Microsoft Word - 3-Agra_33068.docx


1155 
Original Article 

Biosci. J., Uberlândia, v. 32, n. 5, p. 1155-1164, Sept./Oct. 2016 

FERTILIZERS WITH COATED UREA IN UPLAND RICE PRODUCTION 
AND NITROGEN APPARENT RECOVERY  

 

DOSES DE FERTILIZANTES COM UREIA REVESTIDA NA PRODUÇÃO DE ARROZ 
DE TERRAS ALTAS E RECUPERAÇÃO APARENTE DE NITROGÊNIO 

 

Maria da Conceição Santana CARVALHO¹; Adriano Stephan NASCENTE¹;  
Paulo César TEIXEIRA² 

1. Pesquisador, Doutor, Embrapa Arroz e Feijão, Santo Antônio de Goiás, GO, Brasil. adriano.nascente@embrapa.br; 2. Pesquisador, 
Doutor, Embrapa Solos, Rio de Janeiro, RJ, Brasil 

 
ABSTRACT: Urea is the most used N fertilizer for upland rice, however, a great percentage of N loss can occur 

with the use of this fertilizer. The use of products that provide reduction of N loss for urea fertilizers can contribute to 
increase N use efficiency. The objective of this study was to determine the effect of N rates applied in the form of coated 
urea in the content and accumulation of N in dry biomass, apparent recovery of nitrogen and grain yield of upland rice. 
The experimental design was a randomized complete blocks arranged in a 4 x 3 + 1 factorial scheme. The treatments 
consisted of four sources of N fertilizer [1. Common urea; 2. Polymer-coated urea for slow release of N (PCU); 3. urea 
with the urease inhibitor N-(n-Butyl) thiophosphoric triamide (NBPT); and 4. urea coated with copper sulfate and boric 
acid as urease inhibitors (UCCB)], with three fertilization rates (30, 60 and 90 kg ha-1 of N). In addition, we included a 
control treatment without N application. Coated urea did not provide increases in rice grain yield in relation to common 
urea. The increasing amount of N resulted in significant increases in rice grain yield (from 3217 to 5548 kg ha-1, 2010/11, 
and from 3392 to 4560 kg ha-1, 2011/12). The apparent nitrogen recovery rate decreased with the increase in N applied 
doses.  
 

KEYWORDS: N fertilizer. Oryza sativa. Polymer-coated urea. Slow release fertilizers. Urease inhibitor. 
 
INTRODUCTION 
 

Rice is part of the diet of half the world 
population (LADHA; KUMAR, 2011). This cereal 
is mostly grown in Asia under irrigation by flooding 
(PRASAD, 2011). However, the reduced 
availability of water resources for irrigation of the 
crop, due to increased industrial and human 
consumption, has demanded the search for 
alternatives that enable rice cultivation with greater 
water saving. As an alternative, we have the 
cultivation of rice in the upland ecosystem, which 
can be sprinkle irrigated or rainfed, depending on 
rainwater distribution (CRUSCIOL et al., 2013; 
NASCENTE et al., 2013). In this ecosystem, 
fertilization management, mainly with N, can 
provide significant increases in rice grain yield 
(FAGERIA, 2014). 

Nitrogen is one of the most dynamic 
nutrients in the soil (MORO et al., 2013; 
NASCENTE et al., 2014). However, the low 
efficiency of the agronomical use of this nutrient, 
observed in most agricultural systems, is the result, 
in part, of losses associated with nitrification of N, 
i.e., N losses by leaching and denitrification of N-
NO3

- (NASCENTE et al., 2012; FAGERIA, 2014). 
The efficiency of N use and loss processes in the 
soil-plant system have not only economic 
consequences but also environmental ones, 

especially when N oxides are emitted into the 
atmosphere. Nitrous oxide (N2O) has been receiving 
increased attention, mainly because of its 
contribution to the greenhouse effect and the 
depletion of the ozone layer (CHIEN et al., 2009). 
Thus, the development of technologies that increase 
N use efficiency could help to reduce losses and 
contamination of water (nitrate) and the atmosphere 
(nitrous oxide). 

In Brazil, the annual consumption of N-
fertilizers in 2013 was 3.9 million tons, and of this 
total 1.8 million tons (46.15%) was urea (IPNI, 
2014), which is the most used N fertilizer. This 
fertilizer has a number of advantages, such as: lower 
price per unit of N; high concentration of N, which 
reduces the cost of transportation and application; 
high solubility; lower corrosivity; compatibility with 
a large number of other fertilizers and pesticides; 
and high rate of foliar absorption (FARIA et al., 
2013, 2014). However, the main disadvantage of 
urea is the high possibility of loss by volatilization 
of NH3. When applied to the soil, urea suffers 
enzymatic hydrolysis, thus releasing ammonia 
(NASCENTE et al., 2012; FAGERIA, 2014). 

