Quality control of 10-min soil temperatures data at RMI

Abstract. Soil temperatures at various depths are unique parameters useful to describe both the surface energy processes and regional environmental and climate conditions. To provide soil temperature observation in different regions across Belgium for agricultural management as well as for climate research, soil temperatures are recorded in 13 of the 20 automated weather stations operated by the Royal Meteorological Institute (RMI) of Belgium. At each station, soil temperature can be measured at up to 5 different depths (from 5 to 100 cm) in addition to the bare soil and grass temperature records. Although many methods have been developed to identify erroneous air temperatures, little attention has been paid to quality control of soil temperature data. This contribution describes the newly developed semi-automatic quality control of 10-min soil temperatures data at RMI.

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Seasonal Changes in Soil and Air Temperature at Three Locations in Puerto Rico, 1963-67

The Journal of Agriculture of the University of Puerto Rico ◽

10.46429/jaupr.v56i3.10837 ◽

1969 ◽

Vol 56 (3) ◽

pp. 307-317 ◽

Cited By ~ 1

Author(s):

M. A. Lugo-López ◽

Modesto Capiel

Keyword(s):

Soil Moisture ◽

Soil Temperature ◽

Air Temperature ◽

Soil Cover ◽

Bare Soil ◽

Soil Conditions ◽

Adequate Explanation ◽

The North ◽

Air Temperatures ◽

Soil Temperatures

Soil temperature data at Río Piedras in the north, Lajas in the southwest, and Fortuna in the south, are given in this paper for the 5-year period 1963- 67. Seasonal variations in soil and air temperatures follow distinct patterns somewhat, depending on the nature of the soil cover and rainfall. Mean maximum and minimum temperatures at the 2-inch depth, respectively, are: Río Piedras, 96.2° F. and 79.6° F.; Lajas, 102.1° F. and 69.0° F.; and Fortuna, 93.2° F. and 79.1° F. The corresponding soil temperatures at the 8-inch depth, respectively, are: Río Piedras, 80.5° F. and 77.4° F.; Lajas, 83.4° F. and 77.8° F.; and Fortuna, 85.7° F. and 82.7° F. The differences and trends of soil temperature at 2-inch and 8-inch depths can find adequate explanation when soil moisture and soil cover are considered. However, the differences between maximum and minimum soil temperatures at 8 inches of depth are roughly one fifth of the corresponding ones at the 2-inch depth. The maximum and minimum air temperature at Lajas, Fortuna and Río Piedras are much more similar to each other than the corresponding soil temperature, especially at the 2-inch depth. This is mainly because air temperature is rather measured on a macro and integrating scale while soil temperature measurements exhibit localized effects of soil cover and soil moisture. It was found that highly significant 2-inch soil-air temperature relationships are evident under bare soil conditions. The same relationships were not significant under sod cover at Fortuna.

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Seasonal dynamics of methane emissions from a subarctic fen in the Hudson Bay Lowlands

Biogeosciences ◽

10.5194/bg-10-4465-2013 ◽

2013 ◽

Vol 10 (7) ◽

pp. 4465-4479 ◽

Cited By ~ 19

Author(s):

K. L. Hanis ◽

M. Tenuta ◽

B. D. Amiro ◽

T. N. Papakyriakou

Keyword(s):

Soil Temperature ◽

Air Temperature ◽

Growing Season ◽

Near Surface ◽

Growing Seasons ◽

Air Temperatures ◽

Soil Temperatures ◽

Surface Soil Temperature ◽

Filling Method ◽

Highly Correlated

Abstract. Ecosystem-scale methane (CH4) flux (FCH4) over a subarctic fen at Churchill, Manitoba, Canada was measured to understand the magnitude of emissions during spring and fall shoulder seasons, and the growing season in relation to physical and biological conditions. FCH4 was measured using eddy covariance with a closed-path analyser in four years (2008–2011). Cumulative measured annual FCH4 (shoulder plus growing seasons) ranged from 3.0 to 9.6 g CH4 m−2 yr−1 among the four study years, with a mean of 6.5 to 7.1 g CH4 m−2 yr−1 depending upon gap-filling method. Soil temperatures to depths of 50 cm and air temperature were highly correlated with FCH4, with near-surface soil temperature at 5 cm most correlated across spring, fall, and the shoulder and growing seasons. The response of FCH4 to soil temperature at the 5 cm depth and air temperature was more than double in spring to that of fall. Emission episodes were generally not observed during spring thaw. Growing season emissions also depended upon soil and air temperatures but the water table also exerted influence, with FCH4 highest when water was 2–13 cm below and lowest when it was at or above the mean peat surface.

