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Article

Low Tunnels inside Mediterranean Greenhouses: Effects on Air/Soil Temperature and Humidity

1
Research Centre CIAIMBITAL, University of Almería, Ctra, de Sacramento s/n, 04120 Almería, Spain
2
MED—Instituto Mediterrâneo Para a Agricultura, Ambiente e Desenvolvimento, Departamento de Engenharia Rural, Escola de Ciências e Tecnologia, Universidade de Évora, 7000-849 Évora, Portugal
*
Author to whom correspondence should be addressed.
Agronomy 2021, 11(10), 1973; https://doi.org/10.3390/agronomy11101973
Submission received: 28 August 2021 / Revised: 26 September 2021 / Accepted: 27 September 2021 / Published: 30 September 2021
(This article belongs to the Section Horticultural and Floricultural Crops)

Abstract

:
The main objective of this work was to analyze the microclimate generated inside a low tunnel (floating row cover) installed in an Almería-type greenhouse. Low tunnels are commonly used in the open field to protect plants against insect attack and to improve the production of muskmelon and strawberry. Floating row covers can also be used inside greenhouses during the first few weeks after the transplantation of muskmelon and watermelon crops in spring-summer cycles. This work was carried out during the first weeks of a watermelon culture (Citrullus lanatus Thunb.) growing with a polyethylene row cover inside an Almería-type greenhouse (2115 m2). Air temperature and humidity, plant temperature and soil temperature and humidity were measured in the greenhouse inside and outside the row covers. During the three days of measurement, all greenhouse vent openings were closed. The use of the low tunnels increased average air temperature around plants from 24.0 ± 9.0 °C to 26.9 ± 9.7 °C. A maximum difference in air temperature of about 5.9 °C was observed at noon. The average daily temperature of the crop was 28.2 ± 11.8 °C inside the row cover and 24.6 ± 8.9 °C without it. Similarly, the absolute humidity of air was clearly higher inside the low tunnel (0.0201 ± 0.0098 g/g) than around the plant rows without floating cover (0.0131 ± 0.0048 g/g). The soil temperature was also higher inside the low tunnel compared to the area without this second plastic cover. The effect of the tunnel decreased with depth, with average temperature differences of 1.2 ± 0.5 °C on the soil surface and 0.6 ± 0.5 °C at 20 cm depth.

1. Introduction

Low tunnels (floating row cover) are small arched metal structures, covered with plastic film that provides protection to crops in their early stages of development [1,2,3,4]. For example, high or low tunnels are usually used for strawberry cultivation [5]. For the low tunnels, colorless translucent plastic film is often used, similar to that used on the cover of Mediterranean greenhouses [6], usually of polyethylene [7,8]. The main objective of these low tunnels is the advancement or delay of the growing cycle [9,10], thus allowing production to be obtained at times of the year where without this technique it would not be possible. The use of low tunnels produces an increase in the temperature of the air and soil [11,12], which favors the growth of crops [11,13,14]. Other authors have measured higher air relative humidity under low tunnels than without low tunnels [15,16]. In addition, the low tunnels protect against frost [17,18]. They are usually used in outdoor crops [1], although they can also be used in crops inside greenhouses to give extra protection in the early stages of cultivation. Plastic greenhouses are productive structures that have become widespread in regions with mild winters and in regions with warm climates [19], as, for example, in southeastern Spain [20]. The use of low tunnels is rare inside the Mediterranean greenhouses. For example, only 6% of the greenhouses of the province of Almería (Spain) used low tunnel to protect horticultural crops at the early stages of growth [7]. When growing the crop, the leaves touch the plastic, and it is necessary to remove the low tunnel. These low tunnels allow increasing the air temperature surrounding the seedlings by decreasing energy losses by infrared radiation at night. Placing them above heating pipes allows great energy savings by greatly limiting heat losses by convection to the rest of the greenhouse [7].
The dimensions and types of materials used for the low tunnel, as well as the date of placement and removal, will depend on the requirements of each type of crop [9]. For example, for crops such as strawberry, a minimum height of 40–60 cm is sufficient. Low tunnels (30–40 cm high and 40–50 cm wide) are commonly used in watermelon and melon crops in open fields [9]. However, for crops such as tomato or pepper is necessary to increase the height. The appropriate height also depends on the time to use the low tunnel and the climatic conditions of the area [9]. Low tunnels can also be used with perforations or openings in the plastic film [21]. As for handling, they can be opened and closed at certain times of the day [21]. These low tunnels usually are removed progressively, increasing the degree of opening until their total removal [1].
These low tunnels with polyethylene film were analyzed by Loy and Wells [22] in a hybrid muskmelons crop in an open field. Air temperatures reached inside the low tunnels during the daytime were 4–5 °C higher than the air temperature outside the tunnels, advancing the ripening of the fruit between 12 and 13 days.
Gerber et al. [6] found that the use of these structures, inside a glass greenhouse, favored the growth of a pepper crop, as well as its yield and fruit quality, according to observations by Jolliffe and Gaye [23]. Abak et al. [24] also observed an increase in production using low tunnels in a Physalis crop grown in an open field, with respect to unprotected plants.
Other authors have observed that, in open-air muskmelon crops, higher production was obtained by combining plastic mulch and low tunnels, compared to the use only of plastic mulch or only low tunnels [25]. The bibliographic references found refer mainly to the use of these protection structures in outdoor crops. The main objective of this work is to analyze the modifications in the microclimate generated inside a low tunnel, installed inside an Almería-type greenhouse, during the first weeks after transplanting a watermelon crop in a summer spring cycle.

