Embedded NMR Sensor to Monitor Compressive Strength Development and Pore Size Distribution in Hydrating Concrete

In cement-based materials porosity plays an important role in determining their mechanical and transport properties. This paper describes an improved low–cost embeddable miniature NMR sensor capable of non-destructively measuring evaporable water loss and porosity refinement in low and high water-to-cement ratio cement-based materials. The sensor consists of two NdFeB magnets having their North and South poles facing each other, separated by 7 mm to allow space for a Faraday cage containing a Teflon tube and an ellipsoidal RF coil. To account for magnetic field changes due to temperature variations, and/or the presence of steel rebars, or frequency variation due to sample impedance, an external tuning circuit was employed. The sensor performance was evaluated by analyzing the transverse magnetization decay obtained with a CPMG measurement from different materials, such as a polymer phantom, fresh white and grey cement pastes with different w/c ratios and concrete with low (0.30) and high (0.6) w/c ratios. The results indicated that the sensor is capable of detecting changes in water content in fresh cement pastes and porosity refinement caused by cement hydration in hardened materials, even if they are prepared with a low w/c ratio (w/c = 0.30). The short lifetime component of the transverse relaxation rate is directly proportional to the compressive strength of concrete determined by destructive testing. The r2 (0.97) from the linear relationship observed is similar to that obtained using T2 data from a commercial Oxford Instruments 12.9 MHz spectrometer.


Introduction
In Portland cement concrete, porosity plays an important role in determining its mechanical and durability properties. Porosity depends on the water-to-cement ratio and the degree of hydration of the cement paste [1]. On exposure to the environment the material undergoes changes that lead to micro-cracking, increasing the permeability of concrete to water, which is a medium for transport of other aggressive species such as chloride ions and CO 2 [1]. Therefore, monitoring the moisture condition and microstructural changes in concrete are important from durability and mechanical strength points of view.
The moisture condition is normally evaluated by using relative humidity sensors that must be installed by drilling into the structural member [2]. Information obtained in this way is of limited use, unless the sorption/desorption isotherm is known for the material to determine the moisture content corresponding to a specific relative humidity. On the other hand, compressive strength of concrete is normally determined by destructive testing of cylinders cast for this purpose or by coring the structure to determine the "in situ" compressive strength. Traditionally, the rebound hammer and the ultrasonic pulse velocity are used to estimate the compressive strength of concrete in the field provided a calibration curve is first determined. There are however several additional factors affecting the measurements such as moisture content, type and amount of aggregates, and the presence and direction of the reinforcing steel [3].
Nuclear magnetic resonance (NMR) is a non-destructive and non-invasive technique that has been used in the laboratory to study cement-based materials [4][5][6]. To extend the possibilities of NMR to study these materials in the field, portable systems such as the NMR MOUSE [7,8] and the NMR MOLE [9] have been developed but the measurements are restricted to a depth of a few millimeters below the surface. Embedded miniature NMR sensors have been used to monitor changes in evaporable water and pore refinement in high water/cement ratio Portland cement mortar [10]. However, use of these sensors in materials having a low water/cement ratio (low porosity) did not provide useful NMR signal because of low signal intensity.
This paper presents an improved embedded NMR sensor capable of measuring microstructural and evaporable water changes occurring in concrete materials having high and low water/cement ratios, such as those used in the construction industry for ordinary and special applications, respectively.

Sensor Design and Construction
Concrete is essentially a material containing hydrated Portland cement paste and aggregates ( Figure 1). Since hydration of the cement paste is the process properties of concrete, it is the part of the material that the sensor must be capable of monitoring. The sensor design considered the fact that aggregates, especially normal density coa (>4.75 mm), may drastically reduce the amplitude of the NMR signal if they are located within the sensitive region of the sensor. These aggregates have low water absorption (less than 2%). Even if considering lightweight aggregates with much higher water absorpt would not be of interest since it does not reflect changes occurring in the cement paste caused by hydration. Therefore, the sensor has to prevent aggregate particles from entering into its sensitive region. Several magnet arrangements were explored and the Z magnetic field component along the Y (Figure 2) was measured to select those providing the highest and the most homogeneous magnetic fields [11]. The best arrangement was chosen based on the highest signal to noise ratio (SNR) obtained by measuring the transverse magnetization decay of a polymer phantom

