SSHCZO -- Hydropedologic Properties, Matric Potential -- MPS Probes -- Shale Hills -- (2007-2014)

OVERVIEW

Description/Abstract

The Real-Time Soil Moisture Monitoring Network provides integrated observation of water, energy and temperature in the soils of the Shale Hills Susquehanna Critical Zone Observatory watershed. Soil Matric Potential is measured at between 3 and 13 depths at 10 sites. Matric potential is measured with MPS1 probes manufactured by Decagon.

Creator/Author

Lin, Henry

CZOs

Shale Hills

Contact

Dr. Henry Lin, Crop and Soil Science, The Pennsylvania State University, 444 Agricultural Sciences and Industries Building, University Park, PA. 814-865-6726 henry.lin@psu.edu

Subtitle

Level 1 - Quality Controlled Data

SUBJECTS

Disciplines

Soil Science / Pedology

Topics

Hydropedologic Properties|Matric Potential

Subtopic

MPS Probes

Keywords

soil|water|hydrology|hydropedology|soil science|matric potential

Variables

Julian Day|Decimal Time of Day|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)|MPS Matric Potential (kPa)

Variables ODM2

Water potential, Matric potential

TEMPORAL

Date Start

2007-01-01

Date End

2014-08-18

SPATIAL

Field Areas

Susquehanna Shale Hills Critical Zone Observatory

Location

Shale Hills

North latitude

40.6655931893

South latitude

40.664180911799995

West longitude

-77.9056734264

East longitude

-77.9037753202

REFERENCE

Citation

The following acknowledgment should accompany any publication or citation of these data: Logistical support and/or data were provided by the NSF-supported Shale Hills Susquehanna Critical Zone Observatory.

Publications of this data

Lin, H.S., Kogelmann, W., Walker, C., and Bruns, M.A. (2006). Soil moisture patterns in a forested catchment: A hydropedological perspective. Geoderma 131:345-368. http://dx.doi.org/10.1016/j.geoderma.2005.03.013

Publications using this data

Graham, C., and Lin, H.S. (2011). Controls and Frequency of Preferential Flow Occurrence: A 175-event Analysis. Vadose Zone Journal 10:816-831 http://dx.doi.org/10.2136/vzj2010.0119

Jin, L., Andrews, D.M., Holmes, G.H., Lin, H., and Brantley, S.L. (2011). Opening the 'Black Box': Water Chemistry Reveals Hydrological Controls on Weathering in the Susquehanna Shale Hills Critical Zone Observatory . Vadose Zone Journal 10:928-942, http://dx.doi.org/10.2136/vzj2010.0133

Lin, H.S., and Zhou, X. (2008). Evidence of Subsurface Preferential Flow Using Soil Hydrologic Monitoring in the Shale Hills Catchment . European Journal of Soil Science 59:34–49. http://dx.doi.org/10.1111/j.1365-2389.2007.00988.x

Lin, H.S. (2006). Temporal stability of soil moisture spatial pattern and subsurface preferential flow pathways in the Shale Hills Catchment. Vadose Zone Journal 5:317-340. http://dx.doi.org/10.2136/vzj2005.0058

Takagi, K. and H.S. Lin. (2011). Temporal Dynamics of Soil Moisture Spatial Variability in the Shale Hills Critical Zone Observatory. Vadose Zone Journal 10:832-842, http://dx.doi.org/10.2136/vzj2010.0134

CZO ID

2606

COMMENTS

Comments

Probe Depths at each site, in cm: Site A4: 5, 36; Site 11: 11, 36, 66; Site 12: 10, 48, 81; Site 15: 14, 20, 41, 55, 71, 91, 94; Site 51: 6, 17, 27, 40, 70, 95, 162; Site 53: 10, 22, 42, 69, 121; Site 55: 8, 14, 41, 86, 90, 111; Site 60: 14, 41; Site 61: 12, 20, 36, 67, 85, 95, 127; Site 74: 7, 12