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674 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 35, n. 3, p. 674-681, May/June 2019 
http://dx.doi.org/10.14393/BJ-v35n3a2019-41148 

PHOTOSYNTHETIC CHARACTERISTICS OF SUMMER MAIZE UNDER 

DIFFERENT PLANTING PATTERNS AND THE RESPONSES TO NITROGEN 

APPLICATION OF PREVIOUS CROP 
 

CARACTERÍSTICAS FOTOSSINTÉTICAS DO MILHO VERÃO SOB DIFERENTES 
PADRÕES DE PLANTIO E AS RESPOSTAS À APLICAÇÃO DE NITROGÊNIO DA 

CULTURA ANTERIOR 
 

X. B. ZHOU
1
*; P. J. SHEN

1
; Y. X. ZHAO

1
; D. H. JIANG

1
; J. H. HUANG

1 

Guangxi Colleges and Universities Key Laboratory of Crop Cultivation and Farming System, Agricultural College of Guangxi 
University, Nanning 530004, China. *Corresponding author’s e-mail: xunbozhou@gmail.com 

 
ABSTRACT: Maize (Zea mays L.) is one of the most important grain crops in the North China Plain. 

Management practices affect the photosynthetic characteristics and the production of summer maize. This two-
year (2014-2015) study examined the effects of different planting patterns and the application of nitrogen to 
previous winter wheat (Triticum aestivum L.) on the photosynthetic characteristics, yield and radiation use 
efficiency (RUE) of summer maize. Field experiments used a two-factor split-plot design with three replicates 
at Taian, Shandong Province, China (36°09′ N, 117°09′ E). The experiments involved two planting patterns 
(ridge planting, RP; and uniform row planting, UR) and two nitrogen application levels of previous winter 
wheat (N1, 112.50 kg ha-1; N2, 225.00 kg ha-1). The results indicated that the application of nitrogen on 
previous crop and ridge planting of the following crop had significant effects on the photosynthetic 
characteristics and yields of summer maize. Compared with UR, this study found that RP increased the 
chlorophyll content index (CCI), leaf area index (LAI), net photosynthetic rate (Pn), dry matter (DM), yield and 
grain RUE by 4.1%, 6.3%, 5.2%, 6.4%, 8.9% and 9.4%, respectively. The CCI, LAI, Pn, yield, and grain RUE 
of N2 were 9.7%, 3.3%, 3.7%, 10.0% and 10.1% higher than those of N1, respectively. RP combined with the 
application of nitrogen on previous crop of winter wheat could increase the CCI, LAI, Pn, DM, ultimately 
increasing the grain yield and RUE of the following summer’s maize. It was concluded that previous crop 
nitrogen application and RP pattern treatment resulted in optimal cropping conditions for the North China plain. 

 
KEYWORDS: Zea mays L. Ridge plantin. Nitrogen level. Photosynthetic rate. Leaf area index. Yield. 

 

INTRODUCTION 
 
Maize (Zea mays L.) has become an 

important pillar of agricultural development in 
China and is the third primary crop. Currently, there 
are many kinds of planting patterns that are used to 
attain high grain yields in maize production. The 
maize planting patterns used in China include flat 
planting, ridge planting, and furrow planting (WU et 
al., 2017). Planting pattern affects the population 
structure of crops, in addition to physiological 
characteristics, such as light utilization (ZHANG et 
al., 2017). This study hypothesizes that ridge 
planting is superior to conventional flat planting, 
which has been widely promoted and has been 
significantly improved in many ways, including 
conserving water, improving fertilizer use 
efficiency, and increasing grain yield (MAJEED et 
al., 2015). Zhang et al. (2012) and Yao (2015) 
indicate that ridge planting can affect enzyme 
activities and microbial functional groups, increase 
photosynthetic parameters, gas exchange rates, root 

absorption, and reduce water consumption. In 
addition, the canopy structure, net photosynthetic 
rate, stomatal conductance, transpiration rate, and 
the relative content of chlorophyll in maize leaves is 
also increased under ridge planting (TAO et al., 
2013). 