Various modifications have been made in 
fertilizers containing urea to reduce losses by 
volatilization and to increase their use efficiency. 
These modifications include the addition of acidic 
products (BREMNER; DOUGLAS, 1971) and the 

Received: 02/02/16 
Accepted: 06//06/16 



1156 
Fertilizers with coated urea…  CARVALHO, M. C. S. et al. 

Biosci. J., Uberlândia, v. 32, n. 5, p. 1155-1164, Sept./Oct. 2016 

production of fertilizers with solubility controlled by 
means of resins or polymers or even elemental 
sulfur cover (GOULD et al., 1986; FANSURI et al., 
2008; CIVARDI et al., 2011; MORO et al., 2013). 

As examples of products that can be used to 
reduce N loss in the agricultural systems, we have 
polymer-coated urea (PCU), which provide 
reasonable/good control over the rate of N release 
(TRENKEL, 2010). The N-(n-Butyl) thiophosphoric 
triamide (NBPT) is one of the most thoroughly 
studied urease inhibitor (KISS; SIMIHAIAN, 2002). 
The organo-phosphorus compounds are structural 
analogues of urea and are some of the most effective 
inhibitors of urease activity, blocking the active site 
of the enzyme (WATSON et al., 1998; TRENKEL, 
2010). Another product is urea coated with boric 
acid and copper sulfate, which provide positive 
effects in reducing N volatilization losses 
(FANSURI et al., 2008). The acidifying effect, the 
similar structural characteristics of boric acid with 
urea and the defensive effect of B and Cu from the 
soil microorganisms may deviate part of the urease 
activity towards boric acid, consequently decreasing 
N volatilization losses (FARIA et al., 2013). 

There are still few studies in the literature 
that demonstrate the effects of applying fertilizer 
containing urea coated with polymer of slow 
release, urease inhibitor or coated with 
micronutrients for upland rice crop. We have the 

hypothesis that the use of coated urea allows better 
apparent recovery of nitrogen than the common 
urea.  

The aim of this study was to determine the 
effect of N rates applied in the form of coated urea 
in the content and accumulation of N in dry 
biomass, apparent recovery of nitrogen and grain 
yield of upland rice.  
 
MATERIAL AND METHODS 
 

The field experiments were conducted for 
two growing seasons (2010/2011 and 2011/2012) at 
Capivara Farm, located in the city of Santo Antônio 
de Goiás, GO, Brazil. The geographical coordinates 
of the site are 16° 28’ 00” S, 49º 17’ 00” W. The 
altitude is 823 m. The climate is tropical savanna, 
considered Aw according to the Köppen’s 
classification. There are two well-defined seasons: 
usually, the dry season extends from May to 
September (autumn/winter) and the rainy season 
from October to April (spring/summer). The historic 
average annual rainfall ranges from 1500 to 1700 
mm. The historic average annual temperature is 22.7 
°C, ranging annually from 14.2 °C to 34.8 °C. 
Additionally, the average daily temperature and 
precipitation during the experiment were monitored 
(Figure 1). 

 
Figure 1. Temperature and rainfall in the experimental area during the trial (Nov. 2010 to Apr. 2011 and Nov. 

2011 to Apr. 2012). Arrows means time that was done N topdressing fertilization. 
 



1157 
Fertilizers with coated urea…  CARVALHO, M. C. S. et al. 

Biosci. J., Uberlândia, v. 32, n. 5, p. 1155-1164, Sept./Oct. 2016 

The soil was classified as a clay-textured 
Typic Acrustox (USDA, 1999). Prior to the 
experiment chemical characteristics of the soil were 
determined at depth of 0-0.20 m to characterize the 
soil in the experimental area. In the area pH was 5.9 
(CaCl2), organic matter 22 mg dm

-3, Ca 4.3 cmolc 
dm-3, Mg 1.4 cmolc dm

-3, Al 0.0 cmolc dm
-3, H + Al 

2.4 cmolc dm
-3, K 169 mg dm-3, P 7 mg dm-3, S-SO4 

3 mg dm-3, B 0.2 mg dm-3, Cu 1.3 mg dm-3, Fe 35 
mg dm-3, Mn 62 mg dm-3, and Zn 3.6 mg dm-3. The 
soil analysis was performed according to Claessen 
(1997).  

The experimental area has been cultivated in 
a crop-livestock no-tillage system (NTS) for seven 
consecutive years, which consists of following the 
crop rotation program with soybean (summer), 
followed by upland rice (summer) and the common 
bean (winter), followed by corn and Brachiaria 
(summer), followed by two years of grazing pasture. 
The installation of the experiments was conducted 
in plots in which upland rice was the crop to be 
grown following the crop rotation program. 

The experimental design was a randomized 
complete blocks arranged in a 4 x 3 + 1 factorial 
scheme with four replications. The treatments 
consisted of four sources of N fertilizer [1. common 
urea; 2. Polymer-coated urea for slow release of N 
(PCU); 3. urea with the urease inhibitor N-(n-Butyl) 
thiophosphoric triamide (NBPT); and 4. urea coated 
with copper sulfate and boric acid as urease 
inhibitors (UCCB)] with three fertilization rates (30, 
60 and 90 kg ha-1 of N). In addition, we included a 
control treatment without N application. The plots 
consisted of 10 eight-meter-long rows, spaced 0.35 
m apart. The useful area of each plot was formed by 
the six central meters of the six central rows.  

