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Enabling better global research outcomes in soil, plant & environmental monitoring.

Decagon 5TE VWC, Temp + EC

The 5TE lets you monitor bulk electrical conductivity (EC), in addition to volumetric water content (VWC) and soil temperature.

Decagon's full-featured soil moisture sensor. Measures volumetric water content, temperature, and electrical conductivity in soil. This three-pronged, 5 cm long sensor is for use in soil only. High frequency oscillation and patented signal filtering deliver excellent accuracy with minimal textural effects. Serial or SDI-12 communication options come standard with each 5TE, giving lots of options for integrating into systems manufactured by other companies.

The 5TE makes all three measurements (volumetric water content, temperature, and EC) independently. Like all ECH2O sensors, the 5TE determines volumetric water content (VWC) by measuring the dielectric constant of the media using capacitance/frequency domain technology. The sensor uses a 70 MHz frequency, which minimises salinity and textural effects, making the 5TE accurate in most soils. The 5TE measures temperature with an onboard thermistor, and electrical conductivity using a stainless steel electrode array. VWC in mineral soils is calculated using the Topp equation; other calibrations are provided on request. Temperature and electrical conductivity are factory calibrated for all soil types.

 5TE Soil Moisture Sensor Features
  • For measuring volumetric water content, dielectric permittivity, temperature, electrical conductivity
  • Data Logging Compatibility with Em50, Em50R, Em50G, ProCheck, SDI-12 capable
  • Measurement Range 0 to 100% VWC -40 to 50°C 0 to 23 dS/m
5TE SOIL SENSOR
RANGE VWC: 0 – 100%
EC (bulk) 0-23 dS/m (bulk)
TEMPERATURE -40°C to 50°C
RESOLUTION VWC: 0.08% from 0 to 50% VWC
POWER 3-16 VDC
MEASUREMENT TIME 10 ms
OUTPUT Digital 12-bit
OPERATING TEMPERATURE -40°C to 50°C
CONNECTOR TYPES 3.5 mm “stereo” plug or stripped and tinned lead wires.
CABLE LENGTH 5 metres
DIMENSIONS 14.5 cm x 3.3 cm x 0.7 cm
DATALOGGER COMPATIBILITY Em50 Series

SENSOR COMPARISON TABLE

ANALOGUE SENSORS DIGITAL SENSORS
SENSOR EC-5 10HS 5TM 5TE GS3 MPS-2
MEASURES volumetric water content, dielectric permittivity volumetric water content, dielectric permittivity volumetric water content, dielectric permittivity, temperature volumetric water content, dielectric permittivity, temperature, electrical conductivity volumetric water content, dielectric permittivity, temperature, electrical conductivity water potential,
temperature
VOLUME OF INFLUENCE 0.3 L 1 L 0.3 L 0.3 L 0.3 L N/A
DATA LOGGER COMPATIBILITY Em5b, Em50, Em50R, Em50G, ProCheck, ECH2O Check, Campbell Scientific* Em5b, Em50, Em50R, Em50G, ProCheck, ECH2O Check, Campbell Scientific*

Em50, Em50R, Em50G, ProCheck, Campbell Scientific*, SDI-12 capable

Em50, Em50R, Em50G, ProCheck, SDI-12 capable

Em50, Em50R, Em50G, ProCheck, SDI-12 capable

Em50, Em50R, Em50G, ProCheck, SDI-12 capable

MEASUREMENT RANGE 0 to 100% VWC 0 to 57% VWC

0 to 100% VWC

-40 to 50°C

0 to 100% VWC

-40 to 50°C

0 to 23 dS/m

0 to 100% VWC

-40 to 80°C

0 to 23 dS/m

-10 to -500 kPa (pF 2 – pF 3.71)

-40 to 50°C

BEST IF VWC is all that you need.You’re establishing a large sensor network. You want a large volume of influence.

You have high temperature variability in your soils.

You are monitoring shallow or desert soils where data must be corrected for temperature effects.

You need to monitor soil temperature for biological activities.

You want to use SDI-12.

You are managing salts in your system.You want to use SDI-12.

You are measuring water content of soilless substrates.

You need high accuracy EC.

You need to measure at high temperatures

You want to compare soil moisture at different research sites.

You want to determine water available for plant growth.

You are monitoring deficit irrigation.

You want to measure water potential.

BUT NOT IF You cannot apply a regulated voltage (only applies to non-Decagon data loggers). You are measuring in nursery pots.You are installing in rocky soil. N/A You want to monitor soiless substrates or potting soils. You are doing downhole installations. You want to monitor soils at or near saturation.

ABOUT THE 5TE SOIL SENSOR

In water-limited areas, salt management is a serious concern. In these areas, monitoring salt levels can be as important as monitoring soil moisture. The 5TE allows you to measure salt levels through bulk electrical conductivity.

EC measurements require good contact between the stainless steel electrodes on the sensor, and the soil. Because of large air spaces in potting soil and soilless media, the 5TE cannot be used accurately in potting soils or soilless substrates. However, the new GS3 Soil Moisture, Temperature, and EC sensor is designed specifically for use in these media.

The 5TE’s small size makes it easy to install–perfect in field installations. This robust probe should be pushed directly into undisturbed soil to ensure good accuracy.

