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Collaborative Influence of Elevated CO2 Concentration and High Temperature on Potato Biomass Accumulation and Characteristics

  • Yao Yubi , Lei Jun EMAIL logo , Niu Haiyang and Zhang Xiuyun EMAIL logo
Published/Copyright: September 25, 2019
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Open Chemistry
From the journal Open Chemistry Volume 17 Issue 1

Abstract

An experiment with OTC (Open-top Chamber) was conducted to study the influence of elevated CO2 concentration and high temperature on potato yields and quality, particularly the collaborative influence of these two factors on the accumulation of aboveground biomass (leaves, petiole, and stem), and underground biomass (root and tuber) in potato, and the influence on potato characteristics. The results showed that the accumulation of dry weight of potato stem and aboveground biomass under the combined treatment of elevated CO2 concentration and high temperature (warming) was significantly higher than that of the control group by 35.8%-53.4% and significantly higher than that of the warming treatment group by 24.4%34.4%. In terms of potato stem and aboveground biomass in the combined treatment group, the occurrence time of peak accumulation was postponed, but the accumulation velocity was increased; the interval days of fast biomass accumulation was prolonged than the warming treatment group and the control group. In this combined treatment experiments, the fresh weight accumulation of potato tuber was lower than the warming treatment group by 5% during the middle stage of tuber formation. But the fresh weight accumulation in the combined treatment was higher than the warming treatment group and the control group during the rest stages of tuber formation: the tuber fresh weight in the mature stage was higher than the warming treatment group and control group by 24.1%, and 3.4%, respectively. In terms of tuber fresh weight in the combined treatment group, the occurrence time of peak accumulation was postponed; the interval days of fast accumulation was prolonged compare to the warming treatment, but close to the control group.

Keywords: climate change; CO2 increase; combined treatment; biomass change; potato

1 Introduction

Potato (Solanum tuberosum L.), the fourth major crop after rice, wheat and maize, is grown in 157 countries; the global planting area is 19,302,642 hm2, and the total yield is 388,190,674 t. In China, the plantation area is 7,767,481 hm2 and the yield is 99,205,580 tone as of 2017, which consists 25.6% of the global yield [1].

Temperature is one of the major climatic factors influencing potato growth and biomass accumulation [2]. The response of potato to temperature in different physiological stages varies a lot [3], as high temperature will influence the plant shape, anatomy, as well as physiological and biochemical changes, which further influences the crop growth, decreases the biomass accumulation, and reduces the economic yield [4]. A research study has revealed that the optimal ambient temperature for potato biomass accumulation is 20°C. Potato growth will accelerate but the crop growth cycle will shorten when the ambient temperature is 25-30°C. Because of shortened growth cycle, photosynthesis process is shortened as well. Due to this shortened photosynthesis, the dry matter distribution is changed, thus, the dry matter accumulated is reduced [5, 6, 7]. An evaluation of a potato growth model in combination with climate change revealed that the potato yield would be decreased by 18%-32% when the simulated air temperature is elevated by 2.1 - 3.2°C. However, adaptive measures including species seed selection, cropping system adjustment and planting structure change, etc. may be taken to reduce the adverse effect of climate change on cropping [8,9]. For example, the potato stomatal conductance, crop net carbon assimilation rate and biomass accumulation would be improved by supplying sufficient water and suitable temperature increasing with day and night temperature between at 20-30 °C [10].

During the whole growing cycle with elevated CO2 concentration, crop assimilation efficiency increased, and the distribution of dry matter accumulation among organs changes. Dry matter accumulation in leaves decreased, while dry matter accumulation in tubers increased. When harvestable, total fresh weight of tubers increased and water utilization efficiency increased. Thus, elevated CO2 concentration is conducive to the improvement of tuber crops such as potatoes [11, 12, 13, 14, 15]. When the CO2 concentration was increased by 370 - 740 μmol∙mol-1, the potato yield in the treatment zone was 27%-49% higher than that in the control [16]. In the combined treatment, when the CO2 concentration was increased by 260-300 μmol∙mol-1, along with the farming temperature rising by 1.5-2.5°C, the potato leaf net photosynthesis rate was higher than the control group. Under this collaborative influence, the net photosynthesis rate in major growing phase, which is from inflorescence formation stage to early tuber expansion stage, was 2.1 times higher than the control group. The water use efficiency was 76.8% higher than the control group. The aboveground biomass (fresh stem weight) was 40.6% higher than the control group. The actual yield was 12.9% higher than the control group [17]. But some negative effect of CO2 concentration multiplying on the yield was found in the experiment [18]; the improved CO2 supply can accelerate leaf aging and flowering period [17,19].