N application was split and 50% of the N 
rate was applied right after upland rice seedling 
emergence (on December 10th, 2010, and November 
23th, 2011) and 50% at full tillering stage (on 
January 7th, 2011, and December 22th, 2011). The 
fertilizer was applied by hand in strips, 0.10 m apart 
from the rice rows.  

Approximately 15 days before sowing, the 
experimental area was desiccated with glyphosate + 
2,4D. The base fertilization, to be applied in the 
sowing furrows, was calculated according to the 
soil’s chemical characteristics and the 
recommendations of Sousa and Lobato (2003). The 
fertilizer consisted of 17.50 kg ha-1 of N (urea), 105 
kg ha-1 of P2O5 (triple superphosphate) and 52.5 kg 
ha-1 of K2O (potassium chloride), and it was applied 
together with sowing.  

The sowing was performed mechanically, 
using 80 kg of rice seeds per hectare from a mutant 

line 07SEQCL441 CL, which is derived from a 
Primavera variety and is resistant to the Imazapyr + 
Imazapic herbicide. The seed was sowed on 
December 4th, 2010, and November 17th, 2011. 
Before sowing, seeds were treated with Carboxin + 
Tiram (250 mL 100 kg-1 seeds) + Fipronil (100 mL 
100 kg-1 seeds). Weed control was accomplished 
using Imazapyr + Imazapic herbicide at 16 (100 g 
ha-1) and 26 (50 g ha-1) days after crop emergence. 
Other cultural practices were performed according 
to the recommendations for rice crops to keep the 
area free of diseases and insects. Seeds emergence 
occurred 6 and 5 days for the first and second 
growing season, respectively. 

Upland rice plants were sampled when they 
reached full flowering stage. Plants were sectioned 
to separate shoots from roots. The shoots were 
washed in water and then dried in an oven with 
forced air circulation at 65 °C, then weighed to 
determine shoot dry mass content. Sub-samples of 
shoots were collected to determine the 
concentrations of N following the method of 
Malavolta et al. (1997). The N content was 
determined using the data on the shoot dry mass and 
nutrient concentration. Apparent recovery of 
nitrogen (ARN) was calculated by the formula 
(DOBERMANN, 2005):  
ARN = [(UN – U0)/ FN]*100                        (1) 

In which: 
UN – total plant N uptake in aboveground 

biomass at maturity (kg ha-1) in a plot that received 
N 

U0 – the total N uptake in aboveground 
biomass at maturity (kg ha-1) in a plot that received 
no N  

FN – amount of (fertilizer) N applied (kg ha-1) 
Plots were evaluated concerning: number of 

tillering, determined by measuring plants in 1.0 m2 
in the useful area of each plot at the time when the 
crop was at the phenological stage of pasty grains; 
number of panicles, determined by counting the 
number of panicles in 1.0 m2 in the useful area of 
each plot; percentage of full grains, evaluated 
randomly, collecting and counting the number of 
full grains and dividing by the total number of 
grains and multiplying by 100 in two samples of 
100 grains from each plot; and grain yield, 
determined by weighing the harvested grain of each 
plot, corrected to 13% of water content and 
converted to kg ha-1. 

An analysis of variance and F test were 
performed for all variables. Source and dose of 
fertilizer were considered fixed effects. Blocks, 
years and interactions were considered random 
effects. A comparison of means was performed with 



1158 
Fertilizers with coated urea…  CARVALHO, M. C. S. et al. 

Biosci. J., Uberlândia, v. 32, n. 5, p. 1155-1164, Sept./Oct. 2016 

Tukey’s test (p≤ 0.05) for source of fertilizer. To 
compare the sources with the control treatment, we 
used Dunnett’s test at p≤ 0.05. Regression analysis 
was used for quantitative data (fertilizer doses), 
which we included the control treatment (0 of N). 
Dunnett’s test was performed at a significance of p≤ 
0.05 to compare the 0 nitrogen dose with each 
source of nitrogen treatment. We performed these 
analyses using the SAS statistical software (SAS 
Institute, 1999). 
 
 
 
 
 
 

RESULTS 
 
In the 2010/11 growing season, shoot dry 

biomass (SDB), number of tillers m-2, number of 
panicles m-2, percentage of full grains, grain yield, N 
concentration, N content and N apparent recovery 
were significantly influenced by the addition of N 
by all sources of N (common urea, urea polymer, 
urea NBPT and Urea CuB), which differed from the 
control (0 N) (Table 1). However, N concentration 
had similar values for control and the N source Urea 
CuB. Nitrogen rates affected the number of tiller, 
panicle density, shoot dry biomass, grain yield, N 
content in rice shoots and N apparent recovery. 
Grain yield and N content were higher with 
common urea and differed from the Urea CuB.  

