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Seasonality of net radiation in two sub-basins of Paracatu by the use of modis sensor products

Sazonalidade do saldo de radiação em duas sub-bacias do Paracatu por meio da utilização de produtos do sensor modis

Abstracts

The net radiation (Rn) represents the main source of energy for physical and chemical processes that occur in the surface-atmosphere interface, and it is used for air and soil heating, water transfer, in the form of vapor from the surface to the atmosphere, and for the metabolism of plants, especially photosynthesis. If there is no record of net radiation in certain areas, the use of information is important to help determine it. Among them we can highlight those provided by remote sensing. In this context, this work aims to estimate the net radiation, with the use of products of MODIS sensor, in the sub-basins of Entre Ribeiros creek and Preto River, located between the Brazilian states of Goiás and Minas Gerais. The SEBAL (Surface Energy Balance Algorithm for Land) was used to obtain the Rn in four different days in the period of July to October, 2007. The Rn results obtained were consistent with others cited in the literature and are important because the orbital information can help determine the Rn in areas where there are not automatic weather stations to record the net radiation.

meteorological information; river basins; remote sensing


O saldo de radiação (Rn) representa a principal fonte de energia para os processos físico-químicos que ocorrem na interface superfície-atmosfera, sendo utilizado no aquecimento do ar e do solo, transferência da água, na forma de vapor da superfície para a atmosfera, e metabolismo das plantas, especialmente a fotossíntese. Se não houver o registro do saldo de radiação em determinadas áreas, torna-se importante a utilização de informações que ajudem a determiná-lo. Entre elas, podemos destacar as fornecidas por sensoriamento remoto. Neste contexto, este trabalho tem o objetivo de determinar o saldo de radiação, com a utilização de produtos do sensor MODIS, nas sub-bacias do Ribeirão Entre Ribeiros e Rio Preto, que ficam entre os Estados de Goiás e Minas Gerais. O SEBAL (Surface Energy Balance Algorithm for Land) foi utilizado para a obtenção do Rn em quatro dias diferentes, no período de julho a outubro de 2007. Os resultados encontrados foram compatíveis com outros citados em literatura e são importantes, pois as informações orbitais podem auxiliar na determinação do Rn em áreas onde não existam estações meteorológicas automáticas que registrem o saldo de radiação.

informação meteorológica; bacias hidrográficas; sensoriamento remoto


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PROFESSIONAL TEACHING, RESEARCHING, EXTENSION AND POLITICS

Seasonality of net radiation in two sub-basins of Paracatu by the use of modis sensor products

Sazonalidade do saldo de radiação em duas sub-bacias do Paracatu por meio da utilização de produtos do sensor modis

Evaldo de P. LimaI; Gilberto C. SediyamaII; Bernardo B. da SilvaIII; José M. GlerianiIV; Vicente P. SoaresV

IMeteorologista, Dr. Pesquisador, CNPS/EMBRAPA, Rua Jardim Botânico Nº 1024 - Jardim Botânico, Rio de Janeiro - RJ, evaldo.lima@embrapa.br

IIEngº Agrônomo, Ph.D. Prof. Titular, Engenharia Agrícola, CCA/UFV, g.sediyama@ufv.br

IIIMeteorologista, Dr. Prof. Visitante, Ciências Geográficas, CFCH/UFPE, bbdasilva.ufpe@gmail.com

IVEngº Agrônomo, Dr. Prof. Adjunto, Engenharia Florestal, CCA/UFV, gleriani@gmail.com

VEng° Florestal, Ph.D. Prof. Associado, Engenharia Florestal, CCA/UFV, vicente@ufv.br

ABSTRACT

The net radiation (Rn) represents the main source of energy for physical and chemical processes that occur in the surface-atmosphere interface, and it is used for air and soil heating, water transfer, in the form of vapor from the surface to the atmosphere, and for the metabolism of plants, especially photosynthesis. If there is no record of net radiation in certain areas, the use of information is important to help determine it. Among them we can highlight those provided by remote sensing. In this context, this work aims to estimate the net radiation, with the use of products of MODIS sensor, in the sub-basins of Entre Ribeiros creek and Preto River, located between the Brazilian states of Goiás and Minas Gerais. The SEBAL (Surface Energy Balance Algorithm for Land) was used to obtain the Rn in four different days in the period of July to October, 2007. The Rn results obtained were consistent with others cited in the literature and are important because the orbital information can help determine the Rn in areas where there are not automatic weather stations to record the net radiation.

