Peruvian Journal of Agronomy 4(2): 68–74  (2020)
ISSN: 2616-4477 (Versión electrónica) 
DOI: http://dx.doi.org/10.21704/pja.v4i2.1571
http://revistas.lamolina.edu.pe/index.php/jpagronomy/index
© The authors. Published by Universidad Nacional Agraria La Molina

Received for publication: 26 April 2020
Accepted for publication: 20 August 2020

Effects of nitrogen fertilization on the photosynthesis and biomass distribution in a 
potato crop

Efectos de la fertilización nitrogenada sobre la fotosíntesis y distribución de biomasa en un cultivo 
de papa

José E. Salas-Rosales1; Pedro Manuel Villa1,2*; Alice C. Rodrigues2; Fermín Rada3

*Corresponding author: pedro.villa@ufv.br

https://orcid.org/0000-0003-4826-3187

Abstract

Nitrogen fertilization has positive effects on growth and production of potato crop. The objective of this study was to 
assess the differences of the photosynthetic response and biomass partitioning patterns during the main phenophases 
of the potato cultivar Capiro under different nitrogen nutrition fertilization treatments in the tropical Andes of Mérida, 
Venezuela. Plots of 40 m2 (2,625 plants m-2) were established under a random block design with three replications by 
nitrogen fertilization treatment: 0, 100, 200, and 300 kg. N ha-1. Photosynthesis and biomass were measured in the 
different organs in the main phenological stages of the crop. The results indicate that photosynthesis tends to increase 
slightly with the nitrogen supply; although the differences were not always significant and, decreases during crop growth. 
Tubers yield it was markedly influenced by the nitrogen fertilization. The total biomass production, as well as biomass 
allocation in different organs showed differences between treatments, maintaining the following order: 300-N> 200-N> 
100-N> 0-N. When analyzing the biomass accumulation curves, it is estimated that the application of 250 kg N ha-1 as 
mineral fertilizer is enough to reach optimal production yields.

Keywords: Dry weight accumulation; nitrogen supply, Solanum tuberosum, tuber yield

Resumen

La fertilización nitrogenada tiene efectos positivos sobre el crecimiento y la producción del cultivo de papa. El objetivo 
de este estudio fue evaluar las diferencias de la respuesta fotosintética y los patrones de partición de biomasa durante 
las principales fenofases del cultivo de papa (cultivar Capiro) bajo diferentes tratamientos de fertilización con nitrógeno 
en los Andes tropicales de Mérida, Venezuela. Se establecieron parcelas de 40 m2 (2.625 plantas m-2) bajo un diseño 
de bloques al azar con tres repeticiones por tratamiento de fertilización nitrogenada: 0, 100, 200 y 300  kg N ha-1. La 
fotosíntesis y la biomasa se midieron en los diferentes órganos en las principales etapas fenológicas del cultivo. Los 
resultados indican que la fotosíntesis tiende a aumentar ligeramente con el suministro de nitrógeno; aunque las diferencias 
no siempre fueron significativas y disminuye durante el crecimiento del cultivo. El rendimiento de los tubérculos estuvo 
marcadamente influenciado por la fertilización nitrogenada. La producción total de biomasa, así como la asignación de 
biomasa en diferentes órganos mostraron diferencias entre los tratamientos, manteniendo el siguiente orden: 300-N> 
200-N> 100-N> 0-N. Al analizar las curvas de acumulación de biomasa, se estima que la aplicación de 250  kg N ha-1 
como fertilizante mineral es suficiente para alcanzar rendimientos de producción óptimos.

Palabras clave: acumulación de peso seco; suministro de nitrógeno, Solanum tuberosum, rendimiento

1 Instituto Nacional de Investigaciones Agrícolas (INIA), 5101, Mérida, estado Mérida, Venezuela..
2 Universidade Federal de Viçosa, Programa de Pós-Graduação em Botânica, Viçosa, Minas Gerais, Brasil.
3 Universidad de los Andes (ULA), Instituto de Ciencias Ambientales y Ecológicas (ICAE), 5101, Mérida, Venezuela.