 
Table 1. Shoot dry biomass (SDB), number of tillers m-2 (NT), number of panicles m-2 (PAN), percentage of 

full grains (%GRAIN), grain yield (GY), N concentration in shoots (NCONC), N content (NCONT) 
and N apparent recovery (NAR) for upland rice in relation to source of N fertilizer and dose in the 
2010/11growing season. 

Factors SDB NT PAN %GRAIN 
Source of N fertilizer kg ha-1 number number % 
Urea 4957+ 229+ 204+ 73.99+ 
Urea polymer 4858+ 239+ 216+ 76.48+ 
Urea NBPT 4750+ 242+ 219+ 72.61+ 
Urea CuB 4444+ 235+ 212+ 77.71+ 
Control 3217 216  186 67.82 
Factors ANOVA – Probability of F test 
Source of N fertilizer (SNF) 0.3099 0.7647 0.7468 0.4012 
N rates (NR) <0.001 0.0354 0.0436 0.8386 
SNF x NR 0.0664 0.1003 0.1868 0.8677 
Source of N fertilizer GY NCONC NCONT NAR 
 kg ha-1 g kg-1 kg ha-1 % 
Urea 3777 a+ 18.73+ 92.90 a+ 79+ 
Urea polymer 3629 ab+ 18.29+ 88.58 ab+ 68+ 
Urea NBPT 3687 ab+ 18.42+ 88.25 ab+ 54+ 
Urea CuB 3181 b+ 17.13 76.61 b+ 37+  
Control 2329 17.50  56.48 0.00 
Factors ANOVA – Probability of F test 
Source of N fertilizer (SNF) 0.0238 0.3607 0.0475 0.2750 
N rates (NR) 0.0050 0.5712 <0.001 0.0365 
SNF x NR 0.7136 0.9893 0.2867 0.4180 
¹Means followed by the same letter do not differ by the Tukey’s test for p<0.05. +means followed by this symbol differ from the control 
treatment (no N application) by the Dunnet’s test for p<0.05.  
 

The number of tiller increased from 216 m-2 
at the control treatment to 244 tiller m-2 at the 90 kg 
N ha-1 (Figure 2A). Panicle density increased from 
186 panicles m-2 at 0 N to 218 panicles m-2 at the 90 
kg N ha-1 (Figure 2B). Shoot dry mass increased 
from 3217 kg ha-1 at control treatment to 5548 kg 
ha-1 at 90 kg N ha-1 (Figure 2C). Grain yield 
increased from 2449 kg ha-1 at control treatment to 
3887 kg ha-1 at 90 kg N ha-1 (Figure 2D). Nitrogen 

content in the rice shoots increased from 56.48 kg 
ha-1 at 0 N to 101.17 kg ha-1 at 90 kg N ha-1 (Figure 
2E). Nitrogen apparent recovery reduced from 77% 
at 30 kg N ha-1 to 50% at 90 kg N ha-1. The increase 
in the number of tillers, panicle density and grain 
yield were quadratic in nature by the application of 
N rates (Table 1). On the other hand, shoot dry 
biomass, N content in rice shoots and N apparent 
recovery fitted to linear equations. 



1159 
Fertilizers with coated urea…  CARVALHO, M. C. S. et al. 

Biosci. J., Uberlândia, v. 32, n. 5, p. 1155-1164, Sept./Oct. 2016 

 
Figure 2. Number of tillers m-2 (A), number of panicles m-2 (B), shoot dry biomass (C), grain yield (D), N 

concentration in the shoots (E) and N apparent recovery (F) of upland rice plant as a function of N 
rates. 2010/2011 growing season. 

 
In the 2011/12 growing season, shoot dry 

biomass, number of tillers, number of panicles, 
grain yield, N content and N apparent recovery were 
significantly influenced by the addition of N by all 
sources of N (common urea, urea polymer, urea 
NBPT and urea CuB), which differed from the 
control (0 N) (Table 2). The number of tillers was 
higher with the urea NBPT source and differed from 
the urea CuB source. Common urea provided the 

highest values of percentage of full grains and 
differed from the urea polymer source. 

Nitrogen rates affected shoot dry biomass, 
number of tillers, panicle density, percentage of full 
grains, grain yield, N content in rice shoots and N 
apparent recovery (Figure 3). Number of tillers 
increased from 207 tillers m-2 at the control 
treatment to 293 tillers m-2 at the 87 kg N ha-1 
(Figure 3A).  

 
Table 2. Shoot dry biomass (SDB), number of tillers m-2 (NT), number of panicles m-2 (PAN), percentage of 

full grains (%GRAIN), grain yield (GY), N concentration in shoots (NCONC), N content (NCONT) 
and N use efficiency (NUE) for upland rice in relation to source of N fertilizer and dose in the 
2011/12 growing season. 