Construction
Concrete is essentially a material containing hydrated Portland cement paste and aggregates ( Figure 1). Since hydration of the cement paste is the process leading to changes in mechanical and transport properties of concrete, it is the part of the material that the sensor must be capable of monitoring. The sensor design considered the fact that aggregates, especially normal density coa mm), may drastically reduce the amplitude of the NMR signal if they are located within the sensitive region of the sensor. These aggregates have low water absorption (less than 2%). Even if considering lightweight aggregates with much higher water absorption, the NMR signal detected would not be of interest since it does not reflect changes occurring in the cement paste caused Piece of hydraulic concrete showing coarse aggregates (A) and mortar ( Mortar is composed of cement paste and fine aggregates (particle size < 4.75 mm) Therefore, the sensor has to prevent aggregate particles from entering into its sensitive region. Several magnet arrangements were explored and the Z magnetic field component along the Y measured to select those providing the highest and the most homogeneous magnetic . The best arrangement was chosen based on the highest signal to noise ratio (SNR) obtained by measuring the transverse magnetization decay of a polymer phantom using the CPMG technique Magnet arrangement for the sensor; (b) Measured Z magnetic field component Concrete is essentially a material containing hydrated Portland cement paste and aggregates ( Figure 1). leading to changes in mechanical and transport properties of concrete, it is the part of the material that the sensor must be capable of monitoring. The sensor design considered the fact that aggregates, especially normal density coarse aggregates mm), may drastically reduce the amplitude of the NMR signal if they are located within the sensitive region of the sensor. These aggregates have low water absorption (less than 2%). Even if ion, the NMR signal detected would not be of interest since it does not reflect changes occurring in the cement paste caused ) and mortar (B).

mm).
Therefore, the sensor has to prevent aggregate particles from entering into its sensitive region. Several magnet arrangements were explored and the Z magnetic field component along the Y-axis measured to select those providing the highest and the most homogeneous magnetic . The best arrangement was chosen based on the highest signal to noise ratio (SNR) obtained using the CPMG technique [12].

Z magnetic field component
The magnet arrangement selected consists of two circular grade 35 NdFeB magnets, measuring 25 mm in diameter and 5 mm in thickness, with opposite poles facing ( Figure 2a). This had an additional advantage of increasing the magnetic field strength and homogeneity that in turn increases sensitivity of the sensor. Figure 2b shows the magnetic field measured at the middle of the distance between the magnets. The measurement was performed by manually displacing a Gaussmeter at 2.5 mm intervals along the Y-axis. For this particular pair of magnets, the magnetic field was 0.38 T and the Larmor frequency for 1 H was 16.18 MHz.
The separation distance between the magnets was 7 mm to allow space for a Faraday cage (Figure 3) made of a phenolic printed circuit board plate, while preventing coarse aggregates from entering into the sensitive region of the sensor. The Faraday cage was used to reduce the influence of external noise on the NMR signal. During preliminary evaluation of the design, it was observed that when the sensor was introduced in the cement paste, there were changes in the tuning frequency and in the impedance of the RF coil. This was due to the influence of external impedance (fresh cement paste) over the total impedance of the RF coil, which hindered external tuning. To reduce this problem, a Teflon tube with ellipsoidal cross section measuring 11 mm in major axis, 5 mm in minor axis and 30 mm in length was used. The tube served also as a mold for the RF coil, which had 22 turns of 20 AWG copper wire. The length of the coil was 23 mm and an inductance of 2.8 µH. The length of the RG58 coaxial cable was 1.17 m (λ/16) with an effective capacitance of 110.8 pF.  Figure 4 shows the response in frequency when the sensor without the Teflon tube is immersed in fresh cement paste. There is a change in both frequency and impedance. However, if the Teflon tube is used (could also be a glass tube) there is only a change in frequency. The effect of coupling in impedance and the change in frequency of the coil when it is embedded in the cement paste depends on the characteristics of the material, such as polarity and the dielectric constant. It is observed that the Teflon tube eliminates the impedance displacement when the sensor is embedded in the cement paste, although it does not avoid changes in frequency. This change in frequency was accommodated using the external tuning circuit described next.  As shown in Figure 5a, the coil design does not include capacitors within the sensor; rather the tuning (16.18 MHz) was performed through a remote tuning circuit ( Figure 5 remote tuning circuit was to refrequency changes due to sample impedance, rebars that influence the static magnetic field, which in turn changes the Larmor frequency. advantage of the external tuning circuit is the possibility of retuning the RF coil embedded, compared to conventional tuning inductance (0.42 µH) in the external tuning circuit is to adjust the resonance frequency of the RF coil. It is connected in parallel to the total inductance (coaxial cable and RF coil), therefore the equivale inductance obtained is lower and the frequency is increased layer of water resistant epoxy resin ( Figure 5c). As shown in Figure 5a, the coil design does not include capacitors within the sensor; rather the performed through a remote tuning circuit ( Figure 5 -tune the RF coil after the sensor is embedded to accommodate frequency changes due to sample impedance, changes in temperature and/or the presence of rebars that influence the static magnetic field, which in turn changes the Larmor frequency. advantage of the external tuning circuit is the possibility of retuning the RF coil compared to conventional tuning-matching circuits. The function of the additional H) in the external tuning circuit is to adjust the resonance frequency of the RF coil. It is connected in parallel to the total inductance (coaxial cable and RF coil), therefore the equivale ower and the frequency is increased [13]. The entire sensor was layer of water resistant epoxy resin ( Figure 5c).
Circuit diagram of the sensor; (b) External tuning circuit (55 mm in length, 25 mm in width, and 20 mm in height); (c) NMR sensor constructed.  Figure 5a, the coil design does not include capacitors within the sensor; rather the performed through a remote tuning circuit ( Figure 5b). The purpose of this after the sensor is embedded to accommodate changes in temperature and/or the presence of steel rebars that influence the static magnetic field, which in turn changes the Larmor frequency. The main advantage of the external tuning circuit is the possibility of retuning the RF coil once the sensor is The function of the additional H) in the external tuning circuit is to adjust the resonance frequency of the RF coil. It is connected in parallel to the total inductance (coaxial cable and RF coil), therefore the equivalent The entire sensor was covered with a (55 mm in length, c) X