Cite this article:
Salas-Rosales, J.E., Villa, P.M., Rodrigues, A.C., & Rada, F. (2020). Effects of nitrogen fertilization on the photosynthesis 
and biomass distribution in a potato crop. Peruvian Journal of Agronomy, 4(2), 68–74. http://dx.doi.org/10.21704/pja.
v4i2.1571



J.E. Salas-Rosales; P.M. Villa; A.C. Rodrigues; F. Rada
Peruvian Journal of Agronomy 4(2): 68-74 (2020)

69

Introduction

The response of plants to different types of environmental 
stress involves structural and functional changes ruled 
by processes linked to the carbon balance (Lambers, 
1998; Lambers et al., 1998; Schurr et al., 2006). Plants 
may respond to environmental heterogeneity through 
physiological and morphological plasticity that allows them 
to optimize resources (Lambers et al., 1998). Additionally, 
the morphological plasticity may also be a consequence of 
higher physiological plasticity (Lambers, 1998; Lambers 
et al. 1998; Schurr et al., 2006). Thus, the change in the 
biomass partitioning patterns throughout the organs may 
constitute an adaptation or acclimation mechanism in 
response to the environmental pressures (Osone & Tateno, 
2005; Schurr et al., 2006). This ecophysiological approach 
may serve as a fundamental instrument for addressing 
crop yields, given its socio-economic and environmental 
relevance. However, studies with this approach are still 
lacking for several crops, including superfoods playing a 
central role in global food security.

Potato is one of the main agricultural products 
contributing to global food security, given its high-yield 
production per unit area (Devaux et al., 2014). Potato is 
originally from the Andes, where it remains one of the 
main crops for its economic relevance (Villa & Sarmiento, 
2009; Machado & Sarmiento, 2012). The Diacol - Capiro 
cultivar has been farmed due to its high productivity, 
edaphoclimatic adaptability, and favorable properties 
for industrial processing (for example, potato chips). 
This potato cultivar has a vegetative cycle, which ranges 
from 130 and 150 days, with up to 35 t ha-1 crop yields 
in optimal growth conditions. Nevertheless, there are 
still not enough ecophysiological data about this cultivar 
showing the effects of different growing conditions (i.e., 
nutrients availability) on the biomass and tuber growth, 
production, and accumulation. Tubers are the organs of 
main economic interest in the case of potato crop, and 
they are notable for their high assimilation and nutrient 
accumulation throughout the crop cycle (e.g., Van Delden, 
2001; Machado & Sarmiento, 2012; Qiqige et al., 2017). 

Various studies have determined the role of nitrogen as 
an essential element to attain high productivity levels of 
potato crop (Biemond & Vos, 1992; Machado & Sarmiento, 
2012; Silva et al., 2013; Qiqige et al., 2017). Similarly, 
reduced levels of nitrogen may lead to considerable 
reductions of production yields and to a reduced biomass 
distribution (Van Delden, 2001; Alva et al., 2002; Qiqige et 
al., 2017). This response of the crop has been connected to 
the influence of leaf nitrogen on photosynthesis (Evans & 
Poorter, 2001), which varies according to the growth stage 
and to the nitrogen demand (Lambers et al., 1998; Poorter 
& Nagel, 2000). One method of analysis of the efficiency 
of nitrogen fertilization in agricultural crops has been the 
examination of the photosynthesis dynamics and biomass 
distribution and accumulation patterns throughout the 

different organs (Biemond & Vos, 1992; Alva et al., 2002; 
Qiqige et al., 2017). 

The biomass accumulation in potato crop may vary a 
lot throughout its phenological stages, yet with unchanged 
fertilization rates and growth conditions (Biemond & Vos, 
1992; Van Delden, 2001). On the other hand, nitrogen 
availability also determines the photosynthetic response 
within the crops, particularly in the case of leaf nitrogen 
destined to protein regeneration (Evans & Poorter, 2001). 
Therefore, the proportion between the nitrogen fertilization 
and the carbon gains considerably influences the growth 
and production yields (Lambers et al., 1998; Poorter & 
Nagel, 2000). 

In this context, there is a need to examine nitrogen 
fertilization alternatives for the potato crop by analyzing the 
implications for the production. Thus, the objective of this 
study was to assess the differences of the photosynthetic 
response and biomass partitioning patterns during the 
main phenostages of the potato crop cultivar Capiro under 
different nitrogen nutrition fertilization treatments in the 
tropical Andes of Mérida, Venezuela. 