Factors SDB NT PAN %GRAIN 
Source of N fertilizer kg ha-1 number number % 
Urea 6333+ 265 ab 255+ 76.59 a 
Urea polymer 6288+ 294 ab+ 272+ 68.59 b 
Urea NBPT 6598+ 314 a+ 282+ 71.66 ab 
Urea CuB 6125+ 250 b+ 245+ 74.43 ab 
Control 3858 207  199  72.00 
Factors ANOVA – Probability of F test 
Source of N fertilizer (SNF) 0.6189 0.0275 0.0768 0.0177 
N rates (NR) 0.0416 0.0354 0.0138 0.0065 
SNF x NR 0.7104 0.4873 0.1020 0.0736 



1160 
Fertilizers with coated urea…  CARVALHO, M. C. S. et al. 

Biosci. J., Uberlândia, v. 32, n. 5, p. 1155-1164, Sept./Oct. 2016 

Source of N fertilizer GY NCONC NCONT NAR 
 kg ha-1 g kg-1 kg ha-1  
Urea 4335+ 15.62 98.97+ 77+ 

Urea polymer 4414+ 16.80  104.19+ 88+ 
Urea NBPT 4195+ 16.44  108.21+ 91+ 
Urea CuB 4355+ 16.12  98.18+ 77+ 
Control 3392  15.14  58.64  0 
Factors ANOVA – Probability of F test 
Source of N fertilizer (SNF) 0.7832 0.0927 0.6154 0.5858 
N rates (NR) 0.0428 0.5102 0.0089 0.0009 
SNF x NR 0.4436 0.6922 0.2378 0.3436 

¹Means followed by the same letter do not differ by the Tukey’s test for p<0.05. +means followed by this symbol differ from the control 
treatment (no N application) by the Dunnet’s test for p<0.05.  
 

Panicle density increased from 199 panicles 
m-2 at 0 N to 273 panicles m-2 at the 81 kg N ha-1 
(Figure 3B). Percentage of full grains ranged from 
69% at 90 kg N ha-1 to 76% at 30 kg N ha-1 (Figure 
3C). Shoot dry biomass increased from 3921 kg ha-
1 at control treatment to 6749 kg ha-1 at 76 kg N ha-
1 (Figure 3D). Grain yield increased from 3390 kg 
ha-1 at control treatment to 4560 kg ha-1 at 84 kg N 
ha-1 (Figure 3E). Nitrogen content in the rice shoots 

increased from 60.2 g kg-1 at 0 N to 109.68 kg ha-1 
at 86.4 kg N ha-1 (Figure 3F). Nitrogen apparent 
recovery reduced from 119% at 30 kg N ha-1 to 
57% at 90 kg N ha-1 (Figure 3G). The increase in 
shoot dry biomass, number of tillers, panicle 
density, percentage of full grains, grain yield, and 
N content in rice shoots were quadratic in nature by 
the application of N rates, and N apparent recovery 
was linear (Table 2). 

 
Figure 3. Number of tillers m-2 (A), number of panicles m-2 (B), percentage of full grains (C), shoot dry 

biomass (D), grain yield (E), N content in the shoots (F) and N apparent recovery (G) of upland rice 
plant as a function of N rates. 2011/2012 growing season. 

 



1161 
Fertilizers with coated urea…  CARVALHO, M. C. S. et al. 

Biosci. J., Uberlândia, v. 32, n. 5, p. 1155-1164, Sept./Oct. 2016 

DISCUSSION 
 

In the experiments conducted in the years 
2010/11 and 2011/12, the use of common urea did 
not provide lower values for the studied variables 
than other sources of nitrogen. By contrast, in the 
2010/11 growing season, grain yield and N content 
in rice plants from treatment with common urea 
resulted in high values that differed from the CuB 
urea source. This fact shows that the coated urea 
sources behave similarly to common urea. Related 
results were obtained by Fageria and Carvalho 
(2014) with the rice crop, Prando et al. (2013, 
2012a, 2012b) working with wheat, and Silva et al. 
(2012) with maize. Thus, it appears that under the 
conditions of this study, the changes made in urea, 
which aimed at increasing their efficiency, were not 
effective in providing higher rice grain yields in the 
two years evaluated, since the common urea yielded 
similar results to the other sources.  

A possible explanation for this lack of 
results was the rains that occurred shortly after the 
application of the nitrogen fertilizers (Figure 1). In 
the 2010/11 growing season, after the first nitrogen 
fertilization, at the same day, it rained 14.1 mm, and 
more 3.2 mm in the other day. Two days after the 
second nitrogen fertilization, it rained 6.2 mm and 
21.6 after fertilization. In the 2011/12 growing 
season, soon after the first nitrogen fertilization, at 
the same day, it rained 8.6 mm and in the next day it 
rained more 21.8 mm. In the day after the second 
nitrogen fertilization, it rained 3.8 mm, and 22 mm 
two days after the fertilization. This rain condition 
up to three days after nitrogen fertilization with urea 
is considered ideal to obtain better efficiency of N 
applied at topdressing, since N losses are minimal 
(Prando et al., 2013; Fageria, 2014) regardless of the 
source or form of the nitrogen fertilizer. Thus, for 
the conditions of our study (i.e., rain incorporating 
urea), the choice of what source of N would be used 
will depend of the price. In this case, common urea 
is advantageous over the other nitrogenous 
fertilizers tested. Likewise, Fageria and Carvalho 
(2014) found no differences in rice when using 
common urea and urea coated with polymer. 