2. Materials and Methods

2.1. Experimental Greenhouse

The test was carried out in an Almería-type greenhouse with a structure type “Raspa y Amagado” [7] with an area of 2115 m2 (45 × 47 m) located at the “Catedrático Eduardo Fernández” experimentally farm of the UAL-ANECOOP Foundation (36°51′ N, 2°16′ W; 87 m elevation), in the province of Almería, Spain. The greenhouse is equipped with side vents throughout its perimeter and three roof vents. The ventilation surface was 16.2% of the greenhouse soil surface; although during the test, the vents remained closed.
A watermelon crop (Citrullus lanatus Thunb.) was transplanted inside the experimental greenhouse. The material selected was 285 Fenway triploid watermelon plants grafted onto RS841 (T) and 140 Premium diploid watermelon plants grafted onto RS841 (D), with a plant density of 0.25 plants/m2. The low tunnels were used to modify the microclimate around the seedlings during the first development stage. These low tunnels provide watermelon seedlings with an additional thermal coat inside the greenhouse, allowing the advance of the transplant date of the crop in spring-summer cycles. Each low tunnel, 75 cm wide and 50 cm high, protects a complete crop line (Figure 1). A steel round structure (1 cm diameter) and a non-perforated low-density polyethylene (LDPE) plastic film protective material were used for the low tunnel.