Material and Methods

Study area and experimental design

The field experiment was carried out in Mucuchíes, in 
the municipality of Rangel, State of Mérida, Venezuela 
(8°46’94’’N - 70°55’47’’W, 3,200 masl) from April through 
July 2005. The Diacol-Capiro cultivar was selected due to 
its socio-economic importance in the region and earliness 
(development cycle of 4 to 4½ months). Mucuchíes has 
a mean annual temperature of 11.5 °C, and mean annual 
precipitation of 800 mm. The soil was characterized 
(0-30 cm) by a loamy-sandy texture, total nitrogen of 
0.03%, available phosphorus of 0.8 ppm, 1.0 meq 100 g 
interchangeable potassium, and pH of 5.5, and bulk density 
of 0.74 g cm-3.

Twelve plots (each 5 m × 8 m = 40m2) were established 
with a planting density of 2.625 plants per m-2 (0.25 m 
between plants, and 1.5 m between rows), with randomized 
block design, four different nitrogen fertilization treatment 
and three replications. Each plot contained five rows 8 m 
long, with two outer rows acting as barriers, and each row 
totaled 32 plants. The treatments used were as follows: 0, 
100, 200, and 300 kg N ha-1. Ammonium nitrate ((NH₄) 
NO3) was the source of inorganic nitrogen used. Inorganic 
fertilization source with ammonium nitrate (33.5% N) was 
supplied. Potassium sulfate (17% assimilable K2O) and 
phosphate rock (25% assimilable P2O5) were applied to 
all plots. A total 20 kg N ha-1 were applied in the 100-N 
treatment, 37.5 kg N ha-1 in the 200-N treatment, and 75 
kg N ha-1 in the 400-N treatment during sowing. During 
sowing, we also applied 100 kg ha-1 P2O5 in the form of 
phosphate rock (400 kg ha-1) and 200 kg ha-1 K2O in the 



Effects of nitrogen fertilization on the photosynthesis and biomass distribution in a potato crop

May - August 2020

70

form of potassium sulfate (476 kg ha-1) to all experimental 
plots. 

Data collection 

In each plot the growth parameters such as, number of stem, 
plant height (in cm), and biomass (g. plant) of the different 
organs was measured along the days after sowing (DAP). 
The samplings were taken during the main phenological 
stages of the crop: near the moment of emergence, on 
the 36th day after sowing (DAP), at the beginning of 
tuberization (60 DAP), at the time of maximum leaf 
expansion (105 DAP), and at harvest (127 DAP). Thus, 
number of stem, plant height and biomass was determined 
in each phenological stage from six plants selected in each 
plot, with the exception of the last sampling where ten 
plants per plot were harvested, given the significance of the 
crop yield from the agronomic point of view (Villa et al., 
2020). Samples of biomass were dried at 70°C until they 
reached a constant weight; subsequently, these samples 
were weighted and milled to further obtain composite 
samples per plot and sampling session. 

Gas exchange measurements were conducted in fully 
expanded leaf blade of three individual in each plot 
during the emergence (near 36 DAP), tuberization (64 
DAP), maximum leaf expansion (105 DAP), and harvest 
(127 DAP). Three of the fully mature and expanded 
top leaves were randomly obtained per plot (36 leaves 
for each treatment). Gas exchange measurements were 
conducted using portable gas exchange system (LI-COR 
6400; LI-COR, Lincoln, Nebraska, USA) measuring leaf 
photosynthesis for amplitude of photosynthetically active 
radiation (PAR) from 25 μmol m-2 s-1 up to 2500 μmol m-2 
s-1. 

Data analysis 

All analyses were carried out in R Environment (R Core 
Team 2018). Variation in the biomass in different organs, 
number of stem and plant height, were compared between 
all treatments by one-way analysis of variance (ANOVA; 
for normally distributed data) followed by a post hoc 
Tukey’s test (p < 0.05) using the car package (Fox et al., 
2017). The different treatments were the factors and the 
block design effects were key aspects to take into account. 
This test is suitable for randomized block design and non-
normal distribution data (Crawley, 2013).

We adjusted the response curves of assimilation based 
on gas exchange measurements. The non-rectangular 
hyperbola equation is commonly used to describe the 
response of foliar photosynthesis to radiation (Xu et al., 
2019). The R software served to estimate the parameters 
of the non-rectangular hyperbola following the same 
equation: 

Where Pn is the CO2 exchange rate (net photosynthesis 
rate), Pb is the gross photosynthesis, and Resp is the leaf 
respiration in the dark. With respect to the non-rectangular 
hyperbola, Rad is the radiation incident on the leaves, m 
is the initial slope of the light response curve, Pmax is 
the rate of gross photosynthesis when light saturation is 
reached, q is the Curvature parameter (Table 1).

