Heat-Pulse Method for Soil Water Content Measurement: Influence of the Specific Heat of the Soil Solids

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DIVISION S-1—SOIL PHYSICS

Heat-Pulse Method for Soil Water Content Measurement

Influence of the Specific Heat of the Soil Solids

T. Ren^a, T. E. Ochsner^b, R. Horton^*^,b and Z. Ju^c

^a Institute of Geographic Sciences and Natural Resources Research, Chinese Academy of Sciences, Beijing, China 100101
^b Dep. of Agronomy, Iowa State Univ., Ames, IA 50011
^c China Agricultural Univ., Beijing, China 100094

^* Corresponding author (rhorton{at}iastate.edu).

ABSTRACT

TOP
NOTES
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

The heat-pulse method measures soil volumetric water content( ${theta}$ ) based on the linear relationship between soil volumetricheat capacity (C) and ${theta}$ . Previous work suggested that this methodwas more appropriate for determining change of ${theta}$ rather thanits absolute value. In this study, we demonstrate that the heat-pulsemethod can give accurate ${theta}$ estimation when values for the specificheat of the soil solids (c_s) are determined using the heat-pulsemethod. Heat-pulse measurements were performed on packed columnsof three soils with a wide range of bulk density ( ${rho}$ _b) and ${theta}$ . Whenthe commonly used c_s value (0.725 kJ kg^-3 K^-1) was used, theheat-pulse method overestimated ${theta}$ by 0.052 m³ m^-3 on average.However, when c_s values determined from heat-pulse measurementson oven-dried soil were used, the heat-pulse method providedaccurate ${theta}$ results (-0.006 m³ m^-3 average error). Using soil-specific,heat-pulse determined c_s values also reduced the average rootmean square error (RMSE) in ${theta}$ for the three soils from 0.061to 0.039 m³ m^-3.

Abbreviations: C, soil volumetric heat capacity • c_s, specific heat of soil solids • RMSE, root mean square error • ${theta}$ , soil volumetric water content • ${rho}$ _b, bulk density • ${rho}$ _w, density of water

INTRODUCTION

TOP
NOTES
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

RECENTLY, the heat-pulse method has been used to measure ${theta}$ . Laboratoryand field studies (Bristow et al., 1993; Tarara and Ham, 1997;Song et al., 1998) indicated that the method offers the benefitsof low cost, less soil disturbance, and automatic and frequentin situ readings. The small sample volume also makes this methodsuitable for detailed measurements of the spatial variabilityof ${theta}$ .

Several factors, including probe spacing (Bristow et al., 1993),soil bulk density (Tarara and Ham, 1997), and soil mineralogy(Bristow, 1998) may affect the accuracy of ${theta}$ measurement usingthe heat-pulse method. Bristow et al. (1993) and Tarara and Ham (1997)concluded that this method could provide accuratemeasurements of changes in ${theta}$ . In this note, we demonstrate thatthe accuracy of ${theta}$ measurement with the heat-pulse method is improvedby using soil-specific values for c_s.

THEORY

TOP
NOTES
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

The measurement of C with the heat-pulse method relies on thetheory of radial heat conduction of a short-duration heat pulseaway from an infinite line source. In an infinite medium, thetemperature change as a function of time at a radial distancefrom the heat-pulse source is given by (de Vries, 1952; Kluitenberg et al., 1993),

[1]
where ${Delta}$ T is the temperaturechange (°C), t is time (s), t₀ is the duration of the heatpulse (s), r is the radial distance (m), q is the rate of heating(W m^-1), ${alpha}$ is the soil thermal diffusivity (m² s^-1), C is thevolumetric heat capacity (J m^-3 K^-1), and -Ei(-x) is the exponentialintegral (Abramowitz and Stegun, 1972). Once the ${Delta}$ T(r, t) dataare obtained from the probe, Eq. [1] is used to determine ${alpha}$ andC by means of nonlinear regression (Bristow et al., 1995; Welch et al., 1996).

The volumetric heat capacity can also be estimated by summingthe contributions of the individual components (Campbell et al., 1991):

[2]
where ${rho}$ _w is the densityof water (Mg m^-3), c_w is the specific heat capacity of water(kJ kg^-1 K^-1), and ${rho}$ _b is soil bulk density (Mg m^-3). The contributionof soil air to C is ignored because the density and specificheat of air are very small relative to the other terms.