According to AR5 of IPCC, by following representative concentration pathways (RCP 4.5), i.e. it is assumed that human try to reduce the greenhouse emission, and the target radiative forcing is realized and stabilized at 4.5 W∙m-2 by the minimum cost, the equivalent CO2 concentration will be stabilized at 650 μmol×mol-1 after 2100, and the global surface temperature increasing will be controlled within 2.0°C [20].

It is also estimated that the major potato planting regions at the middle latitude of planet will be influenced by temperature increasing in the future decades [21]. When temperature rising and CO2 concentration increasing, how does the biomass in potato’s nutritive organs change? What are the similarities and differences between aboveground biomass accumulation and underground biomass accumulation? These questions require further study. Thus, taking an experiment to study the influence of CO2 concentration increasing and temperature increasing on potato biomass accumulation and analyze their collaborative influence on the dynamic process and characteristic parameters of fresh dry weight accumulation of aboveground potato biomass (stem and leaf) and underground biomass (root and tuber) will build a scientific foundation for studying the influence of climate change on crops and provide references for the adaptation to climate change in semiarid regions.

2 Experimental design and methods

2.1 Experimental design

The experiment was carried out in Dingxi arid meteorology and ecological environment experimental base of Lanzhou Institute of Arid Meteorology, China Meteorological Administration during 2016-2017. The experiment was done in a new type octahedron OTC (Open-top Chamber) of 18 m2 base area and 3 m height. The shape of OTC’s cross section is octagon. Eight flanks are covered by transparent glass and top surface is opened. Free-air CO2 Enrichment (FACE) is open to the environment, and there is no barrier around experimental site. When CO2 gas is supplied, CO2 tends to diffuse to surrounding area, which makes it difficult to control the CO2 concentration at a higher consistent level than the control group’s level. Thus, the CO2 concentration control ability of OTC is better than FACE. As a result, OTC has been widely used as a CO2 concentration multiplying simulation device in related fields at home and abroad.

Two treatments and one control were designed in the experiment: One treatment was conducted by increasing temperature (IT). A temperature monitor was used and the air temperature increasing was controlled at 2.0 ± 0.5°C (1.5-2.5°C); the other treatment was conducted by both increasing temperature (IT) and increasing CO2 concentration (IC) (IT + IC). A CO2 concentration monitor was used and the CO2 concentration was controlled at 650 ± 20 μmol/mol; Control group was set in large farm as control check (CK), and the CO2 concentration in natural air was about 370 μmol/mol. The area of each treatment was 18 m2 in OTC and each treatment was repeated for three times. The experimental farm is flat with uniform fertility. Soil type is loessal soil with alkalescence. During the whole growing cycle, OTC structure, water, fertilizer and field management measures were exactly the same, but the treatments (CO2 and temperature) were different. Diseases and insects were controlled strictly.

The potato variety in the experiment was “New Daping”, which was widely planted in the experimental region. In 2016, potatoes were sown on April 29th and harvested on October 15th, with the row space of 40 cm, and the plant space of 45 cm. In 2017, potatoes were sown on April 29th and harvested on October 11th, with the row space of 45 cm, and the plant space of 50 cm. Tubers were divided into 4-5 pieces, according to positions of bud, and then planted. Each piece weighs about 30 g.

In elevated CO2 concentration treatment, CO2 was supplied continuously from seedling stage to harvestable stage; the CO2 concentration was controlled by a CO2 concentration monitor in the OTC, and CO2 was supplemented between 07:00-19:00 every day.

2.2 Measured items and measuring methods

The growth period covers the sowing stage, seedling stage, branching stage, inflorescence formation stage, flowering stage and harvestable stage [22]. The plant height was observed for 5 continuous plants in each zone (OTC, CK) at the branching stage, inflorescence formation stage, flowering stage and harvestable stage. The density was observed in the branching stage and harvestable stage, and items measured were the width, row spaces, length, hole spaces and the number of plants [22].

The biomass and leaf area were measured respectively at the leaf, petiole, stem and tuber of two individual plants in each zone (OTC, CK) at the branching stage, inflorescence formation stage, flowering stage and harvestable stage. They were measured once per 5 and 10 days after the flowering stage. The biomass measurement included fresh weight measurement (tubers) and dry weight measurement (leaves, petiole, and stem). Fresh weight and dry weight per square meter, water content and growth rate were then calculated as well.