2.2. Equipment and Instrumentation

In order to study the effect of low tunnels on the microclimate surrounding the plant, two zones were established for the measurement of different microclimatic parameters. A crop line remained unprotected (without the low tunnel) during the test and all other crop lines were kept protected under low tunnels (Figure 1 and Figure 2). The measures were carried out in the central part of the greenhouse and in areas near the aisle of the greenhouse (Figure 2). Air temperature and humidity were measured with 12 CS215 sensors (Campbell Scientific Spain S.L., Barcelona, Spain) with an SHT75 (Sensirion AG, Zurich, Switzerland) multi sensor module based in complementary metal-oxide-semiconductor CMOSens®. The device includes a capacitive polymer sensing element for relative humidity and a silicon band-gap temperature sensor (accuracy for air temperature of ±0.4 °C over 5 to 40 °C and ±0.9 °C over −40 to 70 °C; accuracy for relative humidity of ±2% over 10 to 90% RH and ±4% over 0 to 100% at 25 °C). The sensors were protected from radiation inside a naturally aspirated box 41003-5 (Campbell Scientific Spain S.L.). The temperature and humidity of the air were measured in three different heights: next to the crop at 0.2 m, and above the crop and low tunnels at 1 m and 2 m in height (Figure 1 and Figure 2). The temperature of the crop was measured using two Thermistor 108 (Campbell Scientific Spain S.L.; accuracy of ±0.1 °C over 0 to 70 °C) attached to the crop leaves. Solar radiation was measured inside the greenhouse (2 m high) with two SP1110 Pyranometers (Campbell Scientific Spain S.L.; sensitivity range of 350–1100 nm; accuracy of ±5%). Two SKP215 Quantum sensors (Skye Instruments Ltd., Llandrindod Wells, UK; measurement range of 0 to 5 × 104 µmol m−2 s−1; accuracy of ±5%) were used to measure photosynthetically active radiation (PAR). Net radiation was measured using two NR-Lite2 Radiometers (Kipp & Zonen B.V., Delft, The Netherlands; spectral response: 0 to 100 µm; measurement range of ±2000 W m−2; accuracy of ±5%). The air velocity was measured (at 1 m height) using two 3D sonic anemometers (model CSAT3, Campbell Scientific Spain S.L.; resolution 0.001 m s−1 for ux, uy and 0.0005 m s−1 for uz; and accuracy ±0.04 m s−1 for ux, uy and ±0.02 m s−1 for uz). The temperature on the ground surface was measured using two TCAV type E thermocouples (Campbell Scientific Spain S.L.; measurement range of −200 to 0 °C and 0 to 900 °C; accuracy of ±1.7%), these sensors were buried superficially [26]. The temperature inside the ground (5, 10, 15, and 20 cm deep) was measured using eight Thermistor 108 (Campbell Scientific Spain S.L.) (Figure 2) [26]. The moisture content in the soil (20 cm deep) was measured with two CS616 Water Content Reflectometers (Campbell Scientific Spain S.L.; measurement range of 0 to 50% VWC (volumetric water content); accuracy of ±2.5%), placed horizontally (Figure 2). The data from these sensors were stored in five CR3000 Microloggers (Campbell Scientific Spain S.L.) with a frequency of 1 Hz [27].
Outside climatic conditions were measured 75 m away from the northern side of the experimental greenhouse (at 10 m of height). Outside air temperature and humidity were measured with a CS215 sensor, outside Solar and PAR radiation were measured with an SP1110 Pyranometer and an SKP215 Quantum sensors, respectively. The data from these sensors were stored in another CR3000 Micrologger (Campbell Scientific Spain S.L.) with a frequency of 1 Hz. Outside wind speed was measured with a Meteostation II (Hortimax S.L., Almería, Spain), incorporating a cup anemometer (measurement range of 0 to 40 m s−1; accuracy of ± 5%) and a vane for wind direction (accuracy ±5°). The Meteostation II measurements were stored in an independent computer system every minute [28].
Climatic parameters were measured from 3 to 5 March 2015 (Table 1). The duration of the test was limited to three days, to avoid damage in the plants that were unprotected outside the low tunnel.

2.3. Statistical Analysis

Multiple range tests were carried out using the software Statgraphics Plus (Manugistics Inc., Rockville, MD, USA). Fisher’s least significant difference (LSD) was used to determine the statistical differences between climatic parameters, establishing the confidence level at 99%.

3. Results and Discussion

3.1. Radiation Levels above the Crop

The solar and PAR radiation measured at 2 m in height were similar in both areas of measurement (above the low tunnels and above the unprotected plants). Thus, the little differences observed in radiation should be caused by the shading of the greenhouse structure components (vents, wire nets, dirt on the cover, etc.). The presence of the low tunnel could be expected to significantly affect net radiation levels measured at 2 m in height above the crop, but no such significant differences have been observed between the two areas of the test, being slightly lower in the area without the low tunnel (Table 2).