Some studies have shown that the 
application of nitrogen fertilizers positively 
influences photosynthetic characteristics and maize 
grain yield (VOS et al., 2005; JAVEED et al., 
2013). The application of nitrogen fertilizer can 
result in considerable increases in maize yields and 
profitability (JAMA et al., 2017); however, the 
application of excess nitrogen can lead to 
environmental problems, particularly for soil and 
groundwater quality (LI et al., 2016). The key to 
addressing this problem is to apply nitrogen 
rationally, taking into account the nitrogen applied 
to the previous crop. The maize yield of tillage 
systems that combine fertilizer applications is 
significantly higher than that of conventional 
systems (TUECHE; HAUSER, 2011). Little 

Received: 12/02/18 
Accepted: 20/03/19 



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Photosynthetic characteristics…  ZHOU, X. B. et al. 

Biosci. J., Uberlândia, v. 35, n. 3, p. 674-681, May/June 2019 

attention has been given to how planting patterns 
combined with nitrogen application of previous 
crops affect summer maize. The objective of this 
study was to evaluate the combined effects of ridge 
planting and the application of nitrogen on previous 
winter wheat (Triticum aestivum) on the 
photosynthetic characteristics and grain yield of 
summer maize.  

 
MATERIAL AND METHODS 

 
A field experiment was conducted at the 

Agronomy Experimental Station of Shandong 
Agricultural University, Taian, Shandong Province, 
China (36°09′ N, 117°09′ E). The winter wheat-
summer maize rotation is an important cropping 
system in the North China Plain. In the experimental 

area, winter wheat (var. Jimai 22) was cultivated 
before the planting of summer maize (var. Zhengdan 
958) in 2014 and 2015. Summer maize was sowed 
on June 15 2014 and June 15 2015, respectively, 10 
days after winter wheat harvested. The planting 
density was 62500 plants ha-1 and harvested on 
September 27 2014 and September 30 2015. This 
study utilized a two-factor split-plot design, with 
two planting patterns (ridge planting, RP; and 
uniform row planting, UR) for the main plot, and 
two nitrogen application levels on previous winter 
wheat (N1, 112.5 kg ha-1; N2, 225.0 kg ha-1) for the 
sub-plot (Figure 1). The summer maize field 
experiment had three replications, and no nitrogen 
was applied for field plots. Each plot was 4 × 4 m in 
size. 

 

 
Figure 1. The summer maize ridge planting (A) and uniform row planting (B). 

 
The study site characterizes the main 

summer maize growth area of North China with a 
warm-temperate monsoon climate. During the 
summer maize growing season, precipitation values 
were 372.5 mm and 282.6 mm for 2014 and 2015, 

respectively (Table 1), and the annual temperature 
mean was 25.0°C (1971-2015). The physical and 
chemical properties of the experimental site soil 
layer at a depth from 0 cm to 20 cm were tested 
before planting the maize (Table 2). 

 
Table 1. Monthly rainfall (mm) in the 2014 and 2015 summer maize growing season. 
Month June (Sowing) July August September (Harvest) Total 
2014 65.0 135.2 35.3 137.0 372.5 
2015 74.7 74.2 120.7 13.0 282.6 
 
Table 2. The soil physical and chemical properties of the experimental field. 

pH 
Total N 
(mg kg-1) 

Available P 
(mg kg-1) 

Available K 
(mg kg-1) 

Soil bulk density 
(g cm-3) 

Soil organic matter 
(g kg-1) 

Field capacity 
(V%) 

6.9 123.2 40.6 124. 5 1.50 18.9 38.6 
 
For vegetative growth stages: V6 (sixth 

leaf), reproductive development stages: R0 (silking 
stage), R2 (blister stage), R3 (milk stage), and R4 
(dough stage), the chlorophyll content index (CCI) 
and the net photosynthetic rate (Pn) of the ear leaf, 
the dry matter (DM) and the leaf area index (LAI) 
were measured (RITCHIE et al., 1986).  

The leaf, stem, and ear samples were 
separated and placed in a drying oven at 105°C for 
30 min and then dried at 80°C until they reached a 
constant weight. The following equations were used 

to calculate the leaf area and radiation use efficiency 
(RUE):  

Leaf area = leaf length × leaf width × 0.83       
(1) 

where leaf length is the distance between the 
leaf pillow and the leaf tip, and leaf width is the 
widest part of the leaf.  