Keywords: meteorological information, river basins, remote sensing.

RESUMO

O saldo de radiação (Rn) representa a principal fonte de energia para os processos físico-químicos que ocorrem na interface superfície-atmosfera, sendo utilizado no aquecimento do ar e do solo, transferência da água, na forma de vapor da superfície para a atmosfera, e metabolismo das plantas, especialmente a fotossíntese. Se não houver o registro do saldo de radiação em determinadas áreas, torna-se importante a utilização de informações que ajudem a determiná-lo. Entre elas, podemos destacar as fornecidas por sensoriamento remoto. Neste contexto, este trabalho tem o objetivo de determinar o saldo de radiação, com a utilização de produtos do sensor MODIS, nas sub-bacias do Ribeirão Entre Ribeiros e Rio Preto, que ficam entre os Estados de Goiás e Minas Gerais. O SEBAL (Surface Energy Balance Algorithm for Land) foi utilizado para a obtenção do Rn em quatro dias diferentes, no período de julho a outubro de 2007. Os resultados encontrados foram compatíveis com outros citados em literatura e são importantes, pois as informações orbitais podem auxiliar na determinação do Rn em áreas onde não existam estações meteorológicas automáticas que registrem o saldo de radiação.

Palavras-chave: informação meteorológica, bacias hidrográficas, sensoriamento remoto.

INTRODUCTION

The net radiation (Rn) can be measured by a radiometer balance, but, in the absence of this instrument, it is common to estimate this climatic element with the aid of information obtained by a heliograph or pyranometer, which are usually installed in conventional and automatic weather stations, respectively. In Brazil, by the end of January 2011, the Brazilian National Institute of Meteorology (INMET) had 294 conventional weather stations and the insolation data were obtained in heliographs. There were also 453 automatic weather stations, of which, 422 recorded the shortwave radiation incident through pyranometers. INMET reported that the installation of the automatic ones sought answers, whenever possible, the synoptic scale (1º x 1º). From these INMET stations, the State of Minas Gerais (MG) has 51 conventional stations, 36 with heliographs and four with actinographs, and 53 automatic stations equipped with pyranometers. The State of Goiás (GO), on the other hand, owns 11 conventional stations, 10 with heliographs, none with actinographs, and 22 automatic stations with pyranometers.

Despite the increase in the number of automatic weather stations, which occurred in recent years in Brazil, as recorded for LIMA (2005), who reports that in 2005 there were only 72 automatic stations installed by INMET. It must be remembered that Brazil has about 8.5 million km2 and that the information collected by these stations are punctual. DI PACE et al. (2008) confirm this information stating that many instruments are able to measure with good accuracy the radiation balance, however, those considered as "conventional" provide punctual measurements of this term, which are representative only for small areas. When there is need to estimate this climate element over large areas, techniques based on measurements taken by satellite sensors are more appropriate because they comprise a large spatial coverage and have low operating cost.

PAIVA (2005) complements stating that due to the scarcity of data, it has become essential to use alternative techniques to complement weather information about a particular location. The remote sensing techniques have been widely used for information parameters of the atmosphere and surface, which are important for monitoring flows or parameters associated with regional and global scale, whose level of detail is determined by the spatial resolution of the multispectral sensors used. Among the sensing techniques, it is important to highlight the use of spaceborne sensors aboard environmental satellites, when it is desired to get information from large areas.

To obtain the net radiation at the surface, beyond the orbital information, it is necessary the use of algorithms, among them it is possible to mention SEBAL (Surface Energy Balance Algorithm for Land). In Brazil, the jobs from MENDONÇA (2007), ANDRADE (2008), DI PACE et al. (2008), NICÁCIO (2008), GOMES et al. (2009) and RODRIGUES et al. (2009) that were performed in different locations can be highlighted. It is noteworthy that most of these studies have used information from the TM (Thematic Mapper) sensor, aboard the Landsat-5, to determine the instantaneous net radiation, i.e., the value was estimated in the moment that the satellite passed over the location.