Rearranging Eq. [2] yields a simple expression for determining ${theta}$ from the heat-pulse method (Campbell et al., 1991):

[3]

MATERIALS AND METHODS

TOP
NOTES
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

The heat-pulse function of a thermo-TDR probe (Ren et al., 1999)was used to measure C. The probe consists of three parallelstainless steel needles, each enclosing a line heater and athermocouple. The rods are 1.3 mm in diameter and 40 mm in lengthand spaced 6 mm apart. The heaters are made from 75-µmdiam. enameled Evanohm wire (Wilbur B. Driver Co., Newark, NJ),and the thermocouples were chromel constantan. The resistanceof the completed heater is 887.6 ${Omega}$ m^-1. See Ren et al. (1999)for additional details regarding the probe design and construction.

The heater-to-thermocouple spacing was calibrated using agar-immobilizedwater (5 g agar L^-1), taking heat capacity of the water as 4.18MJ m^-3 K^-1 (Campbell et al., 1991). The heat pulse was generatedby applying a DC current to the central heater with a directcurrent supply (Model HY1791-3S, Huaiyin Electronics Equip.Corp., Huaiyin, China) for 15 s. A data logger (Model CR10X,Campbell Scientific, Logan, UT) controlled the heat input, monitoredthe temperatures of the thermocouples every second, and recordedthe voltage drop across a precision resistor that was used todetermine the current applied to the heater. The heater-to-thermocouplespacing was calculated by using a nonlinear regression method(Welch et al., 1996) to fit the temperature-by-time data.

The heat-pulse method was evaluated in the laboratory on threesoils: a sand, a silt loam, and a silty clay loam. Table 1 liststhe major physical characteristics of the three soils. Particle-sizeanalysis was performed using the hydrometer method (Gee and Bauder, 1986)and the soil organic matter was measured usingthe Walkely–Black titration method (Nelson and Sommers, 1982).The soils were air-dried, ground, sieved through a 2-mmscreen, moistened with distilled water, and packed into soilcolumns (5.2-cm i.d. and 6.0 cm in height) with different watercontents and bulk densities. Three columns with different ${rho}$ _bvalues were packed at each value of ${theta}$ . The ${rho}$ _b of the soil columnsranged from 0.95 to 1.45 Mg m^-3 and ${theta}$ varied from air dry tosaturation. All of the columns were tightly covered and placedin a temperature-regulated room (20 ± 1.2°C) for48 h before measurements. After the probe was inserted intoa soil column from the surface, a constant current was thenapplied from the direct current supply to the central heaterfor 15 s to generate the heat pulse. The data logger recordedthe heating power by measuring the voltage drop across the precisionresistor and measured the temperature in the outer rods as afunction of time for 300 s. The soil volumetric heat capacitywas calculated by analyzing the temperature increase versustime data at the sensor needles using a nonlinear curve-fittingtechnique (Welch et al., 1996). In each column, the heat-pulsemeasurements were repeated three times at 60-min intervals.The volumetric heat capacity was taken as the mean of the threereplicate measurements. Finally, gravimetric water contentsof the soils were determined by oven drying the samples at 105°C,and ${rho}$ _b of the soil columns was also determined.

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Table 1. Selected properties of the soils.

To estimate c_s in Eq. [2] and [3], we performed heat-pulse measurementsfor oven-dried samples of all three soils. The c_s values werethen calculated from the relationship C = ${rho}$ _bc_s. Table 2 presentsthe measured results. Particle density was also determined usingthe pycnometer method and was used to calculate the volumetricheat capacity of the soil solids shown in Table 2.

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Table 2. Particle density ( ${rho}$ _s), specific heat (c_s), and volumetric heat capacity ( ${rho}$ _sc_s) of the soil solids. The values are means and standard errors of three replicates.