2.3 Data analysis

In each growth cycle, potato biomass is accumulated slowly at beginning, and quickly in a certain stage, and slowly afterwards till the growth is stopped, i.e. it is a dynamic growing process of “increasing rate of accumulation – quick accumulation – slow accumulation”. The accumulation process complies with the Logistic growing curve [23], and can be simulated with Logistic growing curve equation.

The simulating equation for dry matter accumulation is:

y=k1+e(abx)

Where, y is the dry matter; k is the ultimate growth amount under an infinite development time, a and b are regression coefficients, x is the development time, e is the base of the natural logarithm.

From the first derivative of the dry matter accumulation equation, the dry matter accumulation speed function can be obtained:

v=dydx=kbeabx(1+eabx)2

Where, v is the dry matter accumulation speed.

From the first derivative of the dry matter accumulation speed function, and letting dvdx=0,the peak dry matter accumulation time Tmax and the peak dry matter accumulation speed Vmax can be obtained.

From the second derivative of the dry matter accumulation speed function, the following can be obtained:

d2vdx2=d3ydx3=kb3eabx+14eabx+e2a2bx(1+eabx)4

Letting d2vdx2=0,i.e.14eabx+e2a2bx=0, the two characteristic points of the function can be obtained:

x1=aln(2+3)b,x2=aln(23)b

Where, x1 is the time when the dry matter is accumulated from a slow rate to a fast rate, and x2 is the time when the dry matter is accumulated from a slow rate to a fast rate [24].

The data were processed with statistical test method, linear regression, non-linear regression and F-test. The significance level P≤0.05.

Ethical approval: The conducted research is not related to either human or animal use.

3 Result and analysis

3.1 Influence of CO2 concentration increasing and temperature increasing on potato leaf dry matter accumulation

Fig 1 shows that from the potato seedling stage to the branching stage, the dry matter accumulation of leaves in IT is higher than CK by 14%-35.6% (averagely 24.6%), and it is even higher than IT + IC by 19.9%-46.2% (averagely 33.4%). The result of the experiment reveals that the potato leaf growth and the biomass accumulation were improved in the sowing stage, seedling stage and branching stage. From the inflorescence formation stage to harvestable stage, the dry matter accumulation of leaves in IT + IC is 11.8%-35.6% (averagely 29.9%) higher than CK, 11.9%50.6% (averagely 41.3%) higher than in IT.

Figure 1 Dynamic simulation curve of dry matter accumulation for potato leaves in different treatments.
Figure 1

Dynamic simulation curve of dry matter accumulation for potato leaves in different treatments.

This result indicates that high temperatures can stimulate dry matter accumulation in leaves.

The peak time (Tmax) of dry matter accumulation of leaves in IT + IC combined treatment was at the 86th day after sowing. Tmax was respectively 15 days and 8 days later than IT and CK. The peak accumulation speed (Vmax) was 2.9 g/(m2·d), respectively increased by 1.9 g/(m2·d) and 1.6 g/(m2·d). At the 61st day after sowing, the dry matter accumulation was transferred from slow process to quick process (x1), which was postponed 26 days and 13 days respectively when compared to IT and CK. At the 112nd day after sowing, the dry matter accumulation was transferred from quick process to slow process (x2), which was postponed by 5 days and 4 days respectively, when compared to IT and CK. The interval days of quick dry matter accumulation were 51 days, which is reduced by 21 days and 9 days respectively (Table 1).

Table 1

Dynamic simulation and characteristic parameters of dry matter accumulation for potato leaf in different treatments.

TreatmentDry matter accumulation modelFirst derivativeTmax/dVmax/ g/(m2·d)X1/dX2/d(X2- X1) /dFP
ITy=105.101/(1+e2.602- 0.0365x)dy/dx=3.836 e2.602-0.0365x / (1+e2.602-0.0365x)2711.035107728.814≤0.05
IT + ICy=155.12/(1+e4.48-0.052x)dy/dx=8.066 e4.48-0.052x / (1+e4.48-0.052x)862.9611125122.839≤0.01
CKy=115.21/(1+e3.42-0.0438x)dy/dx=5.046 e3.42-0.0438x / (1+ e3.42-0.0438x)2781.348108608.645≤0.05

For IT + IC treatment, the peak accumulation time is postponed; the peak accumulation speed is improved; the quick accumulation period is shortened.

3.2 Influence of CO2 concentration increasing and temperature increasing on potato petiole dry matter accumulation

From the potato seedling stage to branching stage, the dry matter accumulation of petiole in IT was 15.8%23.1% (averagely 19.6%) (Figure 2) higher than CK, 13.2%27.1% (averagely 20.3%) higher than IT + IC. From the inflorescence formation stage to harvestable stage, the dry matter accumulation of petiole in IT + IC was 34.8%122.2% (averagely 88.0%) higher than CK, 6.7%-104.7% (averagely 60.1%) higher than IT.