3.2. Air and Crop Temperature

The air temperature at 1 m and 2 m of height was very similar in both areas analyzed, above the low tunnel and above unprotected plants (Figure 3 and Table 3).
The air temperature (1 and 2 m height) was slightly lower above the low tunnel crop line in comparison with the crop line without the low tunnel (average daily difference of −0.6 ± 0.2 °C). In the area protected with the low tunnels, the energy lost by infrared radiation is reduced as a consequence of the reflection produced by the plastic cover of the tunnel. The low tunnel also reduced the heat exchanged by convection between the soil surface and the air around the plants (at 0.2 m). As consequence, the low tunnel reduces the heat convection to the air at 1 and 2 m.
Inside the low tunnel, the air temperature (area occupied by the crop) was significantly higher than in the area without the low tunnel (average daily difference of 2.8 ± 1.2 °C), with maximum differences of 4.0, 3.7 and 5.9 °C on days 1, 2, and 3 of the test, respectively. Loy and Wells [22], comparing bare soil with clear polyethylene row cover in an open field, observing that the average temperature of daytime was 4.0 °C higher using the row cover. During the night, air temperature increased only 0.5 °C with the row cover. The value of 4.0 °C of air temperature difference is well above the value of 2.8 °C observed in our case. Perhaps, because we worked inside a greenhouse, reducing the effect of the low tunnels observed by Loy and Wells [22] working in an open field.
In our case, the air temperature inside the low tunnel was above 40 °C in the central hours of days 1 and 3. Using low tunnels of 61 cm base and 38 cm of height and with different plastic materials (clear polyethylene, white polyethylene and spun-bonded polypropylene), Gerber et al. [6] observed the highest 1-day temperature (55 °C) under clear polyethylene, being 3–5 °C lower with spun-bonded polypropylene and 8 °C lower with white polyethylene, and 24 °C lower without the low tunnel. Libik and Siwek [29], in a low tunnel 0.5 m of height with a watermelon crop, observed air temperatures above 35 °C in spring. Optimal temperatures for the vegetative development of the watermelon plant range between 23 and 28 °C [30]. With this protection technique applied in the early stages of plant growth, the development of the crop can be enhanced approaching these optimal temperatures in temperate climate conditions.
The major effect of this crop protection system was observed in the temperature of the plants, achieving an average increase of 3.8 ± 3.2 °C (during the three test days), in comparison with the crop without the low tunnel. The temperature difference reached its maximum value at noon on the third day of measurements (13.0 °C difference). During the daytime period, the increase in crop temperature was 5.7 ± 3.4 °C, 4.2 ± 2.5 °C, and 7.4 ± 3.7 °C for test days 1, 2, and 3, respectively. During the first night, the average temperature of the crop protected with the low tunnel increased by 1.4 ± 0.1 °C in comparison to the crop without the low tunnel (1.7 ± 0.1 °C during the second night).

3.3. Absolute Air Humidity

In the same way as for air temperature, the absolute humidity of the air was very similar (at 1 m and 2 m in height) in both zones, with and without low tunnels (Figure 4 and Table 4). Inside the low tunnel, a microclimate was generated in which the water content of the air rises significantly, as a consequence of the reduction in air convection and of the mixing with the bulk air inside the greenhouse. The average daily value of the absolute humidity of the air surrounding the crop (for the three days of the test) was 0.0131 ± 0.0048 g/g (without the low tunnel) and 0.0201 ± 0.0098 g/g (with the low tunnel); with mean daytime values of absolute air humidity, without the low tunnel of 0.0185 ± 0.0057 g/g (day 1), 0.0165 ± 0.0041 g/g (day 2), and 0.0131 ± 0.0037 g/g (day 3) and with the low tunnel of 0.0291 ± 0.0121 g/g (day 1), 0.0235 ± 0.0073 g/g (day 2), and 0.0272 ± 0.0131 g/g (day 3). The maximum values observed were 0.0265 g/g without the low tunnel and 0.0477 g/g with a low tunnel (during day 1). On average, for the three days of the test, the absolute humidity of the air inside the low tunnel was 50% greater than around the unprotected plants (without the low tunnel), increasing by 80% at the noon. The low tunnel system favors the crops such as watermelon and melon, which need extreme temperatures and high air humidity during the early stages of their development.
In the area occupied by the unprotected plants the maximum relative humidity observed was 86% (early in the morning), while inside the low tunnels, saturation (RH = 100%) was reached in the early hours of the three mornings of measurements (from 9:00 to 10:00). During the night, air relative humidity remained above 90% inside the low tunnel and about 80% around unprotected plants (without the low tunnel).

3.4. Water Content in the Soil

The use of the low tunnel reduced water evaporation from the soil surface, observing a noticeable increase (60%) in water content in the soil under the protection (Figure 5). The average daily value of the soil water content for the three days analyzed was 0.2617 ± 0.0089 g/g (water mass/soil mass) without the low tunnel and 0.4242 ± 0.0125 g/g with the low tunnel. For the maximum observed values (during day 1), the water content was 0.2790 g/g without the low tunnel and 0.4500 g/g with the low tunnel.