Finally, tuber and total accumulated biomass along the 
DAP were adjusted with Gompertz functions (Y= a*exp-
b*exp-c*t), where Y is the biomass, t the time, a, b and 
c are parameters obtained by adjusting the experimental 
data. 

Results and Discussion

Overall, the results showed that photosynthesis tends to 
increase with nitrogen supply. This is the case even for non-
contrasting differences, mainly at 64 DAP. Photosynthesis 
tends to drop substantially, from emergence until harvest 
time (Figure 1). In this study, photosynthesis per unit 
of leaf area was found to be slightly different (~15 %) 
between contrasting treatments, but it was consistent in all 
the samples, following the order: 300-N > 200-N > 100-N 
> 0-N (Figure 1). In contrast, other studies have shown that 
nitrogen limitation has a striking effect in the reduction 
of leaf photosynthesis for different species (Lambers, 
1998; De Groot et al., 2003). For instance, De Groot et al. 
(2003), conclude that the limitation of photosynthesis of 

Pn = 1/2q [(mRad + Pmax) - √ (mRad + Pmax)2 – 4mqPmaxRad] – Resp       Equation 1

Pn = Pb – Resp              Equation 2

DAP Treatments
Parameters of the non-
rectangular hyperbola

Pmax m a Resp R2

36

0-N 12.85 0.0034 0.060 2.49 0.92
100-N 13.06 0.0039 0.080 2.47 0.90
200-N 14.52 0.023 0.048 0.99 0.96
300-N 15.22 0.025 0.045 1.55 0.95

64

0-N 11.76 0.010 0.023 1.29 0.91
100-N 12.05 0.020 0.027 1.03 0.92
200-N 12.96 0.025 0.037 0.89 0.90
300-N 13.25 0.027 0.047 0.99 0.93

105

0-N 6.08 0.012 0.020 1.12 0.96
100-N 7.35 0.019 0.024 1.03 0.94
200-N 8.12 0.021 0.025 0.90 0.92
300-N 9.27 0.023 0.027 0.78 0.90

127

0-N 3.90 0.009 0.019 1.05 0.89
100-N 4.10 0.016 0.020 0.90 0.87
200-N 5.86 0.025 0.022 0.72 0.86
300-N 6.09 0.029 0.030 0.60 0.90

Table 1. Parameters of the non-rectangular hyperbola 
during days after planting (DAP) in the different treatments 
of nitrogen fertilization: 0, 100, 200 and 300 kg N ha-1. The 
coefficient of determination (R2) is indicated. 



J.E. Salas-Rosales; P.M. Villa; A.C. Rodrigues; F. Rada
Peruvian Journal of Agronomy 4(2): 68-74 (2020)

71

Lycopersicon esculentum under nitrogen deficit is due to 
the excessive production of assimilates that do not have a 
direct drain or a strong drain, which leads to a significant 
reduction of photosynthesis, compared to the treatments 
without nitrogen deficit. In this regard, allegedly, the small 
differences of photosynthesis between nitrogen deficit 
conditions and those of fertilization, are due to the tubers’ 
demand of a large proportion of available assimilates, 
which increases with the time until the final harvest and 
avoids an accumulation of assimilates in the leaves to take 
place and, consequently, avoids limited photosynthesis. 

Nitrogen fertilization had significant effects on the 
production of tubers and total biomass, following this 
order: 300-N > 200-N > 100-N > 0-N (Figure 2), which 
increased as nitrogen fertilization was higher, 0-N (30.87 
± 4.5 Mg ha-1) <100-N (35.01 ± 2.23 Mg ha-1) <200-
N (36.41 ± 1.37 Mg ha-1) <300-N (38.61 ± 3.37 Mg ha-
1). However, there was only a 25% difference in tuber 
production between the 0-N and the 300-N treatments: 36g 
plant-1, and 49g plant-1, respectively. Furthermore, there 
was a small difference (4%) between the 200-N and the 
300-N treatments, without having significant differences 
(p > 0.05). 