NMR Measuring Technique
The CPMG technique [12] was used to obtain the transverse magnetization decay of protons from a polymer phantom and from evaporable water in fresh and hardened cement paste and concrete. Table 1 provides the CPMG parameters used to determine the transverse magnetization decay of a polymer phantom, which possesses a bi-exponential decay with a long lifetime component of 20 ms and a short lifetime component of 4.5 ms. The SNR was obtained as the ratio of the average amplitude of the first three points of the CPMG envelope divided by the standard deviation of the last ten points where the signal has completely decayed. The coefficient of variation of the CPMG amplitude and the T 2 decay constant obtained by performing seven measurements with the same sensor and the same polymer phantom under temperature controlled conditions was less than 1%.  Table 2 provides the CPMG parameters used for the measurements in cement pastes and concretes. These parameters were used according to the type, w/c ratio and age of the samples, so that the changes in microstructure produced by cement hydration and reflected in the relaxation times could be followed. For instance, the minimum number of scans, the maximum echo time, the maximum number of echoes, and the maximum repetition time, were used at early ages, when the T 2 relaxation times were on the order of few milliseconds. Ordinary and white Portland cement were used to prepare the cement pastes. White cement was used because of its lower iron content compared to grey cement (Table 3). Tap water was used to prepare the cement pastes. Seven cement pastes were prepared at w/c ratios by weight of 0.30, 0.35, 0.40, 0.45, 0.50, 0.55 and 0.60. Immediately the sensor was immersed in the fresh cement paste and the CPMG technique was used to obtain the transverse magnetization decay, which was in all cases best fit to a mono-exponential decay function to determine the NMR signal amplitude and the T 2 decay constant.
Samples from the fresh cement pastes were only taken from those having w/c ratios of 0.30, 0.40, 0.50 and 0.60. They were introduced in small plastic tubes with appropriate size to fit into the sensor and sealed to avoid ingress or loss of moisture. The transverse magnetization decay was determined in the hardened state at 1, 3, 7, 14, and 28 days of age. It was verified that the plastic tubes did not provide any NMR signal.