3.5. Soil Temperature

Figure 6 shows the time evolution of soil temperature at different depths, with the low tunnel and without the low tunnel. The soil temperature difference with the low tunnel and without the low tunnel decreases with depth (Figure 7). On the surface of the soil, the average temperature was 1.2 ± 0.5 °C higher with the low tunnel than without the low tunnel (during the 3 days of testing), while at 20 cm deep the value reached is 0.6 ± 0.5 °C. A maximum temperature difference of 2.5 °C on the soil surface was observed during the three days, and 1.3 °C at 20 cm deep. During the daytime period, there was an average temperature increase on the soil surface of 1.6 ± 0.5 °C (day 1), 0.9 ± 0.2 °C (day 2) and 1.8 ± 0.5 °C (day 3), and 20 cm deep of 0.8 ± 0.3 °C (day 1), 0.5 ± 0.2 °C (day 2) and 0.7 ± 0.4 °C (day 3). The effect at night was less evident, with increases in temperature on the soil surface from 0.7 ± 0.2 °C (first night) to 1.0 ± 0.3 °C (second night), and from 0.3 ± 0.1 °C (second night) to 0.6 ± 0.2 °C (first night) at 20 cm deep. Libik and Siwek [29], in a low tunnel 0.5 m high with a watermelon crop in an open field, observed increases in soil temperature of 5.9 °C (at 8:00) and 6.8 °C (at 14:00) relative to the soil temperature in the area where the crop was unprotected (in spring). In the same way, Loy and Wells [22] observed an average soil temperature increase of 3.0 °C (during the day) and 2.7 °C (at night) with the row cover compared to the temperature of the bare soil for a muskmelon crop in an open field.
In our case, the differences in soil temperature between the area with the low tunnel and without the low tunnel were lower than those obtained by Libik and Siwek [29] and Loy and Wells [22], possibly because they worked in an open field and we worked inside a greenhouse. Inside greenhouses, the effect of low tunnels observed for both air and soil temperatures, seems to be reduced in comparison with the results reported by other authors.
Figure 8 shows soil temperature profiles for different times of the day. From 0:00 h the soil gradually cooled, transferring heat by convection to the air and by radiation to the plants and the surrounding environment. Between 6:00 and 10:00 h the ground continued to transfer energy to the air, even if the sunrise had already occurred. From 10:00 to 14:00 there was a warming of the soil by solar radiation in the surface and by conduction in the rest of the depths analyzed, reducing the increase in temperature with depth. Soil temperature continues to rise during the afternoon (with maximum values at 18:00 h). At 22:00 h, the bulk soil began to transfer heat by conduction to the upper layers. This heat is finally lost by conduction and radiation to the air, plants, and surrounding environment. A slow and progressive cooling of the soil is observed during the night period (Figure 9). The evolution of the temperature difference between the soil under the low tunnel and the unprotected zone (Figure 8) shows that below 15 cm depth the temperature difference remained below 1 °C. Above 15 cm depth, the temperature difference increased, especially in the afternoon.

4. Conclusions

The use of the low tunnels increased average air temperature around plants from 24.0 ± 9.0 °C to 26.9 ± 9.7 °C. A maximum difference in air temperature of about 5.9 °C was observed at the noon. The average daily temperature of the crop was 28.2 ± 11.8 °C inside the row cover and 24.6 ± 8.9 °C without it. In the same way, the absolute humidity of air was clearly higher inside the low tunnel (0.0201 ± 0.0098 g/g) than around the plant rows without floating cover (0.0131 ± 0.0048 g/g). The soil temperature was also higher inside the low tunnel compared to the area without this second plastic cover. The effect of the tunnel decreases with depth, with average temperature differences of 1.2 ± 0.5 °C on the soil surface and 0.6 ± 0.5 °C at 20 cm depth.

Author Contributions

Conceptualization, F.D.M.-A., A.L.-M., A.P.-F. and D.L.V.-M.; methodology, F.D.M.-A., A.L.-M. and F.J.F.B.; data analysis, A.L.-M., F.D.M.-A. and M.d.l.Á.M.-T.; writing—original draft preparation, A.L.-M. and M.d.l.Á.M.-T.; review and editing, F.D.M.-A., D.L.V.-M., A.P.-F. and F.J.F.B.; project administration, D.L.V.-M.; funding acquisition, D.L.V.-M. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the MINISTERIO DE CIENCIA, INNOVACIÓN y UNIVERSIDADES of Spanish government, grant number PID2019-111293RB-I00, project “Improving profitability in greenhouses by increasing photosynthetic activity with passive climate control techniques (GREENPHOC)”.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Acknowledgments