RUE (%) = ∆W × H/ΣS × 100%               (2) 
In this equation, ∆W is grain yield (T ha-1) 

of summer maize, H is the rate of product heat 
(grain is 16.5 MJ kg-1; stem and leaf are 14.4 MJ kg-



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Photosynthetic characteristics…  ZHOU, X. B. et al. 

Biosci. J., Uberlândia, v. 35, n. 3, p. 674-681, May/June 2019 

1), and ΣS is the total radiation (1.95 × 107 MJ ha-1 
from 2014 and 2.21 × 107 MJ ha-1 from 2015). 

Pn was measured using a LI-6 400XT 
syste m (LI-COR Inc., Lincoln, USA), and CCI 
was measured with a Chlorophyll meter 200 (Opti-
Sciences Inc., Tyngsboro, USA) from 09:00 -
11:00. 

All graphs were generated with SigmaPlot 
10.0 (SPSS Inc., Chicago, USA). The trail data were 
analyzed via SAS 9.2, and the treatment means were 
compared using LSD (P < 0.05). 
 

RESULTS AND DISCUSSION  

 

Chlorophyll content index (CCI) 

Figure 2 shows an increasing initial CCI 
trend, followed by a decreasing trend, and it 

indicates the turning CCI points of different 
treatments of R0 and R2 for 2014 and 2015, 
respectively. Compared with UR, the CCI of RP 
increased by 3.6% (2014) and 4.6% (2015). The 
CCI of summer maize with RP and UR decreased 
by 38.8% and 39.3% from R0 to R4 (2014) and 
28.4% and 31.6% from R2 to R4 (2015), 
respectively. The CCI averages of RP and UR were 
40.7 in 2014 and 39.1 in 2015, respectively, and the 
CCI of RP increased by 4.1% compared to that of 
UR. This finding illustrated that RP was beneficial 
to the improvement of CCI. According to the 2-year 
results, the average CCI of N1 and N2 was 37.4 and 
42.4 (2014) and 38.0 and 41.7 (2015) during each 
growing season, respectively. The average CCI 
values of N2 were significantly higher than those of 
N1. 

 

25

30

35

40

45

50

55

N1

C
C

I

2014

2015

N2

N1

Growth stage
V6 R0 R2 R3 R4

C
C

I

25

30

35

40

45

50

V6 R0 R2 R3 R4
Growth stage

N2

Ridge planting Uniform row planting  
 

Figure 2. Effects of planting pattern and nitrogen on chlorophyll content index (CCI) of summer maize. N1 
(112.5 kg ha-1) and N2 (225.0 kg ha-1) were nitrogen content; bars were s.e. 

 

 

Leaf area index (LAI) 
With the growth of summer maize, the LAI of 

RP and UR reached the highest point at R2. The 
average LAI values of RP and UR were 5.35 and 
3.32, respectively, and the LAI of RP was 6.3% 
higher than that of UR over 2 years (Figure 3). The 
LAI descent ranges of RP and UR were 45.3% and 
56.6% from R2 to R4, indicating that RP could 
significantly improve the LAI of summer maize and 

depress the decrease of late growth stages. In two-
year study, the ranking of the LAI average was N2 > 
N1, with specific values of 3.60 and 3.25, 
respectively. For N1 and N2 treatments, the 
maximum change range of LAI variation was 5.7% 
and 6.9%, respectively. The LAI of RP was 3.3% 
higher than that of UR under N2. This showed that 
the RP was beneficial to increasing LAI values for 
summer maize.  



677 
Photosynthetic characteristics…  ZHOU, X. B. et al. 

Biosci. J., Uberlândia, v. 35, n. 3, p. 674-681, May/June 2019 

1

2

3

4

5

6

2014

L
ea

f 
ar

ea
 i

n
de

x
L

ea
f 

ar
ea

 i
n

d
ex

N1

N1

N2

N2

V6 R0 R2 R3 R4

Growth stage
V6 R0 R2 R3 R4

1

2

3

4

5

Growth stage

Ridge planting Uniform row planting

2015

 
Figure 3. Effects of planting pattern and nitrogen amount on leaf area index of summer maize. N1 (112.5 kg 

ha-1) and N2 (225.0 kg ha-1) were nitrogen content; bars were s.e. 
 