NMR Sensors Embedded in Hydraulic Concrete Cylinders
Four sensors were built to monitor changes in the transverse magnetization decay during hydration of cement in concrete. Two mixes with w/c ratios of 0.30 and 0.60 were prepared with the proportions given in Table 4. The materials used were river sand having a fineness modulus of 2.9, specific gravity of 2.65, and absorption of 1.73%. The gravel had a maximum size of ¾ inch, specific gravity of 2.68, and absorption of 1.51%. The chemical composition of the fine aggregate used is given in Table 1. Tap water was used to prepare the concrete mixtures. From each concrete mixture two cylinders measuring 150 mm in diameter and 150 mm in height were cast and immediately one sensor was embedded to a half of the total height of the cylinder (Figure 6a). Before embedding the sensors in the concrete specimens, the SNR for each sensor was determined by obtaining the NMR signal from a polymer phantom. Seven specimens in triplicate measuring 100 mm in diameter and 200 mm in height were cast for compressive strength testing at 1, 3, 7, 14, 21, 28 and 56 days of age (a total of 21 cylinders). After 24 h, all the specimens were removed from the molds and stored in a moist room at 22 ± 3 °C until testing. At this time, the cylinders with the embedded sensors ( Figure 6b) were non-destructively tested using a portable Magritek Kea 2 spectrometer to obtain the transverse magnetization decay using the CPMG technique.
After each cylinder was destructively tested under compression, a sample from the center was taken for NMR measurements in an Oxford Instruments Maran DRX-HF 12/50 spectrometer (Oxford Instruments, Abingdon, UK) at 12.9 MHz, to compare the results obtained with the embedded sensors. Figure 6. (a) Sensor embedded in fresh concrete during external vibration of the material, which made it easy to introduce cement paste and small fine aggregate particles into the sensor; (b) Sensor in a hardened concrete cylinder; (c) After breaking a hardened specimen to extract the sensor, it was observed that only cement paste and some fine aggregate particles (size < 1 mm) had penetrated into the sensor and filled the measurement volume.

Influence of Temperature and Reinforcing Steel Bars on Sensor Resonant Frequency
To measure the effects of temperature on sensor resonant frequency, it was located in a controlled environment at 17.5, 20 and 24 °C. In order to determine the influence of a steel rebar, the sensor was located at 0, 14 and 28 mm (using pieces of 14 mm thick plywood) from a 25.4 mm diameter steel rebar. The thickness of the plywood used to separate the sensor from the steel rebar was 14 mm. In both cases, the magnetic field changes were measured with a gaussmeter and the corresponding resonant frequency determined. Figure 7a presents the relationship between the NMR signal and the water weight of fresh grey and white cement pastes. As expected, there is a linear relationship between the signal amplitude and the amount of water relationship between T 2 and the w/c ratio for the fresh cement pastes. It is observed that T with increasing w/c ratio. This is in agreement with the fact that the w/c ratio is related to the distan between cement particles [14]. That is, in high w/c ratio pastes the cement particles are more separated than in low w/c ratio pastes. For the same w/c ratio, amount of paramagnetic impurities reflected in shorter T 2 values with respect to white cement. approaches (signal amplitude and T in fresh cement paste or concrete.

Hardened Cement Pastes
Increasing hydration times cause the microstructure to change as long as there is enough water to support the hydration process [1] types of cement pastes at different w/c ratios. It is observed that the short and long components, corresponding to gel and capillary pores due to pore refinement caused by cement hydration. In Figure 8d it is interesting to note an increase in the long lifetime component only for the cement paste with w/c ratio of 0.30. Since this sample was sealed, there was no external water source that could help mitigat low w/c ratio materials [16] and micro ratio of the porosity. Figure 7a presents the relationship between the NMR signal and the water-to weight of fresh grey and white cement pastes. As expected, there is a linear relationship between the signal amplitude and the amount of water present in the cement pastes. and the w/c ratio for the fresh cement pastes. It is observed that T with increasing w/c ratio. This is in agreement with the fact that the w/c ratio is related to the distan . That is, in high w/c ratio pastes the cement particles are more separated For the same w/c ratio, an enhanced relaxation produced by the amount of paramagnetic impurities (mainly iron) found in ordinary Portland cement with respect to white cement. From these results, it is seen that both approaches (signal amplitude and T 2 values) would make it possible to determine the actual w/c ratio Relationship between w/c ratio and NMR signal amplitude 2 relaxation times and w/c ratio of cement pastes. ordinary Portland cement, ○ white Portland cement.