The radiation balance through SEBAL is the result of the accounting for shortwave radiation that focuses and reflects the surface, and incident long wave radiation, reflected and emitted by the surface. The Rn available to the surface is strongly influenced by the incident shortwave radiation, and is partitioned into power for air and soil temperatures change and to process the water phase change, which is sensible heat flows in the air (H), sensible heat flow in the ground (G) and latent heat flow (λET), respectively. According to HEMAKUMARA et al. (2003), dividing the available energy to the surface in sensible heat flows in the air and ground, and latent is controlled by surface type and condition. Thus, the net radiation can be defined as the radioactive energy available at the surface, which is the main agent of many physical and biological processes. In this context, this work aims to determine the instantaneous and average, of 24 hours, radiation balance with the use of products of the MODIS (Moderate Resolution Imaging Spectrometer) sensor aboard the Terra satellite, in the sub-basins of the Entre Ribeiros creek e Preto River.

MATERIAL AND METHODS

Studied Area

The Basin of Paracatu River is located in the Medium São Francisco region, and drains an area of approximately 45.600km2, which means it is the second largest sub-basin of the São Francisco River. The sub-basins of Entre Ribeiros creek and Preto River, object of this study, represent about 30% of the Paracatu basin area. These two sub-basins, located in the Alto Paracatu region, cover the territories of the Federal District and the states of Goiás and Minas Gerais (Figure 1). According LATUF (2007), the sub-basins of the Entre Ribeiros creek and Preto river, Paracatu affluents, drain an area of approximately 14.149km2, of which 74.87% (10.621km2) are located in the State of Minas Gerais, 15.71% (2.212km2) in the state of Goiás and 9.42% (1.316km2) in the Federal District.


The climate of the Paracatu basin is predominantly tropical wet, with the rainy period from October to April, with emphasis on the period of November, December and January as the wettest. The annual rainfall average in the basin is 1.338mm, while the annual average evapotranspiration is 1.140mm (BRASIL, 1996).

The main uses of water resources in the sub-basins of the Entre Ribeiros creek and Preto river are to meet the demands of urban and animal water supply and irrigation. Most of the irrigated areas in the Paracatu basin are concentrated from the headwaters to half its draining system, especially in the Entre Ribeiros creek and Preto river, concentrating 53% of the irrigated area in the basin identified by the Master Plan for the Paracatu Basin Water Resources - PLANPAR (BRASIL, 1996).

In the Preto river basin, the land use is characterized by intensive farming and high-tech mechanized agriculture, particularly the use of intensive center pivots in the irrigation process. BORGES (2008), using images from LANDSAT/ETM+ sensor of 2003, identified 226 pivots in the Preto river basin. Of these, 87 were located in the Federal District, 81 in Minas Gerais and 58 in Goiás. This author also states that the main activities developed in the basin are the milk and grains productions, in which the productions of corn, soybean, bean, sorghum, wheat and vegetables in general are highlighted.

Data acquisition and processing

The MODIS sensor products: MOD09GA (surface spectral reflectance, bands 1-7), MOD11A1 (surface temperature, bands 31 and 32) and MOD07 (zenith angle) of July 14th, August 13th, September 16th and October 16th, 2007 were obtained for free at the site http://reverb.echo.nasa.gov/reverb/ in HDF (Hierarchical Data Format) and converted to GeoTIFF using the program MRT (MODIS Reprojection Tool).

To calculate the instantaneous radiation net (Rninst.) it was used SEBAL. For such, it was determined the surface albedo (α), the incident shortwave radiation (RS↓), the long wave radiation emitted by the atmosphere (RL↓) and the long wave radiation emitted by the surface (RL↑). For the complete description of the procedures used, see LIMA (2010).

The surface albedo was obtained from the reflectance bands altogether with the equation proposed by TASUMI et al. (2008).

α = 0.215 α1 + 0.215 α2 + 0.242 α3 + 0.129 α4 + 0.101 α5 + 0.062 α6 + 0.036 α7 (01)

where,

α1, α2, ..., and α7 – reflectance bands of the MOD09GA product.

The incident shortwave radiation, defined as the flow of direct and diffuse solar radiation that reaches the Earth's surface, was estimated for clear sky condition (ALLEN et al., 2002).