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Soil Temperature Estimation with Meteorological Parameters by Using Tree-Based Hybrid Data Mining Models

Mathematics ◽

10.3390/math8091407 ◽

2020 ◽

Vol 8 (9) ◽

pp. 1407

Author(s):

Mohammad Taghi Sattari ◽

Anca Avram ◽

Halit Apaydin ◽

Oliviu Matei

Keyword(s):

Soil Temperature ◽

Soil Depth ◽

Sunshine Duration ◽

Evaluation Criteria ◽

Nonlinear Problems ◽

Soil Temperatures ◽

Different Depths ◽

Windowing Technique ◽

Using Data ◽

Research Decision

The temperature of the soil at different depths is one of the most important factors used in different disciplines, such as hydrology, soil science, civil engineering, construction, geotechnology, ecology, meteorology, agriculture, and environmental studies. In addition to physical and spatial variables, meteorological elements are also effective in changing soil temperatures at different depths. The use of machine-learning models is increasing day by day in many complex and nonlinear branches of science. These data-driven models seek solutions to complex and nonlinear problems using data observed in the past. In this research, decision tree (DT), gradient boosted trees (GBT), and hybrid DT–GBT models were used to estimate soil temperature. The soil temperatures at 5, 10, and 20 cm depths were estimated using the daily minimum, maximum, and mean temperature; sunshine intensity and duration, and precipitation data measured between 1993 and 2018 at Divrigi station in Sivas province in Turkey. To predict the soil temperature at different depths, the time windowing technique was used on the input data. According to the results, hybrid DT–GBT, GBT, and DT methods estimated the soil temperature at 5 cm depth the most successfully, respectively. However, the best estimate was obtained with the DT model at soil depths of 10 and 20 cm. According to the results of the research, the accuracy rate of the models has also increased with increasing soil depth. In the prediction of soil temperature, sunshine duration and air temperature were determined as the most important factors and precipitation was the most insignificant meteorological variable. According to the evaluation criteria, such as Nash-Sutcliffe coefficient, R, MAE, RMSE, and Taylor diagrams used, it is recommended that all three (DT, GBT, and hybrid DT–GBT) data-based models can be used for predicting soil temperature.

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Development of Shallow-Depth Soil Temperature Estimation Model Based on Thermal Response in Permafrost Area

Applied Sciences ◽

10.3390/app8101886 ◽

2018 ◽

Vol 8 (10) ◽

pp. 1886 ◽

Cited By ~ 1

Author(s):

Keunbo Park ◽

Heekwon Yang ◽

Bang Lee ◽

Dongwook Kim

Keyword(s):

Soil Temperature ◽

Temperature Measurement ◽

Thermal Response ◽

Estimation Model ◽

Temperature Estimation ◽

Soil Temperatures ◽

Different Depths ◽

The Relationship ◽

Temperature Depth ◽

Good Agreement

A soil temperature estimation model for increasing depth in a permafrost area in Alaska near the Bering Sea is proposed based on a thermal response concept. Thermal response is a measure of the internal physical heat transfer of soil due to transferred heat into the soil. Soil temperature data at different depths from late spring to the early autumn period at multiple permafrost sites were collected using automatic sensor measurements. From the analysis results, a model was established based on the relationship between the normalized cumulative soil temperatures (CRCST*i,m and CST*ud,m) of two different depths. CST*ud,m is the parameter of the soil temperature measurement at a depth of 5 cm, and CRCST*i,m is the parameter of the soil temperature measured at deeper depths of i cm (i = 10, 15, 20, and 30). Additionally, the fitting parameters of the mathematical models of the CRCST*i,m–CST*ud,m relationship were determined. The measured soil temperature depth profiles at a different site were compared with their predicted soil temperatures using the developed model for the model validation purpose. Consequently, the predicted soil temperatures at different soil depths using the soil temperature measurement of the uppermost depth (5 cm) were in good agreement with the measured results.

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A Study of the Annual Soil Temperature Wave

Australian Journal of Chemistry ◽

10.1071/ch9520303 ◽

1952 ◽

Vol 5 (2) ◽

pp. 303 ◽

Cited By ~ 1

Author(s):

ES West

Keyword(s):

Soil Temperature ◽

Air Temperature ◽

Temperature Wave ◽

Theoretical Equation ◽

Mean Temperature ◽

Air Temperatures ◽

Soil Temperatures

Soil temperatures recorded at Griffith over an 8 year period at a depth ranging from 1 in. to 8 ft. have been examined and compared with air temperatures. The observed fluctuations m the soil temperatures fit closely the theoretical equation for the propagation of a simple harmonic temperature wave into the so11. The diffusivity of the sol1 has been deduced and compared with values found by other workers in other localities. The annual wave of the daily mean temperature at the surface of the soil has been deduced and compared with the annual wave of the dally mean air temperature and the differences in the means, amplitudes, and phase displacements have been discussed.