Photosynthetic rate (Pn) 

The different planting patterns and nitrogen 
fertilization influenced the Pn of the summer maize 
in 2014 and 2015 (Figure 4). The Pn mean 
decreased gradually with growth for two years, and 
the Pn values for V6, R0, R2, R3 and R4 were 41.7, 
39.5, 34.0, 28.8 and 15.1 µmol CO2 m

-2 s-1, 
respectively. The curve displayed that Pn decreased 
slowly at the early stages (V6-R2), and decreased 
rapidly in the late growth stages (R2-R4). Compared 
with UR, the Pn mean of the RP treatment from 

2014 to 2015 increased by 5.2%. Pn values across 
the whole growth period were characterized by a N2 
> N1 relationship, with specific Pn mean values for 
N1 and N2 of 32.5 µmol CO2 m

-2 s-1 (2014) and 35.2 
µmol CO2 m

-2 s-1 (2015), respectively. The Pn 
values of N1 and N2 at R4 decreased by 66.0% and 
55.7% compared with R2, respectively. These 
results show that N2 could maintain a relatively 
high Pn and help to increase the yield of summer 
maize. The Pn of N2 was 3.7% higher than that of 
N1.  

 

N1 N2

P
n

 (
¦Ì

m
o

l 
C

O
2 

m
- 2

 s
-1

)

N1
N2

2014

2015

V6 R0 R2 R3 R4
0

10

20

30

40

50

V6 R0 R2 R3 R4

Ridge planting Uniform row planting

Growth stage Growth stage

P
n 

(¦
Ìm

o
l 

C
O

2
 m

- 2
 s

-1
)

0

10

20

30

40

50

60

 
 

Figure 4. Effects of planting patterns and nitrogen amount on net photosynthetic rate (Pn) of summer maize. 
N1 (112.5 kg ha-1) and N2 (225.0 kg ha-1) were nitrogen content; bars were s.e. 

 
 

 

 

 



678 
Photosynthetic characteristics…  ZHOU, X. B. et al. 

Biosci. J., Uberlândia, v. 35, n. 3, p. 674-681, May/June 2019 

Dry matter (DM) 

DM showed an increasing trend with growth 
(Figure 5). The DM of RP was significantly higher 
than that of UR for R2, R3 and R4, and the trend 
was consistent across 2 years. During the 2015 
growing season, the DM mean of N2 was 5.8% 
greater than that of N1, and there was no significant 

difference (P > 0.05). From 2014 to 2015, the DM 
of N2 was significantly higher than that of N1 (P < 
0.05). DM means for RP and UR were 9810 and 
9322 kg ha-1 (2014), and 8444 and 7603 kg ha-1 
(2015), respectively. The DM of RP was significant 
higher than that of UR.  

N2

D
ry

 m
at

te
r 

w
ei

gh
t 

(k
g

 h
a-

1 )

N2N1

2015

2014

Growth stageGrowth stage

0

3000

6000

9000

12000

15000

18000

V6 R0 R2 R3 R4
0

3000

6000

9000

12000

15000

V6 R0 R2 R3 R4

Ridge planting Uniform row planting

N1

D
ry

 m
at

te
r 

w
ei

g
h

t 
(k

g
 h

a-
1
)

 
 

Figure 5. Effects of planting patterns and nitrogen amount on dry matter weight of summer maize. N1 (112.5 
kg ha-1) and N2 (225.0 kg ha-1) were nitrogen content; bars were s.e. 