These results are consistent with the ones found in 
other studies, where, as observed, biomass accumulation 
in potato crop grew with nitrogen supply (Biemond & 
Vos 1992; Alva et al., 2002; Machado & Sarmiento, 2012; 
Qiqige et al., 2017). These results suggest that, from 
an agricultural and ecological point of view, there is no 
justification for applying measures above 300  kg N ha-1 

Figure 1. Leaf photosynthesis- photosynthetically active radiation (PAR) response curves. A is the net carbon assimilation 
rate during days after planting (DAP) in the different treatments of nitrogen fertilization: (●) 0, (∆) 100, (◊) 200 and (□) 
300 kg N ha-1. 

Figure 2. Pattern of total dry biomass accumulation in 
tubers (A) and total dry biomass (B) during days after 
planting (DAP) in the different treatments of nitrogen 
fertilization: 0, 100, 200 and 300  kg N ha-1. The curves 
correspond to the adjustments Gompertz functions. 



Effects of nitrogen fertilization on the photosynthesis and biomass distribution in a potato crop

May - August 2020

72

in the form of mineral fertilizer, and that it would not be 
financially recommended, as there is no relevant increase 
of production when plants cannot keep the nitrogen surplus.

The dynamics of biomass accumulation tend to 
increase up until the 64th DAP and stays stable until its 
maximum leaf expansion; then, there is a reduction with 
the onset of senescence, after the 105th DAP (Figure 3). 
The pattern of biomass partitioning to the roots and stolons 
was not very different between the treatments (Figure 3). 
The plants are capable of responding to the heterogeneity 
of the environment (e.g. availability of nutrients used for 
growth) through their physiological or morphological 
plasticity, by which they can optimize the use of resources 
and the changes in the patterns of biomass partitioning 
throughout the organs of the plant (Lambers et al., 1998; 
Schurr et al., 2006; Qiqige et al., 2017). This can be 
crucial for agricultural production and financial ends. To 
this day, there are a relevant number of studies on the 
effects of nitrogen nutrition on the production of potato 
tubers. Conversely, a reduced number of studies deal with 
accumulation and partitioning of biomass to the different 
organs, under contrasting doses of nitrogen fertilization, 
during the growth of the crop. Even so, a few of them 
have limited their aim to examine partitioning of biomass 
to the stem and tubers, though leaving behind additional 
considerations regarding partitioning to stolon’s and 
roots. Furthermore, these studies have, in a lesser extent, 
examined the phenomena under nitrogen deficit conditions. 

The results suggest that the changes in the patterns of 
biomass partitioning throughout the plant depend mainly 

on the strength of the tubers as sinks of assimilated of 
photosynthesis, despite the nitrogen deficit conditions, 
maintain a reasonable production capacity from an 
agroecological perspective.

The result showed significant differences in other 
growth parameters (i.e. number of stems and height of 
plants) in the different growth stages before senescence 
(Table 2). Concerning biomass partitioning, this study 
found the greatest values of stem biomass during the 
periods of maximum leaf expansion. In this sense, Alva 
et al. (2002) found that leaf and stem weights were 60g 
and 30g in each plant, respectively, for Russet Burbank, 
and between 50 and 20g in each plant for Hilite Russet, 
respectively. On the other hand, Biemond & Vos (1992) 
found that, despite the great differences in the total weight 
of the stems, nitrogen treatments only offered a mild 
effect (N1= 2.5; N2 = 8 and N3 = 16 g N per plant) on 
the distribution of the dry weight of the stems throughout 
the leaves and the stems. The results showed that there 
is a higher leaves dry weight compared to stems in all 
treatments. However, near the 44 DAP, leaves dry weight 
with respect to the stems dry weight was between 60% and 
65% for N-100 and N-300, respectively. 

The effects of nitrogen nutrition on belowground 
biomass compartments, like the roots and stem, include 
more biomass accumulation in these organs under 
nitrogen deficit conditions, mainly during the first stages 
of development. It was not the case with the aerial 
organs. These results lead to conclude that the changes in 
assimilates distribution patterns of potato crop constitute 

Figure 3. Pattern of dry weight accumulation of different organs during days after planting (DAP) for in the different 
treatments of nitrogen fertilization: 0, 100, 200 and 300 kg N ha-1. The different letters indicate that there are significant 
differences between treatments per sampling period (p <0.05).



J.E. Salas-Rosales; P.M. Villa; A.C. Rodrigues; F. Rada
Peruvian Journal of Agronomy 4(2): 68-74 (2020)

73

a plastic response of acclimation to stress due to N deficit 
(Villa et al., 2020). Additionally, these results are very 
consistent with previous results provided by several review 
and research works dealing with other vegetal species 
(Lambers et al., 1998; Forde, 2002). According to other 
studies, fast-growing species tend to be more plastic than 
those growing more slowly, in terms of biomass partition as 
their response to the different levels of nitrogen availability 
or supply in the soil (Lambers, 1998; Lambers et al., 1998).