RS↓ = GSC . cosθ . dr . τsw (02)

where,

Gsc – solar constant (1367W.m-2);

θ – zenithal angle, obtained from the MOD07 product;

dr – inverse square of the Earth-Sun relative distance;

τsw – atmospheric transmissivity.

The long wave radiation emitted by the atmosphere towards the surface (Equation 3) was calculated by the Stefan-Boltzmann equation.

where,

εa – atmospheric emissivity (dimensionless);

σ – Stefan-Boltzmann constant (σ = 5.67x10-8 W.m .K-4);

T cold pixel – cold pixel temperature (K).

The long wave radiation emitted by the surface was achieved through the Stefan-Boltzmann equation, according to the following expression:

RL↑= ε0 . σ . Ts4 (04)

where,

ε0 – surface emissivity (dimensionless);

Ts – surface temperature (K), obtained from the MOD11A1 product.

The net radiation records the available radiant power and it is function of the components coming to and from the soil surface. This term, in its instantaneous shape, was obtained by the following expression (ALLEN et al. 2002):

where,

Rninst. – instantaneous net radiation (W.m-2).

To obtain the average net radiation occurred in a period of 24 hours (W.m-2.d-1), it was used the TEIXEIRA et al. (2009) expression mentioned by LIMA (2010).

where,

Rs24h – daily incident shortwave radiation (W.m-2.d-1);

τsw24h – daily atmospheric transmissivity (dimensionless).

The incident shortwave radiation data, from the days listed in the study, were obtained from the automatic weather station (A542) located in the city of Unaí, Minas Gerais, as observed in Figure 1. These data were used as input data in SEBAL to estimate the average net radiation occurred in a period of 24 hours. The data were obtained at the site http://www.inmet.gov.br/portal/index.php?r=estacoes/estacoesAutomaticas. The station used in this study has the following geographical coordinates: latitude 16º33'14" South, longitude 46º52'55" West and 631m of altitude, and belongs to INMET automatic stations network.

RESULTS AND DISCUSSION

The surface albedo estimated using the information of MOD09GA product (spectral reflectance of the surface) is shown in Figure 2 for the areas of the sub-basins of the Entre Ribeiros creek and Preto river. The albedo exerts a control on the amount of energy that is absorbed by the Earth's surface, acting in net radiation and in the consequent energy balance.


 





It was found some homogeneity in the comparison of the albedo maps, except for the areas located mainly in the upper Preto river region. Mostly of the thematic maps α ranged between 0.11 and 0.2 (red), but there were some areas in the upper Preto river region (Figures 2a and 2b) in which the albedo was lower, i.e., between 0.0 and 0.1. However, in some areas of that part of the Preto river basin (Figures 2c and 2d), there was an increase in the surface albedo, which ranged between 0.21 and 0.3. According to HARTMANN (1994) mentioned by LIMA (2010), the albedo for vegetated surfaces depends on the soil texture and physiological conditions of the plant canopy. Dry soils have a significantly larger albedo than those observed in wet soils, while a smooth surface has greater albedo than a rough one, since they have the same material. As seen in Table 1, the average surface albedo varied between 0.14 and 0.17, with a minimum value of 0.02 on July 14th and August 13th, and a maximum of 0.31 on August 13th and September 16th, 2007.

MENDONÇA (2007) estimated the surface albedo in the Norte Fluminense region, in the state of Rio de Janeiro (RJ), Brazil, using two methods: first, using albedo maps obtained from the MODIS product (MOD43B1) and, second, by the method proposed by TASUMI et al. (2008) through surface reflectance maps (MOD09 GHK). The author states that the differences between the albedos estimated by both methodologies can be explained by spatial and temporal resolutions in which the maps were generated. While the MOD43B1 product is generated in a resolution of 1.000m and integrated in 16 days, which tends to soften the values of albedos obtained in the period, the proposal of TASUMI et al. (2008) uses maps of surface reflectance (MOD09 GHK), generated at a resolution of 500m for specific days of satellite overpass. Based on the results obtained in the evaluation of these two methodologies, MENDONÇA (2007) chose to adopt the model proposed by TASUMI et al. (2008) for estimating the net radiation through the SEBAL algorithm. Thus, it was found the albedo values between 0.0 and 0.31, with an average of 0.18 on January 15th, 2006, between 0.0 and 0.23, with an average of 0.14 on 12th April, 2006, between 0.0 and 0.26, with an average of 0.12 on May 19th, 2006, and between 0.0 and 0.19, with an average of 0.13 on 8th July 2006.

