Effects of Crop Straw on the Plant Height, Stem Diameter and
Soluble Sugar Content of Peach (Amygdalus davidiana) Seedlings
Jinrong Zhang
1a
, Panhong Zou
1b
, Yunying Xiao
2c
, Xiangting Xu
2d
, Junjiang Shu
2e
,
Lijin Lin
2f
and Huashan Lian
1,* g
1
School of Agriculture and Horticulture, Chengdu Agricultural College, Chengdu, Sichuan, China
2
College of Horticulture, Sichuan Agricultural University, Chengdu, Sichuan, China
506281331@qq.com,
*
49939450@qq.com
Jinrong Zhang and Panhong Zou contributed equally to this work
*Corresponding Author
Keywords: Peach (Amygdalus davidiana) Seedlings, Straw, Growth, Soluble Sugar.
Abstract: The study of the effects of adding different crop (rape, rice, wheat, and maize) straw to the soil on the plant
height, stem diameter and soluble sugar of peach (Amygdalus davidiana) seedlings were studied. The plant
height and stem diameter of the peach seedlings treated with rape straw were the largest, 27.09 cm and 3.24
mm, respectively, and the plant height increased by 20.51% compared with the control. The soluble sugar
contents in roots, leaves of peach seedlings treated with wheat straw were the highest, which were 78.14
mg/g and 97.74 mg/g, respectively. Therefore, soil covering of rape straw was beneficial to the growth of
plant height and stem diameter of peach seedlings, and the accumulation of soluble sugar content of peach
seedlings treated with wheat straw was the best.
1 INTRODUCTION
1
As an economic resource, straw is the product of
agricultural crops, and the people pay more and
more attention to the utilization of straw, and many
utilization methods of straw have been invented,
among which the most important one is returning
straw to the field (Yin 2021). In recent years, a large
number of straw burning has occurred in the world,
however the choice of straw burning not only wastes
resources, but also pollutes the environment (Yin
2021, Wu 2021). The crop straw is mainly used for
rice, wheat, maize, beans and tubers, which can be
used on a large scale because of their extensive
sources (Wu 2021). Many scholars have studied the
use of rape straw in rice fields can bring huge
economic benefits (Zhang 2021, He 2021). Straw is
a
https://orcid.org/0000-0002-0186-9117
b
https://orcid.org/0000-0003-3380-9191
c
https://orcid.org/0000-0003-4880-5660
d
https://orcid.org/0000-0002-8903-974X
e
https://orcid.org/0000-0003-2598-2365
f
https://orcid.org/0000-0002-3650-8557
g
https://orcid.org/0000-0001-8036-109X
rich in some specific nutrient elements and nutrients,
under certain conditions, these elements and
nutrients with the rotten straw into the soil to be
absorbed by the plant use (An 2021, Gao 2021).
Many studies have shown that the straw of rape,
maize, rice and wheat can promote the growth of
plants (An 2021, Gao 2021, Chen 2021), and the
application of rape straw can also increase the
content of soluble sugar in maize (An 2021).
Peach (Amygdalus davidiana) is a small
deciduous tree belonging to the genus Prunus in the
family Rosaicaceae (Chen 2021). Peach has very
strong tolerance, such as salt tolerance, alkali
resistance and cold resistance, which is often used as
the rootstock (Wang 2021). The stro ng
adaptability of peach makes people pay more and
more attention to it, and there are more and more
studies on it, and most of them are to study the
benefits brought by peach as a graft material (Wang
2021, Xiang 2019). Peach plays an important role in
returning farmland to forest, restoring soil and
greening (Wu 2020, Benedikt 2020). In this study,
we added the straw of rape, rice, wheat, and maize
on to the soil, and planted peach seedlings, and the
effects of crop straw on the growth and soluble sugar
Zhang, J., Zou, P., Xiao, Y., Xu, X., Shu, J., Lin, L. and Lian, H.
Effects of Crop Straw on the Plant Height, Stem Diameter and Soluble Sugar Content of Peach (Amygdalus davidiana) Seedlings.
DOI: 10.5220/0011392500003443
In Proceedings of the 4th International Conference on Biomedical Engineering and Bioinformatics (ICBEB 2022), pages 1249-1253
ISBN: 978-989-758-595-1
Copyright
c
2022 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
1249
content of peach seedlings were studied. The aim of
this study was screened out the best crop straw that
could promote the growth of peach seedlings, and
provide reference for peach production.