The use of increasing nitrogen doses 
affected most variables providing increases in the 
shoot dry biomass, tiller number, panicle number, 

grain yield and N content in rice leaves. Similarly, 
Fageria (2009), Fageria et al. (2010) and Fageria et 
al. (2011a; 2011b) also reported increased 
production of grain yield and yield components of 
upland rice by applying N in Brazilian Oxisols. 
Nitrogen is an important nutrient in crop 
development, and the use of nitrogen fertilizer in 
rice is directly related to increased crop productivity 
(FAGERIA et al., 2011b; FAGERIA, 2014). 

Regarding apparent recovery of N, we 
found that with increasing N rates, reduction of 
nutrient recovery rate has occurred (Figures 2F and 
3G). Corroborating these results, Viana et al. (2011) 
also reported a reduction in nutrient utilization with 
increasing doses of N. This happened because the 
increase of N by fertilization could increase N loss 
and reduces its efficiency. Lara-Cabezas (2011) 
added that nitrogen use efficiency by crops is 
affected by several factors, and the recovered 
nutrient can be used for the following crop. 

Based on our results, it appears that the 
application of N increases crop yield. However, the 
sources of this nutrient do not affect upland rice 
grain when rains occur soon after application of urea 
fertilizer. Prando et al. (2013) reported that when it 
occurred nine days without rainfall after application 
of various sources of coated urea, compared to the 
common urea, a difference among the N sources 
regarding N loss was observed. It occurred because 
of hydrolysis of urea on the surface and hence loss 
by NH3 volatilization. Even so, the authors observed 
no differences in grain yield, probably because this 
urea N loss by volatilization was not sufficient to 
result in differences in performance of wheat. Thus, 
for these authors, the use of coated urea appears 
feasible only in places with risk of dry spells greater 
than nine days after the completion of nitrogen 
topdressing. 
 
CONCLUSIONS 
 

Coated urea did not provide increases in rice 
grain yield in relation to common urea; 
 The increasing amount of N applied resulted 
in significant increases in the upland rice grain 
yield; 

Apparent N recovery rate decreased with the 
increase in N applied doses. 

 
 

RESUMO: A ureia é o fertilizante nitrogenado mais utilizado para o arroz de terras altas, no entanto, esse 
fertilizante tem grande percentual de perda de N. O uso de produtos que proporcionam redução da perda de N em 
fertilizantes com ureia pode contribuir para aumentar a eficiência de uso do nitrogênio. O objetivo deste estudo foi 
determinar o efeito de doses de N aplicadas na forma de ureia encapsulada no teor e acúmulo de N na biomassa seca, 
recuperação aparente de nitrogênio e produtividade de grãos de arroz de terras altas. O delineamento experimental foi em 



1162 
Fertilizers with coated urea…  CARVALHO, M. C. S. et al. 

Biosci. J., Uberlândia, v. 32, n. 5, p. 1155-1164, Sept./Oct. 2016 

blocos ao acaso no esquema fatorial 4 x 3 + 1. Os tratamentos consistiram de quatro fontes de N fertilizante [1. ureia 
tradicional; 2. Polímero de ureia revestida para liberação lenta de N (PCU); 3. ureia com o inibidor de urease N- (n-butil) 
triamida tiofosfórico (NBPT); e 4. ureia revestida com sulfato de cobre e ácido bórico como inibidores de urease (UCCB)], 
com três doses de fertilizante (30, 60 e 90 kg ha-1 de N). Além disso, incluímos uma testemunha sem aplicação de N. Ureia 
revestida não forneceu aumentos no rendimento de grãos de arroz em relação à ureia comum. O aumento da quantidade de 
N resultou em aumentos significativos no rendimento de grãos de arroz (de 3217 para 5548 kg ha-1, 2010/11, e de 3392 
para 4560 kg ha-1, 2011/12). A taxa de recuperação aparente de nitrogênio diminuiu com o aumento das doses aplicadas de 
N.  

 
PALAVRAS-CHAVE: Fertilizantes N. Oryza sativa. Polímero revestido de ureia. Fertilizantes de liberação 

lenta. Inibidor de urease. 
 
 
REFERENCES 
 
BREMNER, J. M.; DOUGLAS, L. A. Inhibition of urease activity in soils. Soil Biology and Biochemistry, 
Amsterdam, v. 3, p. 297–307, 1971. http://dx.doi.org/10.1016/0038-0717(71)90039-3 
 
CHIEN, S. H.; PROCHNOW, L. I.; CANTARELLA, H. Recent developments of fertilizer production and use 
to improve nutrient efficiency and minimize environmental impacts. Advances in Agronomy, San Diego, v. 
102, p. 261-316, 2009. http://dx.doi.org/10.1016/s0065-2113(09)01008-6 
 
CIVARDI, E. A.; SILVEIRA NETO, A. N.; RAGAGNIN, V. A.; GODOY, E. R.; BROD, E. Slow-release urea 
applied to surface and regular urea incorporated to soil on maize yield. Pesquisa Agropecuária Tropical, 
Goiânia, v. 41, p. 52-59, 2011. 
 