NICÁCIO (2008) estimated the surface albedo for October 12th, 2004, in the region of Petrolina/Juazeiro, in Brazil, using the MODIS in the satellite Aqua, and noted that the albedo values were less than 13% over the São Francisco river. After the "water" class, the lowest values of albedo occurred over the region occupied by dense savanna steppe, with values between 0.13 and 0.17, while open areas with native vegetation showed values around 0.17 to 0.20. The author mentions that regions occupied by productions of irrigated fruit showed albedo values ranging especially from 0.22 to 0.25, and the highest values of albedo occurred in urbanized areas, such as the city of Petrolina, state of Pernambuco (PE), with values greater than 27%.

The results found by MENDONÇA (2007) and NICÁCIO (2008) served to compare the results of the albedo found for the two sub-basins of the Paracatu river. It will be highlighted the minimum values found by MENDONÇA (2007), because from the analysis of these results, it was concluded that the author may have set a condition at the time of processing through SEBAL, so that the minimum value of the albedo was 0.0 in different dates. Although the soil cover, the dates and time of the satellite imagery of the surface were distinct to the regions of Paracatu and Norte Fluminense, RJ, the maximum albedo of 0.31, found in the sub-basins of Paracatu, was compatible with the one from MENDONÇA (2007) on January 15th, 2006. To complement, the albedo found for part of the Preto river (yellow), in the areas circled in black (Figures 2a and 2b), is similar to the result found by NICÁCIO (2008) in the riverbed of the São Francisco river.

The instantaneous net radiation (Rninst.) estimated by SEBAL using MODIS sensor information is presented in Figure 3 for the areas of the sub-basins of the Entre Ribeiros creek and Preto river. The spatial variation of net radiation observed in thematic maps is explained by the surfaces present in the sub-basins of the Entre Ribeiros creek and Preto river (savannah, grassland, irrigated areas with different types of crops, waterways, etc.), because the surface albedo - shortwave balance modeler - varies according to the physicochemical characteristics of the surfaces and the zenithal angle.


 





None of the thematic maps can clearly show the hydrography of the sub-basins. This was due to spatial resolution of each pixel (500m×500m) that composes the map; sometimes the pixel information is the combination of different surfaces that makes up the pixel area in question. Due to the spatial resolution of MODIS, an element of the scene corresponding to a pixel of the image can include more than one type of ground cover. When a sensor observes the scene, the detected radiance is integration, called mixture of all objects contained in the scene element (AGUIAR et al., 1999).

Despite the hydrography of the sub-basins is not fully present in thematic maps, it was observed that the values of the instantaneous net radiation were high on liquid surfaces when compared to other types of surface. To illustrate this statement, there are areas circled in black (Figures 3a and 3b), which shows high values of Rn from part of the Preto river. According to LIMA et al. (2009), the trend of higher values of Rn on liquid surfaces and less on other types of surfaces can be explained by the combined effect of albedo and surface temperature, because the first one influences the balance of shortwaves and second one, the balance of long waves.

LIMA et al. (2009) complement saying that a lower surface albedo (α), situation observed on the liquid surface, favors a low reflection of shortwave radiation, thus contributing to the balance of shortwaves be larger as compared with a surface area of greater reflection, i.e., higher albedo surfaces. Whereas, a lower surface temperature (Ts), situation observed on liquid surfaces, promotes a lower balance of long waves in terms of absolute value, as compared to surfaces with higher temperatures. They conclude by saying that a lower value of α and Ts favors that Rn be higher on liquid surfaces.

Comparing the four maps of Figure 3 it is possible to see the increase in the instantaneous net radiation, especially when observing Figure 3d, with the presence of many areas with values greater than 651W.m-2, and compares it to 3a. This trend can be explained by the seasonality of the incident shortwave radiation, which varies with the solar declination. In most thematic maps Rn ranged between 451 and 650W.m-2 (red and green), but there were some areas in the upper Preto river region (Figure 3a) with the net radiation lesser than 450W.m-2 (yellow). The instantaneous net radiation average ranged between 509.41 and 643.33W.m-2, with a minimum value of 419.13W.m-2 on July 14th and a maximum of 797.35W.m-2 on October 16th, 2007, as presented in Table 1.