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Do wheat breeders have suitable genetic variation to overcome short coleoptiles and poor establishment in the warmer soils of future climates?

Functional Plant Biology ◽

10.1071/fp15362 ◽

2016 ◽

Vol 43 (10) ◽

pp. 961 ◽

Cited By ~ 8

Author(s):

Greg J. Rebetzke ◽

Bangyou Zheng ◽

Scott C. Chapman

Keyword(s):

Soil Temperature ◽

Crop Yields ◽

Triticum Aestivum L ◽

Wheat Breeding ◽

Crop Failure ◽

Coleoptile Length ◽

Crop Establishment ◽

Air Temperatures ◽

Reduced Height ◽

Soil Temperatures

Increases in air and soil temperatures will impact cereal growth and reduce crop yields. Little is known about how increasing temperatures will impact seedling growth and crop establishment. Climate forecast models predict that by 2060, mean and maximum air temperatures in the Australian wheatbelt will increase by 2−4°C during the March–June sowing period, and particularly at lower latitudes. Concomitant increases in soil temperature will shorten coleoptile length to reduce crop establishment, particularly where deep sowing to access sub-surface moisture. Mean coleoptile length was reduced in commercial wheat (Triticum aestivum L.) germplasm with increasing soil temperature (106 mm and 51 mm at 15°C and 31°C, respectively). Coleoptile lengths of modern semidwarf varieties were significantly (P < 0.01) shorter than those of older tall wheats at 15°C (95 mm and 135 mm) and 31°C (46 mm and 70 mm). A 12-parent diallel indicated large additive and small non-maternal genetic effects for coleoptile length at 15°C and 27°C. Large genotype rank changes for coleoptile length across temperatures (rs = 0.37, P < 0.05) contributed to smaller entry-mean heritabilities (0.41–0.67) to reduce confidence in selection for long-coleoptile genotypes across contrasting temperatures. General combining ability effects were strongly correlated across temperatures (rp = 0.81, P < 0.01), indicating the potential of some donors in identification of progeny with consistently longer coleoptiles. Warmer soils in future will contribute to poor establishment and crop failure, particularly with deep-sown semidwarf wheat. Breeding long-coleoptile genotypes with improved performance will require targeted selection at warmer temperatures in populations incorporating novel sources of reduced height and greater coleoptile length.

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Local Air and Soil Temperature Modeling Using Himawari 8 Satellite Imagery

Sains Tanah - Journal of Soil Science and Agroclimatology ◽

10.15608/stjssa.v15i2.23020 ◽

2018 ◽

Vol 15 (2) ◽

pp. 123

Author(s):

Adhia Azhar Fauzan ◽

Komariah Komariah ◽

Sumani Sumani ◽

Dwi Priyo Ariyanto ◽

Tuban Wiyoso

Keyword(s):

Soil Temperature ◽

Satellite Imagery ◽

Air Temperature ◽

Statistical Tests ◽

Pair Correlation ◽

Satellite Image ◽

Bare Soil ◽

Central Java ◽

Temperature Modeling ◽

Soil Temperatures

Himawari 8 satellite image, which was launched in October 2014 and began the operational in July 2015, serves to identify and track the phenomenon of rapid changes in weather. The purpose of this research was to determine the model of local air and soil temperatures using Himawari 8 satellite image. Local air and soil temperatures information was collected from the Climatology Station of Semarang district, Central Java, Indonesia. Interpretation of the Himawari 8 satellite image was performed, as well as the statistical tests of correlation and regression, according to the sun's pseudo motion. Pair correlation and regression analysis on satellite image with air temperature; and air temperature with soil temperature (bare and grass). The results showed the satellite imagery of Himawari 8 could predict the air and soil temperatures, especially bare soil. In specific, the accuracies were higher on soil temperature at 0 (surface) and 5 cm depth. But each period produced vary accuracy, due to many weather elements had may affect the air and soil temperatures.