The authors wish to express their gratitude to the Research Centre CIAIMBITAL of the University of Almería (Spain) and the University of Almeria—ANECOOP Foundation for their collaboration and assistance during the development of this study.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Low tunnels installed inside the experimental greenhouse (a) and measurement equipment (b).
Figure 1. Low tunnels installed inside the experimental greenhouse (a) and measurement equipment (b).
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Figure 2. Experimental setup and location of sensors used in the test.
Figure 2. Experimental setup and location of sensors used in the test.
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Figure 3. Temperature in the zone without low tunnel (a) and in the zone with low tunnel (b) measured from the 3 to 5 March 2015: air temperature at 2 m (─), at 1 m (---) and at 0.2 m (-·-) in height; outside air temperature (▬); plant leaves temperature (···).
Figure 3. Temperature in the zone without low tunnel (a) and in the zone with low tunnel (b) measured from the 3 to 5 March 2015: air temperature at 2 m (─), at 1 m (---) and at 0.2 m (-·-) in height; outside air temperature (▬); plant leaves temperature (···).
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Figure 4. Humidity values in the zone without low tunnel (a) and in the zone with low tunnel (b) measured from the 3 to 5 March 2015: at 2 m (─), 1 m (---) and 0.2 m (-·-) in height; outside (▬).
Figure 4. Humidity values in the zone without low tunnel (a) and in the zone with low tunnel (b) measured from the 3 to 5 March 2015: at 2 m (─), 1 m (---) and 0.2 m (-·-) in height; outside (▬).
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Figure 5. Soil water content (water mass gw/soil mass gs), measured at 0.20 m depth, from the 3 to 5 March 2015: without low tunnel (---); with low tunnel (─).
Figure 5. Soil water content (water mass gw/soil mass gs), measured at 0.20 m depth, from the 3 to 5 March 2015: without low tunnel (---); with low tunnel (─).
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Figure 6. Soil temperature without low tunnel (a) and with low tunnel (b) measured from the 3 to 5 March 2015: at 0 m (▬), 0.05 m (─), 0.10 m (---), 0.15 (-·-), and 0.20 m (···) deep.
Figure 6. Soil temperature without low tunnel (a) and with low tunnel (b) measured from the 3 to 5 March 2015: at 0 m (▬), 0.05 m (─), 0.10 m (---), 0.15 (-·-), and 0.20 m (···) deep.
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Figure 7. Difference in soil temperature with low tunnel and without low tunnel measured from the 3 to 5 March 2015: at 0 m (▬), 0.05 m (─), 0.10 m (---), 0.15 (···), and 0.20 m (···) depth.
Figure 7. Difference in soil temperature with low tunnel and without low tunnel measured from the 3 to 5 March 2015: at 0 m (▬), 0.05 m (─), 0.10 m (---), 0.15 (···), and 0.20 m (···) depth.
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Figure 8. Soil temperature profile without low tunnel (a) and with tunnel (b) at different times on the third day of the test (5 March 2015): at 0:00 (●), 2:00 (○), 6:00 (): 10:00 (), 14:00 (), 18:00 (Δ), and 22:00 () hours.
Figure 8. Soil temperature profile without low tunnel (a) and with tunnel (b) at different times on the third day of the test (5 March 2015): at 0:00 (●), 2:00 (○), 6:00 (): 10:00 (), 14:00 (), 18:00 (Δ), and 22:00 () hours.