Conclusions 

This research showed that photosynthesis and growth 
parameters (i.e. biomass, number of stem, and plant 
height) tend to increase with the supply of nitrogen. 
Thus, this result reveals the high potential of the tubers 
to store assimilated of photosynthesis under conditions 
of nitrogen deficit. However, results allow us to conclude 
that the application of 300 kg N ha-1 as mineral fertilizer 
is not justified from a socioeconomic and environmental 
perspective, considering the little existing differences in 
tuber production with respect to the 200-N treatment. Thus, 
we recommend research that demonstrates the efficiency 
of nitrogen fertilization close to 200 Kg, and even less 
using combinations with organic fertilizers under different 
environmental conditions (i.e. topography, climate) and 
agronomic management (i.e. irrigation). Finally, in this 
study, the whole harvest did not attain its maximum 
productive potential. The suggestion is to combine mineral 
fertilizers with organic sources in order to guarantee and 
synchronize the nitrogen availability, in accordance with 
the actual demand of the crop during each phenological 
stage.

Acknowledgments

The authors acknowledge the collaboration of all employees 
from the Institute of Environmental and Ecological 
Sciences (Instituto de Ciencias Ambientales y Ecológicas 
– ICAE) of the Universidad de Los Andes (ULA) for their 
unconditional help during the experimental stages of the 
study. We specially acknowledge Johnny Marques, Francis 
Guillen, Zulay Méndez, Luis Cedeño, Kleira Quintero, and 
Wilmer Espinosa for their important technical support in 
the field and laboratory. We also thank Luis Castillo for 
providing certified seeds. The author wishes to thank the 
Institute of International Education’s Scholar Rescue Fund 
for their support to Fermín Rada during the past couple of 
years than has been participating in this research.

References 

Alva, A.K., Hodges, T., Boydston, R.A. & Collins, H.P. 
(2002). Dry matter and nitrogen accumulations 
and partitioning in two potato cultivars. Journal 
of Plant Nutrition, 25(8), 1621–1630. https://doi.
org/10.1081/PLN-120006047

Biemond, H. & Vos, J. (1992). Effects of nitrogen on 
the development and growth of the potato plant. 
2. The partitioning of dry matter, nitrogen and 
nitrate. Annals of Botany, 70(1), 37–45. https://doi.
org/10.1093/oxfordjournals.aob.a088437

Crawley, M.J. (2013). The R Book, second ed. Wiley, 
London. 

De Groot, C.C., Marcelis, L.F.M., Van Den Boogaard, R., 
Kaiser, W.M. & Lambers, H. (2003). Interaction of 
nitrogen and phosphorus nutrition in determining 
growth. Plant Soil, 248, 257–268. https://doi.
org/10.1023/A:1022323215010

Devaux, A., Kromann, P. & Ortiz, O. (2014). Potatoes for 
sustainable global food security. Potato Research, 
57, 185–199. https://doi.org/10.1007/s11540-014-
9265-1

Evans, J.R. & Poorter, H. (2001). Photosynthetic 
acclimation of plants to growth irradiance: the 
relative importance of specific leaf area and nitrogen 
partitioning in maximizing carbon gain. Plant, Cell 
and Environment, 24 (8), 755–767. https://doi.
org/10.1046/j.1365-3040.2001.00724.x

Forde, B.G. (2002). The role of long-distance signaling in 
plant responses to nitrate and other nutrients. Journal 
of Experimental Botany, 53(366), 39–43. https://doi.
org/10.1093/jexbot/53.366.39

Fox, J., Weisberg, S., Adler, D., Bates, D., Baud-Bovy, 
G., Ellison, S., Firth, D., Friendly, M., Gorjanc, G., 

Table 2. Number of stem and plant height during days 
after planting (DAP) in the different treatments of nitrogen 
fertilization: 0, 100, 200 and 300 kg N ha-1. 