CLAESSEN, M. E. C. Manual de Métodos de Análise de Solos, 2. ed. Rio de Janeiro: Embrapa Solos, 1997. 
212 p. 
 
CRUSCIOL, C. A. C., SORATTO, R. P.; NASCENTE, A. S.; ARF, O. Root  distribution, nutrient uptake, and 
yield of two upland rice cultivars under two water regimes. Agronomy Journal, Madison, v. 105, p. 237-247, 
2013. http://dx.doi.org/10.2134/agronj2012.0298 
 
DOBERMANN, A. R. Nitrogen Use Efficiency - State of the Art. Lincoln: University of Nebraska, 2005. 16p. 
 
FAGERIA, N. K. Nitrogen management in crop production. Boca Raton: CRC Press, 2014. 399 p. 
http://dx.doi.org/10.1201/b17101 
 
FAGERIA, N. K. The Use of Nutrients in Crop Plants. Boca Raton: CRC Press, 2009. 419 p. 
 
FAGERIA, N. K.; MOREIRA, A.; COELHO, A. M. Yield and yield components of upland rice as influenced 
by nitrogen sources. Journal of Plant Nutrition, New York, v. 34, p. 361-370, 2011b. 
http://dx.doi.org/10.1080/01904167.2011.536878 
 
FAGERIA, N. K.; MORAIS, O. P.; SANTOS, A. B. Nitrogen use efficiency in upland rice genotypes. Journal 
of Plant Nutrition, v. 33, p. 1696-1711, 2010. http://dx.doi.org/10.1080/01904167.2010.496892 
 
FAGERIA, N. K.; BALIGAR, V. C.; JONES, C. A. Growth and mineral nutrition of field crops. 3. ed. Boca 
Raton: CRC Press, 2011a. 586 p. 
 
FAGERIA, N. K.; CARVALHO, M. C. S. Comparison of conventional and polymer-coated urea as nitrogen 
sources for lowland rice production. Journal of Plant Nutrition, New York, v. 37, p. 1358-1371, 2014. 
http://dx.doi.org/10.1080/01904167.2014.888736 
 



1163 
Fertilizers with coated urea…  CARVALHO, M. C. S. et al. 

Biosci. J., Uberlândia, v. 32, n. 5, p. 1155-1164, Sept./Oct. 2016 

FANSURI, H.; PRITCHARD, D.; ZHANG, D. Manufacture of Low-grade zeolites from fly ash for 
fertilizer applications. Curtin: Curtin University of Technology, Australia, Cooperative Research Center for 
Coal in Sustainable Development, 2008. 98 p. (Research Report n. 91). 
 
FARIA, L. A.; NASCIMENTO, C. A. C.; VITTI, G. C.; LUZ, P. H. C., GUEDES, E. M. S. Loss of ammonia 
from nitrogen fertilizers applied to maize and soybean straw. Revista Brasileira de Ciência do Solo, Viçosa, 
v. 37, p. 969-975, 2013. 
 
FARIA, L. A.; NASCIMENTO, C. A. C.; VENTURA, B. P.; FLORIM, G. P. LUZ, P. H. C. VITTI, G. C. 
Hygroscopicity and ammonia volatilization losses from nitrogen sources in coated urea. Revista Brasileira de 
Ciência do Solo, Viçosa, v. 38, p. 942-948, 2014. 
 
GOULD, W. D.; HAGEDORN, C. MCCREADY, R. G. L. Urea transformation and fertilizer efficiency in soil. 
Advances in Agronomy, San Diego, v. 40, p. 209-238, 1986. http://dx.doi.org/10.1016/S0065-2113(08)60283-
7 
 
IPNI. 2014. International Plant Nutrition Institute (IPNI). Fertilizantes. Disponível em: 
http://brasil.ipni.net/article/brs-3132#aparente. Acesso em 20 de outubro de 2015. 
 
KISS, S.; SIMIHAIAN, M. Improving efficiency of urea fertilizers by inhibition of soil urease activity. 
Norwell: Kluwer Academic, 2002. 393 p. http://dx.doi.org/10.1007/978-94-017-1843-1 
 
LADHA, J. K.; KUMAR, V. Direct seeding of rice: recent developments and future research needs. Advances 
in Agronomy, San Diego, v. 111, p. 297–396, 2011. http://dx.doi.org/10.1016/B978-0-12-387689-8.00001-1 
 
LARA-CABEZAS, W. A. R. Manejo de gramíneas cultivadas em forma exclusiva e consorciada com 
Brachiaria ruziziensis e eficiência do nitrogênio aplicado em cobertura. Revista Brasileira de Milho e Sorgo, 
Sete Lagoas, v. 10, p. 130-145, 2011. 
 