 

Yield and radiation use efficiency (RUE) 
In 2014 growth season, biomass yield and 

biomass RUE of UR (N1) and RP (N2) were 
significantly higher than that of RP (N1), grain yield 
and grain RUE of RP (N2) were significantly higher 
than that of UR (N1) (P < 0.05); in 2015 growth 
season, biomass yield and biomass RUE were no 
significantly between different treatments (P > 
0.05), grain yield and grain RUE of RP (N2) were 
significantly higher than those of other treatments 
(P < 0.05). Under N1, means of tow growth seasons 
of biomass yield, grain yield, biomass RUE and 
grain RUE were 1.76 T ha-1, 0.95 T ha-1, 1.31%, 
0.76% (RP) and 1.89 T ha-1, 0.85 T ha-1, 1.40%, 

0.68% (UR); under N2, means of tow growth 
seasons of biomass yield, grain yield, biomass RUE 
and grain RUE were 1.88 T ha-1, 1.02 T ha-1, 1.41%, 
0.82% (RP) and 1.84 T ha-1, 0.96 T ha-1, 1.38%, 
0.76% (UR) (Table 3). These results indicated that 
nitrogen fertilization of previous crop, yield of the 
following maize were increased under the same 
planting pattern; yield of RP was 11.7% (N1) and 
6.3% (N2) higher than those of UR. The results 
showed that biomass yield and RUE there were 
significantly interaction effect between application 
nitrogen in previous crop and following summer 
maize planting pattern (P < 0.05).  

 
Table 3. Effects of planting patterns (PP) and nitrogen amount on yield and radiation use efficiency (RUE) of 

summer maize.  
Treatments Biomass yield (T ha-1) Grain yield (T ha-1) Biomass RUE (%) Grain RUE (%) 

2014 2015 2014 2015 2014 2015 2014 2015 
N1 RP 1.63b 1.88a 0.98ab 0.91b 1.31b 1.31a 0.83ab 0.68b 
 UR 1.85a 1.93a 0.84b 0.86b 1.46a 1.34a 0.71b 0.64b 
N2 RP 1.87a 1.89a 1.01a 1.03a 1.49a 1.33a 0.86a 0.77a 
 UR 1.76ab 1.92a 0.98ab 0.93b 1.41ab 1.34a 0.83ab 0.69b 
P value N 0.7195 0.8125 0.3507 0.1640 0.0940 0.6561 0.1381 0.0042 

PP 0.8101 0.1209 0.3482 0.2085 0.3775 0.3342 0.1372 0.0134 
N×PP 0.0205 0.5990 0.2060 0.2837 0.0241 0.4693 0.5261 0.2837 

N1, 112.5 kg ha-1; N2, 225.0 kg ha-1; RP, ridge planting; UR, uniform row planting. Values followed by a different small letter within a 
column are significantly different at 5% probability level. 



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Biosci. J., Uberlândia, v. 35, n. 3, p. 674-681, May/June 2019 

The correlation analysis between yield and 

photosynthetic factors 
The N, Pn, CCI, LAI and yield correlation 

analysis of summer maize for the 2-year results is 
shown in Table 4. There was significant positive 

correlation between N, Pn, CCI, and LAI with yield 
(P < 0.05); between Pn and CCI (P < 0.01). In 
addition, there was significant positive correlation 
among N, CCI, LAI, and yield (P < 0.05).  

 
Table 4. The correlation analysis between yield and photosynthetic factors. 
Person correlation coefficients 
Variable N Pn CCI LAI Yield 
N 1.000 0.926** 0.990** 0.882* 0.988** 
Pn  1.000 0.941** 0.791 0.897* 
CCI   1.000 0.913* 0.982** 
LAI    1.000 0.933** 
Yield     1.000 
*, ** Correlation is significant at the 0.05 and 0.01 level, respectively. 

 
Chlorophyll is an important pigment for 

photosynthesis (PENG et al., 2011). When the 
nitrogen level in previous crops was high, this study 
found that the CCI of maize leaves was also high, 
which indicated that CCI was strongly influenced by 
previous crop nitrogen levels. Other studies 
observed similar results (CLEVERS; KOOISTRA, 
2012; SCHLEMMER et al., 2013). Leaves are the 
material carrier of intercepted light energy, and leaf 
size in maize is responsive to nitrogen supply and 
had a close relationship with photosynthetic rate. 
LAI is also one of the main physiological 
determinants of crop yield (HAMZEI; SOLTANI, 
2012). The results of this study indicated that the 
relationship for the LAI and Pn averages was N2 > 
N1 and that N2 had advantage for increasing LAI, 
maintaining a relatively high Pn and increasing the 
yield of summer maize. In general, the increase of 
previous crop nitrogen content combined with using 
RP pattern for the following maize crops could 
enhance CCI and increase both Pn and grain yield.  