DAP Treatment Number of 
stem

Heigth (cm)

36 0-N 2.4 ± 0.50 22.5 ± 2.83
 100-N 3.0 ± 0.69 23.0 ± 2.4
 200-N 3.2 ± 0.50 24.0 ± 2.9
 300-N 3.2 ± 0.69 24.0 ± 2.8
64 0-N 4.5 ± 0.96 50.5 ± 6.85
 100-N 5.2 ± 0.90 50.55 ± 4.2
 200-N 5.2 ± 0.92 52.8 ± 6.8
 300-N 5.3 ± 0.94 54.0 ± 3.5

105 0-N 4.7 ± 0.79 62.4 ± 8.14
 100-N 5.0 ± 0.81 63.0 ± 6.7
 200-N 5.0 ± 0.67 69.2 ± 8.2
 300-N 5.2 ± 0.69 70.0 ± 5.9



Effects of nitrogen fertilization on the photosynthesis and biomass distribution in a potato crop

May - August 2020

74

& Graves, S. (2017). “car” package: Companion to 
applied regression. RStudio package version 1.0.14. 
http://CRAN.R-project. org/package= car

Lambers, H. (1998). Epilogue: Research on the control 
of plant growth-where do we go next? In: H. 
Lambers, H. Poorter & M.M.I. Van Vuuren (Eds.), 
Inherent variation in plant growth: Physiological 
mechanisms and ecological consequences (pp. 139–
157). Netherlands, Backhuys Publishers, Leiden.

Lambers, H., Chapin, III., & Pons, T. (1998). Plant 
Physiological ecology. New York: Srpinger-Verlag. 
540 p. 

Machado, D. & Sarmiento, L. (2012). Respuesta del cultivo 
de papa a la combinación de diferentes fuentes de 
fertilización nitrogenada: evaluando la hipótesis de 
la sincronización. Bioagro, 24(2), 83–92. 

Osone, Y. & Tateno, M. (2005). Applicability and 
limitations of optimal biomass allocation models: a 
test of two species from fertile and infertile habitats. 
Annals of Botany, 95(7), 1211–1220. https://doi.
org/10.1093/aob/mci133

Poorter, H. & Nagel, O. (2000). The role of biomass 
allocation in the growth response of plants to 
different levels of light, CO2, nutrients and water: 
a quantitative review. Australian Journal of 
Plant Physiology, 27(12), 1191–1191. https://doi.
org/10.1071/PP99173_CO

Qiqige, S., Jia, L., Qin, Y., Chen, Y. & Fan, M. (2017). 
Effects of Different Nitrogen Forms on Potato Growth 
and Development. Journal of Plant Nutrition, 40 
(11), 1651–1659. https://doi.org/10.1080/01904167
.2016.1269345

R Core Team (2018). R: A language and environment for 
statistical computing. R Foundation for Statistical 
Computing. Vienna, Austria. https://www.R-project.
org/

Schurr, U., Walter, A. & Rascher, U. (2006). Functional 
dynamics of plant growth and photosynthesis 
from steady-state to dynamics-from homogeneity 
to heterogeneity. Plan Cell and Environment, 
29 (3), 340–352. https://doi.org/10.1111/j.1365-
3040.2005.01490.x

Silva, J.G., França, T.C., Gomide, F.T.F. & Magalhaes, J.R. 
(2013). Different Nitrogen Sources Affect Biomass 
Partitioning and Quality of Potato Production in a 
Hydroponic System. American Journal of Potato 
Research, 90, 179–185. https://doi.org/10.1007/
s12230-012-9297-5

Van Delden, A. (2001). Yield and growth components 
of potato and wheat under organic nitrogen 

management. Agronomy Journal, 93 (6), 1370–1385. 
https://doi.org/10.2134/agronj2001.1370

Villa, P.M. & Sarmiento, L. (2009). Recomendación 
alternativa para la fertilización nitrogenada del 
cultivo de papa en los altos Andes venezolanos. INIA 
Hoy, 6, 191–199. 

Villa, P.M., Sarmiento, L., Rada, F., Rodrigues, A.C., 
Márquez, N. & Espinosa, W. (2020). Partición de 
biomasa y nitrógeno en el cultivo de papa bajo tres 
tratamientos de fertilización nitrogenada. Siembra, 
7(2), 057–068. https://doi.org/10.29166/siembra.
v7i2.2235

Xu, J., Lv, Y., Liu, X., Wei Q., Qi Z., Yang, S. & Liao 
L. (2019). A general non-rectangular hyperbola 
equation for photosynthetic light response curve of 
rice at various leaf ages. Scientific Reports, 9, 9909. 
https://doi.org/10.1038/s41598-019-46248-y