	RESULTS AND DISCUSSION

TOP NOTES ABSTRACT INTRODUCTION THEORY MATERIALS AND METHODS RESULTS AND DISCUSSION CONCLUSIONS REFERENCES

A survey of the published data indicates a relatively wide rangeof values for c_s (Table 3), from 0.644 kJ kg^-1 K^-1 (Johnston, 1937)to 0.939 kJ kg^-1 K^-1 (Campbell et al., 1991). Bristow (1998)showed that errors of >10% can occur in heat-pulse ${theta}$ measurementwhen inaccurate values of c_s were used in Eq. [3]. In this study,we first used 0.725 kJ kg^-1 K^-1 (de Vries, 1963) for c_s andcalculated ${theta}$ from C measurements using Eq. [3]. Figure 1 presentsthe heat-pulse results in comparison with the values determinedgravimetrically. Good linear relationships exist between thedata of the heat-pulse method and the gravimetric method. However,regardless of soil texture, ${theta}$ , and ${rho}$ _b, the heat-pulse method systematicallyoverestimated ${theta}$ . On average, Eq. [3] overestimated ${theta}$ by 0.067,0.040, and 0.050 m³ m^-3 for the sand, the silt loam, and thesilty clay loam, respectively. Some of the scatter of the dataat ${theta}$ > 0.2 m³ m^-3 was caused by the spatial variation of ${rho}$ _b withinthe columns, since we experienced difficulties in packing thesoil columns uniformly at higher water contents.

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Table 3. Literature values of specific heat of soil solids (c_s).

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Fig. 1. Heat-pulse water content, ${theta}$ , vs gravimetrically determined ${theta}$ . The parameter of specific heat of soil solids, c_s, was 0.725 kJ kg^-1 K^-1. The solid lines are the 1:1 lines.

We then used the c_s values determined from the heat-pulse measurementson the oven-dried soils to estimate ${theta}$ using Eq. [3]. The heat-pulseestimated c_s values were 0.881, 0.913, and 0.973 kJ kg^-1 K^-1for the sand, silty loam, and silty clay loam (Table 2). Thesevalues are respectively 21.5, 25.9, and 34.2% higher than thecommonly used value of 0.725 kJ kg^-1 K^-1 (de Vries, 1963). Theresults calculated using these soil specific c_s values agreedwell with the gravimetrically measured values, and the datawere randomly distributed along the 1:1 line (Fig. 2) . Onaverage, Eq. [3] overestimated ${theta}$ by 0.02 m³ m^-3 for the sandand underestimated ${theta}$ by 0.014 and 0.025 m³ m^-3 for the silt loamand the silty clay loam, respectively. For each soil the biasof the ${theta}$ measurement was reduced by using the c_s values determinedfrom the heat-pulse measurements on oven-dried soil.

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Fig. 2. Heat-pulse water content, ${theta}$ , vs gravimetrically determined ${theta}$ . The heat-pulse measured specific heat of soil solids, c_s, for each soil was used. The solid lines are the 1:1 lines.

Using the soil-specific c_s values also led to decreases in theroot mean square error (RMSE) of the heat-pulse ${theta}$ measurementsfor each soil. The RMSE decreased from 0.073 to 0.041 m³ m^-3for the sand, from 0.046 to 0.029 m³ m^-3 for the silt loam,and from 0.062 to 0.048 m³ m^-3 for the silty clay loam. We suspectthat non-uniformities of ${rho}$ _b and ${theta}$ within the packed columns causedthese RMSE values to be larger than they would have been ifthe columns had been perfectly uniform. If so, then the realprecision of the heat-pulse method is likely better than thatindicated by these RMSE values.

Previous investigators (Bristow et al., 1993; Tarara and Ham, 1997)concluded that the heat-pulse method could provide accuratemeasurements of changes in ${theta}$ . Ours results showed that the heat-pulsemethod is also able to provide accurate absolute ${theta}$ for soilswith a range of textures and ${rho}$ _b, provided appropriate c_s valuesare used. For the three soils used in this study, the measuredc_s values are greater than the commonly employed value, butthey are still in the range of literature values (Table 3).

CONCLUSIONS

TOP
NOTES
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

We demonstrate that using an inappropriate c_s value leads toerrors in heat-pulse measured ${theta}$ . In this study, using the c_svalue (0.725 kJ kg^-3 K^-1) from de Vries (1963) resulted in overestimationof ${theta}$ by 0.040 to 0.067 m³ m^-3. We also illustrated that usingc_s values determined from heat-pulse measurements on oven-driedsoil samples improves the accuracy of the heat-pulse ${theta}$ measurements.Again, the focus of this study is on obtaining more accurate ${theta}$ measurements by the heat-pulse technique. Independent measurementsof c_s would be required to determine if the c_s values determinedby the heat-pulse method are themselves accurate.