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Figure 9. Difference in soil temperature with low tunnel and without low tunnel at different times on the third day of the test (5 March 2015) and at different depths: at 0:00 (●), 2:00 (○), 6:00 (): 10:00 (), 14:00 (), 18:00 (Δ), and 22:00 () hours.
Figure 9. Difference in soil temperature with low tunnel and without low tunnel at different times on the third day of the test (5 March 2015) and at different depths: at 0:00 (●), 2:00 (○), 6:00 (): 10:00 (), 14:00 (), 18:00 (Δ), and 22:00 () hours.
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Table 1. Outside climatic conditions (average value ± standard deviation): uo, wind speed (m s−1); θ, wind direction (°); HRo, air relative humidity (%); To, air temperature (°C); Ro, solar radiation (W m−2); Ro-PAR, PAR radiation (μmol m−2 s−1).
Table 1. Outside climatic conditions (average value ± standard deviation): uo, wind speed (m s−1); θ, wind direction (°); HRo, air relative humidity (%); To, air temperature (°C); Ro, solar radiation (W m−2); Ro-PAR, PAR radiation (μmol m−2 s−1).
Dateuoθ aToHRoRoRo-PAR
Daily
03/03/20150.7 ± 0.6176 ± 11213.7 ± 3.093 ± 11179 ± 280377 ± 590
04/03/20151.8 ± 2.2150 ± 10213.7 ± 2.192 ± 9130 ± 205282 ± 442
05/03/20154.3 ± 2.3104 ± 8212.6 ± 3.741 ± 24235 ± 313483 ± 651
Daytime
3/03/20150.9 ± 0.7260 ± 5215.4 ± 3.486 ± 13358 ± 304755 ± 642
4/03/20151.9 ± 1.9167 ± 8514.8 ± 2.489 ± 9259 ± 224561 ± 482
5/03/20155.0 ± 2.5111 ± 7315.2 ± 2.921 ± 8462 ± 297951 ± 624
Night
3–4/03/20150.3 ± 0.2146 ± 12312.5 ± 0.5100 ± 10.0 ± 0.00 ± 0
4–5/03/20150.3 ± 0.2146 ± 12312.1 ± 1.277 ± 120.0 ± 0.00 ± 0
a Direction perpendicular to the roof vents is 208° for a wind from southwest (SW).
Table 2. Radiation levels inside the greenhouse [average value ± standard deviation]. Ri, inside solar radiation [W m−2]; Ri-PAR, inside PAR radiation [μmol m−2 s−2]; Ri-N, inside net radiation [W m−2]. Subscripts: w, with low tunnel; nw, without low tunnel.
Table 2. Radiation levels inside the greenhouse [average value ± standard deviation]. Ri, inside solar radiation [W m−2]; Ri-PAR, inside PAR radiation [μmol m−2 s−2]; Ri-N, inside net radiation [W m−2]. Subscripts: w, with low tunnel; nw, without low tunnel.
DateRi,wRi,nwRi-PAR,wRi-PAR,nwRi-N,wRi-N,nw
Daily
03/03/2015132 ± 203120 ± 184266 ± 407250 ±38155 ± 12652 ± 124
04/03/201598 ± 15193 ± 141202 ± 309193 ± 29333 ± 9630 ± 93
05/03/2015166 ± 229146 ± 205323 ± 444 *301 ± 414 *61 ± 141malfunction
Daytime
3/03/2015272 ± 217248 ± 195549 ± 433 *518 ± 403 *141 ± 136136 ± 134
4/03/2015201 ± 162191 ± 150415 ± 330397 ± 31098 ± 10392 ± 100
5/03/2015335 ± 222294 ± 202652 ± 428 *607 ± 400 *163 ± 139malfunction
* Denote that there were statistical differences at the 99.0% confidence level (Fisher’s least significant difference, LSD) between the values of radiation with low tunnels and without low tunnels.
Table 3. Temperatures inside the greenhouse [average value ± standard deviation]. Ti, air temperature [°C]; Tc, crop temperature [°C]. Subscripts: w, with low tunnel; nw, without low tunnel. Heights of air temperature measurements: two meters [2 m]; one meter [1 m] and zero point two meters [0.2]; crop temperature [crop].
Table 3. Temperatures inside the greenhouse [average value ± standard deviation]. Ti, air temperature [°C]; Tc, crop temperature [°C]. Subscripts: w, with low tunnel; nw, without low tunnel. Heights of air temperature measurements: two meters [2 m]; one meter [1 m] and zero point two meters [0.2]; crop temperature [crop].
Date[2 m][1 m][0.2 m][Crop]
Ti,wTi,nwTi,wTi,nwTi,wTi,nwTc,wTc,nw
Daily
03/03/201524.9 ± 9.825.5 ± 9.925.5 ± 10.225.8 ± 10.427.8 ± 9.9 *25.5 ± 9.3 *29.3 ± 12.0 *25.7 ± 9.1 *