MENDONÇA (2007) estimated the instantaneous Rn for the Norte Fluminense region, State of Rio de Janeiro, using images from the MODIS sensor, and found values between 411.76 and 646.64W.m-2 on August 29th, 2005, 499.06 and 873.28W.m-2 on November 16th, 2005, 482.40 and 818.32W.m-2 on February 5th, 2006, and 270.04 and 438.72W.m-2 on June 15th, 2006. Although these two locations are in different latitudes, the Rn minimum of 419.13W.m-2, found in this study, was consistent with that one from MENDONÇA (2007) on August 29th, 2005, and the Rn maximum of 797.35W.m-2 found for the sub-basins of the Entre Ribeiros creek and Preto river, was compatible with the one from MENDONÇA (2007) on February 5th, 2006.

ATAÍDE (2006) estimated the instantaneous Rn for the city of Quixeré, in the state of Ceará (CE), in Brazil, using information from the MODIS sensor, aboard the Terra satellite, on four different days, and found values between 719 and 848W.m-2 on September 10th, 2005, 733 and 864W.m-2 on October 10th, 2005, 686 and 817W.m-2 on October 14th, 2005, and between 661 and 809W.m-2 on October 25th, 2005. It was found that the maximum value of instantaneous Rn of 797.35W.m-2, estimated for the sub-basins of the Entre Ribeiros creek and Preto river, was consistent with those found in the city of Quixeré, CE, on October 14th e 25th, 2005. However, the minimum value of instantaneous Rn of 419.13W.m-2, found for the Paracatu river region, was always less than those from the city of Quixeré, CE. This difference may be due to the surface albedo, because a change in this term directly affects the net radiation. It is worth noting that α depends on the angle of incidence of solar radiation and surface conditions such as soil color, moisture, coating type and stage of crop development. Another issue that must be considered to explain the difference in the minimum values of this study and those found by ATAÍDE (2006) are the methodological differences in the determination of Rn.

The results found by MENDONÇA (2007) and ATAÍDE (2006) served to compare the results of the instantaneous radiation found for the two sub-basins of the Paracatu river, since the automatic weather station (A542), located in the municipality of Unaí, MG, lacked balance radiometer. Usually, weather stations have no balance radiometers, which, due to the purchase cost, are often restricted to experimental campaigns.

In the absence of information from the net radiation, LIMA (2010) used data from incident shortwave radiation (RS↓), collected by an automatic station, to check the behavior of this component estimated using the SEBAL. LIMA (2010) states that the values of incident solar radiation estimated by SEBAL algorithm showed a good correlation (r2 = 0.92) with the values measured at the weather station, but there was a tendency to overestimate. The root-mean-square error (RMSE) was 47.00W.m-2 and the mean absolute error (MAE) was 39.36W.m-2.

The average net radiation occurred within 24 hours (Rn24h) estimated by the SEBAL using information from the MODIS sensor is presented in Figure 4 for the areas of the sub-basins of the Entre Ribeiros creek and Preto river. To determine this term, it was necessary the incident shortwave radiation data, obtained in the automatic weather station in the city of Unaí, MG, and the atmospheric transmissivity data presented in Table 2.


 





Comparing the thematic maps there has been an increase in the average net radiation for 24 hours, especially when it is observed in Figure 4d. This behavior is explained mainly by increasing the daily incident shortwave radiation, as observed in Table 2 that over time is a function of the solar declination. However, the daily atmospheric transmissivity, ranging between 0.66 in 09/16 and 0.71 in 08/13, had little influence on the increase in average net radiation for 24 hours.

Thematic maps of Rn24h, except for some areas, showed homogeneous conditions. On July 14th (Figure 4a), although mostly of the sub-basins of the Entre Ribeiros creek and Preto river present the Rn24h less than 100W.m-2.d-1 (yellow), some areas showed the Rn24h between 101 and 150W.m-2.d-1, which is the case occurred on the Entre Ribeiros creek and São Pedro, shown by the area circled in black. In 4b and 4c, the predominance of Rn24h between 101 and 150W.m-2.d-1 was higher, with the exception of some areas in the middle and upper Preto river region (Figure 4c). On October 16th the Rn24h predominant range was higher than the verified in previous maps, i.e., Rn24h ranged between 151 and 200W.m-2.d-1 (green). As seen in Table 1, the average net radiation for 24 hours was between 95.99 and 168.07W.m-2.d-1, with a minimum value of 67.75W.m-2.d-1 on July 14th and a maximum of 202.73W.m-2.d-1 on October 16th, 2007.