2 MATERIALS AND METHODS
2.1 Materials
The seeds of Amygdalus davidiana were purchased
from the market. The seeds were germinated and
transplanted to a plastic basin containing perlite.
Rape, rice, wheat and maize straw were collected in
the fields around Sichuan Agricultural University,
dried and crushed for reserve use. The soil was
fluvial soil, taken from the farmland around
Chengdu Campus of Sichuan Agricultural
University. The basic physical and chemical
properties of soil were: pH 7.71, organic matter
22.38 g/kg, total nitrogen 1.75 g/kg, total
phosphorus 10.25 g/kg, total potassium 11.32 g/kg,
alkali-hydrolyzable nitrogen 87.99 mg/kg, available
phosphorus 55.78 mg/kg, available potassium 41.96
mg/kg.
2.2 Experimental Design
The pot experiment was conducted at the Chengdu
Campus of Sichuan Agricultural University from
April to October 2019. Perlite was installed in 50-
hole high-bottom hole tray for seedling cultivation,
and the chassis was irrigated with 1 L Hoagland
nutrient solution, which was changed every three
days, and cultured day and night in an artificial
climate chamber between 21°C and 23 °C. Air dried
and crushed the soil, passed through a 5 mm sieve,
and filled each plastic basin (20 cm high, 20 cm
diameter) with 3.0 kg of air dried soil. The
experiment consisted of five treatments, including
rape straw, rice straw, wheat straw, maize straw and
no straw (control). The proportion of straw added to
each pot of soil was 10 g/kg, and the mixture was
evenly mixed. Each treatment was repeated 4 times
(4 pots). All potted plants were watered daily,
always maintaining soil moisture at 80% of field
capacity, and transplanted the peach seedlings after
two weeks. In early May 2019, when the seedlings
grow to 6-8 true leaves (6-9 cm height), the
seedlings with the same growth selected and
transplanted into pots, and 4 seedlings (four
directions) planted in each pot. The plastic basins
(about 15 cm height) were placed completely
randomly and the positions were changed randomly
at random intervals to reduce the influence of edge
effect. According to the water requirement of peach
seedlings, watered in time to ensure that the soil is
moist. After 60 days, the plant height and stem
diameter of each seedlings were measured. The
soluble sugar content of plants was determined by
the anthrone colorimetry method (Xiong 2003).
2.3 Statistical Analysis
Statistical analyses were performed using SPSS 22.0
statistical software. Data were analysed using a one-
way analysis of variance with the least significant
difference test (p ≤ 0.05).
3 RESULTS
3.1 Plant Height
The difference of plant height after rape, rice and
wheat straw treatment reached a significant level
(Fig. 1). The plant height of the seedlings treated
with rape straw was the highest, 27.09 cm, which
increased by 20.51% (p < 0.05) compared with the
control. The plant height of peach seedlings treated
with rice and wheat straw was lower than that of the
control, which decreased by 31.14% (p < 0.05) and
43.86% (p < 0.05), respectively. The order of plant
height was ranked as rape straw > control > maize
straw > rice straw > wheat straw.
Figure 1: Plant height. Different lowercase letters indicate significant differences based on one-way analysis of variance and
the least significant difference test (p ≤ 0.05).
b
a
c
c
b
0
5
10
15
20
25
30
Control Rape Rice Wheat Maize
Treatments
Plant height (cm)-1
ICBEB 2022 - The International Conference on Biomedical Engineering and Bioinformatics
1250
Figure 2: Stem diameter. Different lowercase letters indicate significant differences based on one-way analysis of variance
and the least significant difference test (p ≤ 0.05).
3.2 Stem Diameter
For stem diameter of peach seedlings, the order was
ranked as rape straw > control > maize straw > rice
straw > wheat straw (Fig. 2). Compared with the
control, the rape straw increased the stem diameter
of peach seedlings by 2.86% (p > 0.05), and the rice
straw, wheat straw, and maize straw decreased the
stem diameter by 2.43% (p > 0.05), 4.42% (p <
0.05), and 0.45% (p > 0.05), respectively.