NOTES

TOP
NOTES
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Supported by the Natural Science Foundation of Hebei (No. 300309).Journal Paper No. J-19760 of the Iowa Agriculture and Home EconomicsExperiment Station, Ames, IA, Project No. 3287. Supported bythe Agronomy Department Endowment Funds, Hatch Act, and theState of Iowa.

Received for publication March 7, 2002.

REFERENCES

TOP
NOTES
ABSTRACT
INTRODUCTION
THEORY
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
REFERENCES

Abramowitz, M., and Stegun. I., 1972. Handbook of Mathematical Functions. Dover Publications, New York.

Bristow, K.L. 1998. Measurement of thermal properties and water content of unsaturated sandy soil using dual-probe heat-pulse probes. Agric. For. Meteorol. 89:75–84.

Bristow, K.L., G.S. Campbell, and K. Calissendorff. 1993. Test of a heat-pulse probe for measuring changes in soil water content. Soil Sci. Soc. Am. J. 57:930–934.[Abstract/Free Full Text]

Bristow, K.L., J.R. Bilskie, G.J. Kluitenberg, and R. Horton. 1995. Comparison of techniques for extracting soil thermal properties from dual-probe heat-pulse data. Soil Sci. 160:1–7.

Campbell, G.S. 1985. Soil physics with BASIC. Elsevier Science Publishers B.V., Amsterdam, Netherlands.

Campbell, G.S., C. Calissendorff, and J.H. Williams. 1991. Probe for measuring soil specific heat using a heat-pulse method. Soil Sci. Soc. Am. J. 55:291–293.[Abstract/Free Full Text]

de Vries, D.A. 1952. A nonstationary method for determining thermal conductivity of soil in situ. Soil Sci. 73:83–89.

de Vries, D.A. 1963. Thermal properties of soils. p. 210–235. In W.R. van Wijk (ed.) Physics of plant environment. North-Holland Publ. Co., Amsterdam, Netherlands.

Gee, G.W., and J.W. Bauder. 1986. Particle-size analysis. p. 383–411. In A. Klute (ed.) Methods of soil analysis. Part 1. 2nd ed. ASA and SSSA, Madison, WI.

Hanks, R.J., and G.L. Ashcroft. 1986. Applied soil physics. Springer-Verlag, Berlin, Germany.

Hillel, D. 1982. Introduction to soil physics. Academic Press, San Diego, CA.

Johnston, C.N. 1937. Heat conductivity of soil governs heat losses from heated oil lines. Pet. Eng. 9:41.

Kluitenberg, G.J., J.M. Ham, and K.L. Bristow. 1993. Error analysis of the heat pulse method for measuring soil volumetric heat capacity. Soil Sci. Soc. Am. J. 57:1444–1451.[Abstract/Free Full Text]

Nelson, D.W., and L.E. Sommers. 1982. Total carbon, organic carbon, and organic matter. p. 539–579. In A.L. Page (ed.). Methods of soil analysis. Part 2. 2nd ed. ASA and SSSA, Madison, WI.

Ochsner, T.E., R. Horton, and T. Ren. 2001. A new perspective on soil thermal properties. Soil Sci. Soc. Am. J. 65:1641–1647.[Abstract/Free Full Text]

Ren, T., K. Noborio, and R. Horton. 1999. Measuring soil water content, electrical conductivity and thermal properties with a thermal time domain-reflectometry probe. Soil Sci. Soc. Am. J. 63:450–457.[Abstract/Free Full Text]

Song, Y., J.M. Ham, M.B. Kirkham, and G.J. Kluitenberg. 1998. Measuring soil water content under turfgrass using the dual-probe heat-pulse technique. J. Am. Soc. Hort. Sci. 123:937–941.[Abstract/Free Full Text]

Tarara, J.M., and J.M. Ham. 1997. Measuring soil water content in the laboratory and field with dual-probe heat-capacity sensors. Agron. J. 89:535–542.[Abstract/Free Full Text]

Welch, S.M., G.J. Kluitenberg, and K.L. Bristow. 1996. Rapid numerical estimation of soil thermal properties for a broad class of heat-pulse emitter geometries. Meas. Sci. Technol. 7:932–938.[ISI]

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