OLIVEIRA et al. (2006) conducted a study in an area of native savanna vegetation in the city of Petrolina, in the state of Pernambuco, Brazil. These authors found that the seasonal variation of radiation accompanies the seasonal variation of incident shortwave radiation. The minimum values of net radiation were observed in July, whose daily averages did not exceed 150W.m-2, reaching values slightly above 200W.m-2 in February. The sub-basins of the Entre Ribeiros creek and Preto river have various types of surfaces, such as savannah, grasslands, streams and irrigated areas with different crops, and this may be the reason for the minimum value of 67.75W.m-2.d-1, found in the sub-basins in the study of Paracatu be lower than the values found by OLIVEIRA et al. (2006).

The knowledge of the radiation is essential for estimating water loss by vegetated surfaces, and it is necessary for the planning of agricultural activities. In this context, the results of instantaneous and average radiation for 24 hours are important. In the absence of such information the SEBAL algorithm can determine them, since the results were consistent with various locations, like those cited in the literature.

Many areas of Brazil do not have or have disabilities of automatic weather stations with balance radiometers. The sub-basins of the Entre Ribeiros creek and Preto river, which together have a considerable area, with approximately 15.000km2, and have only one INMET automatic station, depict well this situation. FIETZ & FISCH (2009) complement mentioning that most of the weather stations in Brazil do not have the instruments to measure the net radiation, because the radiometers balance present high cost and difficulties in maintenance.

CONCLUSIONS

The highest values of average net radiation and instantaneous net radiation for 24 hours occurred on liquid surfaces, and lower values on other types of surfaces, such as savannah, pasture and irrigated areas with different crops and stages of development.

The results of net radiation found by the SEBAL algorithm are important because it can estimate them when there is deficiency of automatic weather stations, especially when there is no radiometers balance. This condition reflects the sub-basins of the Entre Ribeiros creek and Preto river, which together have a considerable area and only one automatic station, that belongs to INMET, without a radiometer balance.

Recebido pelo Conselho Editorial em: 15-3-2011

Aprovado pelo Conselho Editorial em: 24-8-2012

ERRATA

p.1189 e 1190, onde se lê:

"MENDONÇA (2007) estimated the instantaneous Rn for the Norte Fluminense region, State of Rio de Janeiro, using images from the MODIS sensor, and found values between 410 and 650W.m-2 on August 29th, 2005, 500 and 870W.m-2 on November 16th, 2005, 480 and 820W.m-2 on February 5th, 2006, and 270 and 440W.m-2 on June 15th, 2006. Although these two locations are in different latitudes, the Rn minimum of 419.13W.m-2, found in this study, was consistent with that one from MENDONÇA (2007) on August 29th, 2005, and the Rn maximum of 797.35W.m-2 found for the sub-basins of the Entre Ribeiros creek and Preto river, was compatible with the one from MENDONÇA (2007) on February 5th, 2006."

Leia-se:

"MENDONÇA (2007) estimated the instantaneous Rn for the Norte Fluminense region, State of Rio de Janeiro, using images from the MODIS sensor, and found values between 411.76 and 646.64W.m-2 on August 29th, 2005, 499.06 and 873.28W.m-2 on November 16th, 2005, 482.40 and 818.32W.m-2 on February 5th, 2006, and 270.04 and 438.72W.m-2 on June 15th, 2006. Although these two locations are in different latitudes, the Rn minimum of 419.13W.m-2, found in this study, was consistent with that one from MENDONÇA (2007) on August 29th, 2005, and the Rn maximum of 797.35W.m-2 found for the sub-basins of the Entre Ribeiros creek and Preto river, was compatible with the one from MENDONÇA (2007) on February 5th, 2006."

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Publication Dates

  • Publication in this collection
    15 Mar 2013
  • Date of issue
    Dec 2012

History

  • Received
    15 Mar 2011
  • Accepted
    24 Aug 2012
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