MALAVOLTA, E.; VITTI, G. C.; OLIVEIRA, S. A. Avaliação do estado nutricional das plantas: princípios 
e aplicações. 2.ed. Piracicaba: Potafos, 1997. 319p. 
 
MORO, E.; CRUSCIOL, C. A. C.; CANTARELLA, H.; NASCENTE, A. S. Upland rice under no-tillage 
preceded by crops for soil cover and nitrogen fertilization. Revista Brasileira de Ciência do Solo, Viçosa, v. 
37, p. 1669-1677, 2013. 
 
NASCENTE, A. S.; CRUSCIOL, C. A. C. COBUCCI, T. Ammonium and nitrate in soil and upland rice yield 
as affected by cover crops and their desiccation time. Pesquisa Agropecuária Brasileira, Brasília, v. 47, p. 
1699-1706, 2012. http://dx.doi.org/10.1590/S0100-204X2012001200004 
 
NASCENTE, A. S.; CRUSCIOL, C. A. C.; COBUCCI, T. The no-tillage system and cover crops - alternatives 
to increase upland rice yields. European Journal of Agronomy, Amsterdam, v. 45, p. 124-131, 2013. 
http://dx.doi.org/10.1016/j.eja.2012.09.004 
 
NASCENTE, A. S.; CRUSCIOL, C. A. C.; STONE, L. F. Straw degradation and nitrogen release from cover 
crops under no-tillage. Revista Caatinga, Mossoró, v. 27, p. 166-175, 2014. 
 
PRANDO, A. M.; ZUCARELI, C.; FRONZA, V.; OLIVEIRA, F. A.; OLIVEIRA JÚNIOR, A. Productive 
characteristics of wheat according to nitrogen sources and doses. Pesquisa Agropecuária Tropical, Goiânia, 
v. 43, p. 34-41, 2013. http://dx.doi.org/10.1590/S1983-40632013000100009 
 
PRANDO, A. M.; ZUCARELI, C.; FRONZA, V.; BASSOI, M. C.; OLIVEIRA, F. A. Forms of urea and 
nitrogen doses in top dressing in the agronomic performance of wheat genotypes. Semina: Ciências Agrárias, 
Londrina, v. 33, p. 621-632, 2012a. http://dx.doi.org/10.5433/1679-0359.2012v33n2p621 
 



1164 
Fertilizers with coated urea…  CARVALHO, M. C. S. et al. 

Biosci. J., Uberlândia, v. 32, n. 5, p. 1155-1164, Sept./Oct. 2016 

PRANDO, A. M.; ZUCARELI, C.; FRONZA, V.; OLIVEIRA, E. A. P.; PANOFF, B. Forms of urea and 
nitrogen doses in topdressing on the physiological quality of wheat seeds. Revista Brasileira de Sementes, 
Londrina, v. 34, p. 272-279, 2012b. http://dx.doi.org/10.1590/S0101-31222012000200012 
 
PRASAD, R. Aerobic rice systems. Advances in Agronomy, San Diego, v. 111, p. 207–236, 2011. 
http://dx.doi.org/10.1016/B978-0-12-387689-8.00003-5 
 
SAS Institute. Procedure guide for personal computers. Version 5. Cary: SAS Institute Inc., 1999. 
 
SILVA, A. A.; SILVA, T. S.; VASCONCELOS, A. C. P.; LANA, R. M. Q. Application of different sources of 
urea with gradual release in corn. Bioscience Journal, Uberlândia, v. 28, supl. 1, p. 104-111, 2012. 
 
SOUSA, D. M. G.; LOBATO, E. Cerrado: correção do solo e adubação. Planaltina, DF: Embrapa Cerrados, 
2003. 
 
TRENKEL, M. E. Slow and controlled-release and stabilized fertilizers: An option for enhancing nutrient 
use efficiency in agriculture. Paris: International Fertilizer Industry Association, 2010. 123 p. 
 
USDA, United States Department of Agriculture. 1999. Soil Taxonomy: a basic system of soil classification 
for making and interpreting soil surveys. 2nd ed. Washington: USDA. Disponível em: 
bhttp://www.nrcs.usda.gov/Internet/FSE_DOCUMENTS/nrcs142p2_051232.pdfN. Acesso em: 15 de 
Novembro de 2015 
 
VIANA, M. C. M.; FREIRE, F. M.; FERREIRA, J. J.; MACÊDO, G. A. R.; CANTARUTTI, R. B.; 
MASCARENHAS, M. H. T. Nitrogen fertilization on yield and chemical composition of signalgrass under 
rotational grazing. Revista Brasileira de Zootecnia, Viçosa, v. 40, p. 1497-1503, 2011. 
 
WATSON, C. J.; POLAND, P.; ALLEN, M. B. D. The efficacy of repeated applications if the urease inhibitor 
N-(n-butyl) thiophosporic triamide (nBTPT) for impruve the efficiency of urea fertiliser utilization on 
temperature grassland. Grass and Forage Science, Oxford, v. 53, p. 137-145, 1998. 
http://dx.doi.org/10.1046/j.1365-2494.1998.5320137.x