04/03/201523.0 ± 7.523.6 ± 7.623.5 ± 7.923.8 ± 8.125.9 ± 7.4 *23.6 ± 7.0 *27.0 ± 9.2 *24.2 ± 7.0 *
05/03/201522.3 ± 10.922.9 ± 10.922.9 ± 11.323.1 ± 11.426.8 ± 11.3 *22.9 ± 10.2 *28.4 ± 13.6 *23.8 ± 10.2 *
Daytime
3/03/201531.5 ± 10.332.3 ± 10.532.5 ± 10.832.9 ± 11.034.4 ± 10.7 *31.8 ± 9.9 *37.7 ± 12.5 *32 ± 9.4 *
4/03/201528.3 ± 7.729.0 ± 7.829.2 ± 8.129.5 ± 8.331.0 ± 7.8 *28.5 ± 7.3 *33.5 ± 9.5 *29.3 ± 7.1 *
5/03/201530.5 ± 10.231.0 ± 10.231.4 ± 10.531.7 ± 10.635.2 ± 10.7 *30.5 ± 9.8 *38.9 ± 12.4 *31.4 ± 9.5 *
Night
3–4/03/201519.2 ± 1.7 *19.9 ± 1.7 *19.6 ± 1.719.7 ± 1.722.2 ± 2.0 *20.3 ± 1.7 *22.0 ± 1.7 *20.6 ± 1.7 *
4–5/03/201515.5 ± 1.9 *16.1 ± 1.9 *15.8 ± 1.915.9 ± 2.019.3 ± 2.1 *16.6 ± 1.9 *19.0 ± 1.9 *17.3 ± 2.0 *
* Denote that there were statistical differences at the 99.0% confidence level (Fisher’s least significant difference, LSD) between the values of temperature with low tunnels and without low tunnels.
Table 4. Absolute air humidity inside the greenhouse, xi [g g−1] [average value ± standard deviation]. Subscripts: w, with low tunnel; nw, without low tunnel. Heights of air temperature measurements: two meters [2 m]; one meter [1 m] and zero point two meters [0.2].
Table 4. Absolute air humidity inside the greenhouse, xi [g g−1] [average value ± standard deviation]. Subscripts: w, with low tunnel; nw, without low tunnel. Heights of air temperature measurements: two meters [2 m]; one meter [1 m] and zero point two meters [0.2].
Date[2 m][1 m][0.2 m]
xi,wxi,nwxi,wxi,nwxi,wxi,nw
Daily
03/03/20150.0148 ± 0.00540.0151 ± 0.00540.0149 ± 0.00540.0151 ± 0.00540.0219 ± 0.0110 *0.0149 ± 0.0054 *
04/03/20150.0136 ± 0.00400.0139 ± 0.00400.0137 ± 0.00400.0139 ± 0.00400.0189 ± 0.0068 *0.0137 ± 0.0039 *
05/03/20150.0104 ± 0.00360.0107 ± 0.00350.0106 ± 0.00360.0107 ± 0.00360.0195 ± 0.0108 *0.0106 ± 0.0036 *
Daytime
3/03/20150.0184 ± 0.00580.0187 ± 0.00570.0186 ± 0.00580.0187 ± 0.00580.0291 ± 0.0121 *0.0185 ± 0.0057 *
4/03/20150.0164 ± 0.00420.0167 ± 0.00410.0166 ± 0.00420.0168 ± 0.00420.0235 ± 0.0073 *0.0165 ± 0.0041 *
5/03/20150.0129 ± 0.00370.0131 ± 0.00360.0130 ± 0.00370.0131 ± 0.00360.0272 ± 0.0108 *0.0131 ± 0.0037 *
Night
3–4/03/20150.0118 ± 0.0009 *0.0122 ± 0.0009 *0.0120 ± 0.0009 *0.0122 ± 0.0009 *0.0155 ± 0.0016 *0.0120 ± 0.0009 *
4–5/03/20150.0092 ± 0.0012 *0.0096 ± 0.0012 *0.0094 ± 0.00110.0095 ± 0.00120.0129 ± 0.0015 *0.0094 ± 0.0012 *
* Denote that there were statistical differences at the 99.0% confidence level (Fisher’s least significant difference, LSD) between the values of temperature with low tunnels and without low tunnels.
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López-Martínez, A.; Molina-Aiz, F.D.; Moreno-Teruel, M.d.l.Á.; Peña-Fernández, A.; Baptista, F.J.F.; Valera-Martínez, D.L. Low Tunnels inside Mediterranean Greenhouses: Effects on Air/Soil Temperature and Humidity. Agronomy 2021, 11, 1973. https://doi.org/10.3390/agronomy11101973

AMA Style

López-Martínez A, Molina-Aiz FD, Moreno-Teruel MdlÁ, Peña-Fernández A, Baptista FJF, Valera-Martínez DL. Low Tunnels inside Mediterranean Greenhouses: Effects on Air/Soil Temperature and Humidity. Agronomy. 2021; 11(10):1973. https://doi.org/10.3390/agronomy11101973

Chicago/Turabian Style

López-Martínez, Alejandro, Francisco D. Molina-Aiz, María de los Ángeles Moreno-Teruel, Araceli Peña-Fernández, Fátima J. F. Baptista, and Diego L. Valera-Martínez. 2021. "Low Tunnels inside Mediterranean Greenhouses: Effects on Air/Soil Temperature and Humidity" Agronomy 11, no. 10: 1973. https://doi.org/10.3390/agronomy11101973

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