Volumetric Water Content

The 5TE sensor uses an electromagnetic field to measure the dielectric permittivity of the surrounding medium. The sensor supplies a 70 MHz oscillating wave to the sensor prongs that charges according to the dielectric of the material. The stored charge is proportional to soil dielectric and soil volumetric water content. The 5TE microprocessor measures the charge and outputs a value of dielectric permittivity from the sensor.

Temperature

The 5TE uses a surface-mounted thermistor to take temperature readings. The thermistor is underneath the sensor overmold, next to one of the prongs, and it reads the temperature of the prong sur- face. The 5TE outputs temperature in C unless otherwise stated in DataTrac 3 or ECH2O Utility preferences file.

It is important to note that if the black polyurethane overmold of the sensor is in direct sunshine, the temperature measurement may read high. We do not recommend that the sensor be installed with the overmold in the sun.

Electrical Conductivity

Electrical conductivity (EC) is the ability of a substance to conduct electricity and can be used to infer the amount of polar molecules that are in solution. Measure EC by applying an alternating electrical current to two electrodes and measuring the resistance between them. Conductivity is then derived by multiplying the inverse of the resistance (conductance) by the cell constant (the ratio of the distance between the electrodes to their area).

The 5TE uses a two-sensor array to measure the EC. The array is located on the screws of two of the 5TE prongs.

Note: Small amounts of oil from skin contact with the screws will cause significant inaccuracy in the EC measurement.

The 5TE uses a two electrode array to measure the bulk EC of the surrounding medium. Decagon factory calibrates the bulk EC measurement to be accurate within 10% from 0 to 7 dS/m. This range is adequate for most eld, greenhouse and nursery applications. However, some special applications in salt affected soils may require measurements with bulk EC greater than the specified range. The 5TE can measure up to 23.1 dS/m bulk EC, but requires user calibration above 7 dS/m. Additionally, EC measurements above 7 dS/m are sensitive to contamination of the electrodes by skin oils, etc.

ECH2O Soil Moisture Sensor References
Bogena, H.R., Huisman, J.A., Oberdörster, C. and Vereecken, H. 2007, ‘Evaluation of a Low Cost Soil Water Content Sensor for Wireless Network Applications’, Journal of Hydrology, vol. 344, pp. 32-42.

Borhan, M.S., Parsons, L.R. and Bandaranayake, W. 2004, Evaluation of a Low Cost Capacitance ECH2O Soil Moisture Sensor for Citrus in a Sandy Soil, 25th International Irrigation Show, Tampa, Florida. 14-16 November 2004 pp. 447-458.

Campbell, C.S., Application Note: Response of ECH2O Soil Moisture Sensor to Temperature Variation, Decagon Devices: 1-6.

Campbell, C.S., Application Note: Response of the ECH2O Soil Moisture Probe to Variation in Soil Water Content, Soil Type, and Solution Electrical Conductivity, Decagon Devices: 1-5.

Christensen, N.B. 2005, Irrigation Management using Soil Moisture Monitors, Western Nutrient Management Conference, Salt Lake City, UT, USA. pp. 46-53.

Czarnomski, N.M., Moore, G.W., Pypker, T.G., Licata, J. and Bond, B.J. 2005, ‘Precision and Accuracy of Three Alternative Instruments for Measuring Soil Water Content in Two Forest Soils of the Pacific Northwest’, Canadian Journal of Forest Research, vol. 35, pp. 1867-1876.

Decagon Inc., Application Note: ECH2O Dielectric Probes vs Time Domain Reflectometers (TDR), Decagon Inc.: 3 pp.

Kizito, F., Campbell, C.G., Cobos, D.R., Teare, B.L., Carter, B. and Hopmans, J.W. 2008, ‘Frequency, Electrical Conductivity and Temperature Analysis of a Low-cost Capacitance Soil Moisture Sensor’, Journal of Hydrology, vol. 352, pp. 367-378.

Laurent, J.P., Olivier, F. and Goure, J.P. 2005, Monitoring Moisture Content in Municipal Solid Waste: Results of a Preliminary Test under Laboratory Conditions, International Workshop on Hydro-Physico-Mechanics of Landfills, Grenoble Univerisity. 21-22 March.

Luedeling, E., Nagieb, M., Wichern, F., Brandt, M., Deurer, M. and Buerkert, A. 2005, ‘Drainage, Salt Leaching and Physico-chemical Properties of Irrigated Man-made Terrace Soils in a Mountain Oasis of Northern Oman’, Geoderma, vol. 125, pp. 273-285.

Mattson, E.D., Baker, K.E., Palmer, C.D., Breckenridge, C.R., Svoboda, J.M. and Smith, R.W. 2006, ‘A Flexible Water Content Probe for Unsaturated Soil Column Experiments’, Vadose Zone Journal, vol. 5, pp. 805-808.

McMichael, B. and Lascano, R.J. 2003, ‘Laboratory Evaluation of a Commercial Dielectric Soil Water Sensor’, Vadose Zone Journal, vol. 3, pp. 650-654.

Sakaki, T., Limsuwat, A., Smits, K.M. and Illangasekare, T.H. 2008, ‘Empirical Two-point α-mixing Model for Calibrating the ECH2O EC-5 Soil Moisture Sensor in Sands’, Water Resources Research, vol. 44, pp.

Smith, P. and Christie, J. 2006, Practical Irrigation Scheduling of Pastures under Centre Pivot Irrigators, Irrigation Australia 2006 Conference, Brisbane.