3.3 Soluble Sugar Content
There was a great difference in the soluble sugar
content of peach seedlings in different treatments
(Table 1). Compared with the control, the soluble
sugar contents in roots, stems, and leaves of peach
seedlings reached a significant level after wheat
straw treatment. The order of soluble sugar content
in roots was wheat straw > rice straw > maize straw
> control > rape straw, soluble sugar content in
stems was rape straw > maize straw > control > rice
straw > wheat straw, and soluble sugar content in
leaves was wheat straw > maize straw > rice straw >
control > rape straw. The root and leaf soluble sugar
contents of peach seedlings treated with wheat were
the highest, which were 78.14 mg/g and 97.74 mg/g,
respectively. The soluble sugar content in leaves of
peach seedlings in the rape straw treatment was
49.08 mg/g, which was 10.92% (p < 0.05) higher
than that in the control. There were no significant
differences in soluble sugar content between maize
straw treatment and control.
Table 1 Soluble sugar content
Treatmen
ts
Roots
(mg/g)
Stems
(mg/g)
Leaves
(mg/g)
Control 60.42±1.94c 44.25±1.26b 94.11±0.92b
Rape 58.88±1.43c 49.08±1.67a 93.12±0.75b
Rice 64.50±2.56b 37.93±0.24c 95.59±2.27ab
Wheat 78.14±2.16a 37.91±1.39c 97.74±1.60a
Maize 61.90±1.17bc 43.94± 1.11b 95.12±1.16ab
Different lowercase letters within a column
indicate significant differences based on one-way
analysis of variance and the least significant
difference test (p ≤ 0.05).
4 DISCUSSIONS
Straw plays an important role in the protection of
ecological homes and agricultural environment, and
the necessity of straw utilization is of great value to
the ecological civilization construction advocated by
China (Wang 2020). When rice straw is applied to
wheat crops, it is found that the use of rice straw can
improve the utilization efficiency of potassium
fertilizer and thus increase the yield (Luo 2019).
According to near-infrared spectroscopy analysis,
rice straw contains abundant soluble proteins (Zhao
2017). In this experiment, the effect of rice straw on
plant height and stem diameter of peach seedlings
was shown to decrease. Different from the previous
research results, the preliminary conclusion was that
ab
a
ab
b
ab
2.80
2.85
2.90
2.95
3.00
3.05
3.10
3.15
3.20
3.25
3.30
3.35
Control Rape Rice Wheat Maize
Treatments
Stem diameter (mm)-1
Effects of Crop Straw on the Plant Height, Stem Diameter and Soluble Sugar Content of Peach (Amygdalus davidiana) Seedlings
1251
rice straw had no promoting effect on the growth of
plant height and stem diameter of peach seedlings.
Soluble sugar is an important product of plant
photosynthesis, and its content reflects the intensity
of photosynthesis (Gu 2016). Compared with the
control, the soluble protein content of peach
seedlings treated with rice straw did not change
significantly, indicated that the photosynthesis of
peach seedlings did not increase under the action of
rice straw. Studies have shown that rape straw
returning to the field can increase the aboveground
biomass of maize and improve the nitrogen
absorption of roots (Fu 2016). In this experiment,
rape straw treatment significantly increased the plant
height and stem diameter of peach seedlings which
was consistent with previous experiments. In this
experiment, through the processing of rape straw,
peach seedling soluble sugar content in the stem of
no significant differences compared with controls,
but in the stem, soluble sugar content was
significantly higher than control, preliminary
inference, after the rape straw processing peach
seedling can promote the storage of soluble sugar in
the stem. Maize straw is also widely used in
production, but its effect is not as good as that of
wheat straw and rice straw. In the study of Yue et al.
(Gong 2015), it shows that the application of maize
straw in production could increase soil water
content, but the decrease of soil temperature would
lead to the yield reduction of spring maize.
However, using maize straw in summer maize
planting can increase the yield (Zhang 2014). In this
experiment, compared with control, no significant
increase of maize straw application on plant height,
stem diameter and the content of soluble sugar of
peach seedlings. Studies have found that wheat
straw returning to the field can promote the growth
of maize seedlings, including increasing the stem
diameter and leaf width (Jiang 2014). Mulching with
wheat straw on the soil surface can improve the
yield and quality of pakchoi and tomato (An 2012).
In this experiment, compared with the control, the
plant height and stem diameter of peach seedlings
were significantly decreased after wheat straw
treatment, which was inconsistent with previous
studies. Compared with the control, the soluble
sugar content in stems of seedlings was significantly
decreased after wheat straw treatment, but the
soluble sugar content in the roots and leaves of the
seedlings was significantly higher than that of the
control.
ACKNOWLEDGMENTS
This work was financially supported by the Youth
Fund Project of Chengdu Agricultural College
(20QN04).
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