(b)
Increasing hydration times cause the microstructure to change as long as there is enough water to [1]. Figure 8 shows the T 2 variation with hydration time for the two different w/c ratios. It is observed that the short and long components, corresponding to gel and capillary pores [15], respectively, decrease with increasing age inement caused by cement hydration. In Figure 8d it is interesting to note an increase in component only for the cement paste with w/c ratio of 0.30. Since this sample was sealed, there was no external water source that could help mitigate the autogenous shrinkage occurring in d micro-cracking was developed, thus increasing the surface to-cement ratio (w/c) by weight of fresh grey and white cement pastes. As expected, there is a linear relationship between sent in the cement pastes. Figure 7b shows the and the w/c ratio for the fresh cement pastes. It is observed that T 2 increases with increasing w/c ratio. This is in agreement with the fact that the w/c ratio is related to the distance . That is, in high w/c ratio pastes the cement particles are more separated enhanced relaxation produced by the higher in ordinary Portland cement (Table 1), is From these results, it is seen that both ) would make it possible to determine the actual w/c ratio of cement pastes; and w/c ratio of cement pastes. The symbols Increasing hydration times cause the microstructure to change as long as there is enough water to variation with hydration time for the two different w/c ratios. It is observed that the short and long lifetime , respectively, decrease with increasing age inement caused by cement hydration. In Figure 8d it is interesting to note an increase in component only for the cement paste with w/c ratio of 0.30. Since this sample was e the autogenous shrinkage occurring in , thus increasing the surface-to-volume

Performance of the Sensors in
The normalized transverse magnetization decay at 1, 7 and 28 days of age obtained with the sensors embedded in concrete are shown in Figure 9. concrete with a w/c ratio = 0.30 is observed the higher w/c ratio concrete. in Hardened Hydraulic Concrete transverse magnetization decay at 1, 7 and 28 days of age obtained with the sensors embedded in concrete are shown in Figure 9. A more rapid decay in the specimen prepared with is observed. This is expected, since the pores are finer with respect to ransverse magnetization decay measured with the embedded w/c ratio = 0.30 and (b) w/c = 0.60.
transverse magnetization decay at 1, 7 and 28 days of age obtained with the sensors in the specimen prepared with are finer with respect to ransverse magnetization decay measured with the embedded Comparing the SNR of the signal obtained when using the new design in concrete with w/c ratio of 0.60 (SNR = 101 for 8192 scans) to the one reported in reference [10], which was mortar with w/c ratio of 0.60 (SNR= 27.3 for 8192 scans), there is an improvement factor of about 4. This increase in sensitivity was a result of a higher magnetic field (0.38 Tesla), homogeneity and larger sensitive volume due to the nature of the magnet arrangement with respect to the unilateral design (0.24 Tesla). Figure 10 shows the Inverse Laplace Transformation of the transverse magnetization decay data [17] shown in Figure 9. As expected, the T 2 distributions indicate that a finer porosity is obtained in the concrete with w/c ratio of 0.30 compared to the concrete with w/c ratio of 0.60 (lower T 2 values in concrete with w/c of 0.30). On the other hand, in concrete with w/c ratio of 0.30, it is only possible to resolve one peak due to the quality of the NMR signal obtained. However, in the concrete with w/c ratio of 0.60, the signal obtained was of better quality and the ILT resolves the two types of pores known in cement-based materials: capillary and gel pores [1]. The size of the gel pores in a hydrating cement paste are in the order 1 to 3 nm, whereas the size of the capillary pores depends on the w/c ratio and the degree of hydration. The size of capillary pores are in the order of 10 to 200 nm for a hydrated cement paste having a w/c ratio of 0.60, and from 10 to 90 nm for a paste with a w/c ratio of 0.30 [1]. The materials used in the present study would have gel and capillary pores sizes similar to those mentioned before.
The NMR relaxation times are sensitive to the pore structure of materials and decrease as the pore size also decreases. These times vary widely for chemically bound hydrogen, hydrogen adsorbed on the surfaces, and hydrogen in water confined in small pores. It is known that the transverse relaxation rate 1/T 2 is proportional to the surface to volume ratio (S/V) of the pore system, as expressed by Equation (1) [18]: where ρ = T 2 surface relaxivity (T 2 relaxing strength of the pore surfaces), varies with the chemical composition of the pore surface. It is a common practice in magnetic resonance to use T 2 as a proxy for pore size and not to convert the data to actual pore size. Figure 11 shows the transverse relaxation rate (1/T 2 ) versus compressive Sensors 2013, 13 strength of concrete cylinders with w/c = 0.30. The bi-exponential decay, therefore short and long is observed that the highest correlation is obtained with the short poor correlation observed with the long be affected by internal micro-cracking caused by s materials with low w/c ratio [16,18 (a) Figure 12 shows the results obtained for the relationship between the the compressive strength of concrete with w/c ratio = 0.60. In this case, both components (short and long lifetime) are highly correlated to mechanical strength. The highest r lifetime component (r 2 > 0.97). The effects of negligible [19], therefore micro-cracking should not have any the long lifetime component observed has information only from capillary porosi   Figure 13. The r Because the samples used small pieces taken from destructive testing, extensive cracking was evident by visual examination. This condition affected the long T high w/c ratio had a very low r 2 . Figure 13. Transverse relaxation rate obtained with the Oxford Instruments Maran DRX-HF 12/50 system versus compressive w/c = 0.60, ○ Concrete w/c = Table 5 shows the frequency variation a steel rebar. Table 5. Effect of ambient temperature and distance to a steel rebar on the frequency of the sensor Temperature (

