satellite - derived soil moisture products. In: International Journal of Applied Earth Observation and Geoinformation : JAG, 17 (2012) pp. 55-65.

van der Velde, R., Su, Z., van Oevelen, P., Wen, J., Ma, Y. and Salama, M.S. (2012) Soil moisture mapping over the central part of the Tibetan Plateau using a series of ASAR WS images. Remote sens. Environ., 120,175-187.

 
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