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Physical Characteristics of Mulches and Their Impact on Crop Response and Profitability in Muskmelon Production

HortTechnology ◽

10.21273/horttech.7.2.165 ◽

1997 ◽

Vol 7 (2) ◽

pp. 165-169 ◽

Cited By ~ 8

Author(s):

Lynn Brandenberger ◽

Bob Wiedenfeld

Keyword(s):

Soil Temperature ◽

Fruit Quality ◽

Fruit Size ◽

Bare Soil ◽

Physical Characteristics ◽

Soluble Solids ◽

Crop Response ◽

Commercial Products ◽

Soil Temperatures ◽

Base Selection

Using polyethylene mulches has increased earliness, yields, and fruit quality in muskmelon, resulting in their extensive use for melon production with numerous commercial products. However, two problems are associated with polyethylene use: removal and disposal following production. Organic mulches are potential alternatives but, in this study, resulted in significantly lower soil temperatures than all other treatments and generally had lower yields. Soil temperature, yield, fruit size and percent soluble solids were increased by polyethylene mulches compared to bare soil. Crop response differences between polyethylene mulches were not significant for most characteristics measured. There were significant differences in durability and ease of removal of polyethylene mulches. Based our results, durability and ease of removal are the main characteristics on which to base selection. Proper mulch selection can reduce removal costs and enable commercial producers to leave a mulch in place for the production of a second crop.

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Soil Temperature and Tomato Root Growth Under Black Polyethylene and Hairy Vetch Mulches

HortScience ◽

10.21273/hortsci.30.4.850b ◽

1995 ◽

Vol 30 (4) ◽

pp. 850B-850

Author(s):

John R. Teasdale ◽

Aref A. Abdul-Baki

Keyword(s):

Soil Temperature ◽

Total Yield ◽

Bare Soil ◽

Outer Edge ◽

Hairy Vetch ◽

Tomato Root ◽

Vicia Villosa ◽

Tomato Roots ◽

Soil Temperatures ◽

Raised Bed

Temperature and root length at selected locations within a raised bed under black polyethylene (BP), hairy vetch (Vicia villosa Roth) residue (HV), or bare soil (BS) were measured and correlated with tomato (Lycopersicon esculentum Mill.) growth. Early in the season, before the tomato leaf canopy closed, soil temperature was influenced more by vertical depth in the bed than by horizontal location across the bed. Maximum soil temperatures under BP averaged 5.7 and 3.4C greater than those under HV at 5- and 15-cm depths, respectively. More hours at temperatures >20C during the first 4 weeks probably accounted for greater early root and shoot growth and greater early yield of tomatoes grown in BP rater than in HV or BS. After canopy closure, soil temperatures under tomato foliage were reduced compared to those on the outer edge of the beds. Most tomato roots were in areas of the bed covered by the tomato canopy where temperatures in all treatments remained in the optimum 20 to 30C range almost continuously. Soil temperature, therefore, did not explain why total yield was higher in the HV than the BP or BS treatments.

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Mow-kill Regulation of Winter Cereals for Spring No-till Crop Production

Weed Technology ◽

10.1017/s0890037x00039890 ◽

1996 ◽

Vol 10 (2) ◽

pp. 247-252 ◽

Cited By ~ 10

Author(s):

Erik D. Wilkins ◽

Robin R. Bellinder

Keyword(s):

Soil Temperature ◽

Crop Production ◽

Dry Matter ◽

Field Studies ◽

Bare Soil ◽

Growth Stages ◽

Winter Cereals ◽

No Till ◽

Soil Temperatures ◽

Different Growth Stages

Field studies determined the influence of developmental stage on mow-killing of winter wheat and rye. Both crops were clipped at either three or four different growth stages in 1992 and 1993. When mowed at first node, wheat biomass was 4350 and 1970 kg/ha in 1992 and 1993, respectively. At this stage, primary tiller apices were below 10 cm and regrowth was vigorous. Mowing prior to 75% heading consistently yielded more than 1000 kg/ha regrowth 8 wk later. Wheat cut after flowering produced 15 460 and 9160 kg/ha dry matter in 1992 and 1993, respectively, but less than 30 kg/ha total regrowth. At first and second node, rye produced 4440 and 1800 kg/ha biomass in 1992 and 1993. When mowed belore boot, more than 50% of the total rye biomass was due to regrowth. Rye mowed at boot yielded 6940 and 3740 kg/ha in 1992 and 1993 respectively, and regrowth measured 780 and 910 kg/ha 8 wk later. Mowing after flowering resulted in no measurable regrowth. Soil temperature and PAR were affected by mow-kill date and biomass. Biomass at first mowings (first and second node) in both wheat and rye reduced seasonal soil temperatures 3.5 C compared to bare soil temperatures; while biomass at kernal-filling lowered temperatures 6.0 C. Measured 8 wk after mowing, first node mowings absorbed between 55% and 70% PAR, while plants mowed at kernal-filling absorbed less than 5%.

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