Distance (mm)
It is observed that the frequency decreases with increasing temperature while the increases with reduced distance of the sensor to the steel rebar. These changes in frequency can be easily accommodated with the external tuning circuit. Based on the limited data obtained related to the influence of temperature on the sensor's m 15 to 30 °C, which would produce changes in frequency that can be accommodated with the external tuning circuit that has a range of 1 MHz. bars were measured at 14 and 28 mm (one and two times the thickness of the plywood used to separate the steel from the sensor), 28 mm might be the minimum distance because the presence of the steel The correlations obtained from the T 2 measurements undertaken with the Oxford Instruments HF 12/50 are shown in Figure 13. The r 2 are similar to those obtained with the sensors. Because the samples used small pieces taken from destructive testing, extensive cracking was evident visual examination. This condition affected the long T 2 and the correlation in concrete with low and It is observed that the frequency decreases with increasing temperature while the increases with reduced distance of the sensor to the steel rebar. These changes in frequency can be easily accommodated with the external tuning circuit. Based on the limited data obtained related to the influence of temperature on the sensor's magnetic field, a reasonable range of variation could be from C, which would produce changes in frequency that can be accommodated with the external tuning circuit that has a range of 1 MHz. Since the effects on frequency caused by the presence of bars were measured at 14 and 28 mm (one and two times the thickness of the plywood used to separate the steel from the sensor), 28 mm might be the minimum distance because the presence of the steel measurements undertaken with the Oxford Instruments are similar to those obtained with the sensors. Because the samples used small pieces taken from destructive testing, extensive cracking was evident and the correlation in concrete with low and relaxation rate obtained with the Oxford Instruments Maran The symbols indicate: • Concrete Sensor Resonant Frequency due to changes in ambient temperature or by the presence of temperature and distance to a steel rebar on the frequency of the sensor.
It is observed that the frequency decreases with increasing temperature while the frequency increases with reduced distance of the sensor to the steel rebar. These changes in frequency can be easily accommodated with the external tuning circuit. Based on the limited data obtained related to the agnetic field, a reasonable range of variation could be from C, which would produce changes in frequency that can be accommodated with the external Since the effects on frequency caused by the presence of steel bars were measured at 14 and 28 mm (one and two times the thickness of the plywood used to separate the steel from the sensor), 28 mm might be the minimum distance because the presence of the steel does not affect the magnetic field of the sensor. At shorter distances and depending on the steel bar diameter, it might create significant magnetic field gradients due to the corrugated surface of the reinforcing steel used in the construction industry. With respect to the direction, because the sensor is considered as a point sensor, it would seem to have no natural direction.

Conclusions
An improved miniature embeddable NMR sensor for use in cement-based materials was designed, built and characterized. Changes in frequency due to temperature variations and the presence of steel rebars can be accommodated using an external tuning circuit. The sensor was successfully used to detect water in fresh cement pastes and to monitor porosity refinement in hardened cement pastes and concretes containing ordinary materials routinely used in the construction industry. A linear relationship exists between the relaxation rate and the compressive strength of concrete mixtures at low and high w/c ratios. The results demonstrate that practical applications are possible and they will be pursued.