RP has been widely used for wheat, maize, 
rice, and soybean crops, with varying increases of 
yield (SONG et al., 2013). REN et al. (2016) 
illustrates that RP is conducive to improved 
photosynthetic characteristics, contribute to 
photoassimilate accumulation and enhance maize 
productivity (JIANG et al., 2016). HASSAN et al. 
(2005) observe that there are increases of 30% in the 
grain yield of RP compared to flat planting pattern. 
This study demonstrated that previous winter wheat 
nitrogen levels significantly affected photosynthetic 

factors and yield of the following summer maize 
crop. The yields of different nitrogen contents can 
be significantly different owing to their differential 
impacts on growth and yield (HAMZEI; SOLTANI, 
2012). The photosynthetic characteristics, grain 
RUE and yields of RP were higher than those of 
UR.  
 

CONCLUSIONS 

 
Previous crop nitrogen levels and following 

crop ridge planting pattern had a significant effect 
on the photosynthetic characteristics and yield of 
summer maize.  

The use of RP pattern, combined with the 
application of nitrogen to previous winter wheat, 
could increase CCI, LAI, Pn, and DM, ultimately 
increasing the grain yield and RUE of the following 
summer maize crops.  

This study demonstrated that the previous 
crop N2 (225.0 kg ha-1) combined with following 
crop ridge planting pattern could be utilized for 
summer maize in the North China Plain.   
 

ACKNOWLEDGEMENTS 
 
The research was sponsored by the National 

Natural Science Foundation of China (31760354), 
Guangxi Natural Science Foundation 
(2017GXNSFAA198036). We would like to thanks 
Zhang Zhen for the work contribution. 

 
 
RESUMO: O milho (Zea mays L.) é uma das culturas de grãos mais importantes da Planície do Norte 

da China. Práticas de manejo afetam as características fotossintéticas e a produção do milho verão. Este estudo 
de dois anos (2014-2015) examinou os efeitos de diferentes padrões de plantio e a aplicação de nitrogênio ao 
trigo de inverno anterior (Triticum aestivum L.) sobre as características fotossintéticas, produtividade e 
eficiência de uso de radiação (RUE) do milho verão. Experimentos de campo usaram um delineamento em 



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Biosci. J., Uberlândia, v. 35, n. 3, p. 674-681, May/June 2019 

parcelas subdivididas de dois fatores com três repetições em Taian, província de Shandong, China (36°09′ N, 
117°09′ E). Os experimentos envolveram dois padrões de plantio (ridge planting, RP; e uniform row planting, 
UR) e dois níveis de aplicação de nitrogênio do trigo de inverno anterior (N1, 112,50 kg ha-1; N2, 225,00 kg 
ha-1). Os resultados indicaram que a aplicação de nitrogênio na cultura anterior e no plantio RP da cultura 
seguinte teve efeitos significativos nas características fotossintéticas e na produtividade do milho verão. 
Comparado com o plantio UR, este estudo concluiu que RP aumentou o índice de conteúdo de clorofila (CCI), 
índice de área foliar (LAI), taxa fotossintética líquida (Pn), matéria seca (DM), produtividade e RUE de grãos 
em 4,1%, 6,4%, 5,2%, 6,4%, 8,9% e 9,4%, respectivamente. Os valores de CCI, LAI, Pn, produtividade e RUE 
de N2 foram 9,7%, 3,3%, 3,7%, 10,0% e 10,1% superiores aos de N1, respectivamente. RP combinada com a 
aplicação de nitrogênio na safra anterior de trigo de inverno poderia aumentar os valores de CCI, LAI, Pn, DM, 
aumentando o rendimento de grãos e RUE do milho do verão seguinte. Concluiu-se que a aplicação prévia de 
nitrogênio na colheita e o tratamento com padrão RP resultaram em condições ótimas de cultivo para a planície 
do norte da China. 
 

PALAVRAS-CHAVE: Zea mays L . Ridge planting. Nível de nitrogênio. Taxa fotossintética. Índice 
de área foliar. Produção. 

 
 

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