Figure 2 Dynamic simulation curve of dry matter accumulation for potato petiole in different treatments.
Figure 2

Dynamic simulation curve of dry matter accumulation for potato petiole in different treatments.

It reveals that from seedling stage to branching stage, potato petiole growth was accelerated in IT, and biomass accumulation was higher than CK and IT+IC. From inflorescence formation stage to harvestable stage, the dry matter accumulation of petiole in IT+IC was significantly higher than IT.

The peak petiole dry matter accumulation time in IT + IC was at the 118th day after sowing, respectively 29 days and 12 days later than IT and CK. The peak petiole dry matter accumulation speed was 0.6 g/(m2·d), which was 0.4 g/(m2·d) higher than IT and CK. The dry matter accumulation of petiole was transferred from slow process to quick process at the 82nd day after sowing, which was postponed by 34 days and 25 days respectively when compared to IT and CK. Then transferred from quick process to slow process at the 154th day after sowing, which was postponed by 24 days in comparison with IT but basically close to CK. The quick accumulation period of petiole dry matter was 72 days, which was reduced by 10 days and 26 days respectively (Table 2).

Table 2

Dynamic simulation and characteristic parameters of dry matter accumulation for potato petiole in different treatments.

TreatmentDry matter accumulation modelFirst derivativeTmax/dVmax/ g/(m2·d)X1/dX2/d(X2- X1) /dFP
ITy=27.429/(1+e2.867- 0.0323x)dy/dx=0.886 e2.867-0.0323x / (1+ e2.867-0.0323x)2890.2481308215.149≤0.01
IT + ICy=61.162/(1+e4.304- 0.0364x)dy/dx=2.226 e4.304-0.0364x / (1+ e4.304-0.0364x)1180.6821547251.489≤0.01
CKy=28.11/(1+e2.833-0.0267x)dy/dx=0.751e2.833-0.0267x / (1+ e2.833-0.0267x)21060.2571559816.250≤0.01

For the petiole under IT + IC treatment, the peak accumulation time was significantly postponed; the peak accumulation speed was improved; the quick accumulation period was shortened.

3.3 Influence of CO2 concentration increasing and temperature increasing on potato stem dry matter accumulation

The dynamic simulating curve (Figure 3) shows that the potato stem dry matter accumulation in IT + IC was 23.2%61.8% (averagely 34.4%) higher than IT, 25.9%-105.5% (averagely 53.4%) higher than CK; from seedling stage to early tuber expansion stage in IT, the potato stem dry matter accumulation was 4.6%-27.7% (averagely 21.0%) higher than CK; in later tuber expansion stage, stem dry matter accumulation speed was decreased, which was 2.8%-5.8% (averagely 4.4%) lower than CK.

Figure 3 Dynamic simulation curve of dry matter accumulation for potato stem in different treatments.
Figure 3

Dynamic simulation curve of dry matter accumulation for potato stem in different treatments.

It indicates that the potato stem dry matter accumulation in IT + IC is higher than IT and CK.

The peak dry matter accumulation time for potato stem in IT + IC was at the 113rd day after sowing, 4 days later than IT and 2 days earlier than CK. The peak dry matter accumulation speed was 2.9 g/(m2·d), 0.6 g/(m2·d) and 0.5 g/(m2·d) respectively higher than IT and CK; the dry matter accumulation in stem was transferred from slow process to quick process at the 90th day after sowing, 2 days later than IT and 4 days earlier than CK. Then transferred from quick process to slow process at the 136th day after sowing, 6 days later than IT and 1 day earlier than CK; the quick accumulation period of dry matter in stem was 46 days, 4 days longer than IT and 3 days longer than CK (Table 3).

Table 3

Dynamic simulation and characteristic parameters of dry matter accumulation for potato stem in different treatments.

TreatmentDry matter accumulation modelFirst derivativeTmax/dVmax/ g/(m2·d)X1/dX2/d(X2- X1) /dFP
ITy=146.43/(1+e6.87-0.0628x)dy/dx=9.195 e6.87-0.0628x /(1+ e6.87-0.0628x)21092.3881304231.041≤0.01
IT + ICy=199.59/(1+e6.455-0.0572x)dy/dx=11.417 e6.455- 0.0572x /(1+ e6.455-0.0572x)1132.9901364628.613≤0.01
CKy=157.84/(1+e7.154-0.0620x)dy/dx=9.786 e7.154-0.0620x /(1+ e7.154-0.0620x)21152.4941374362.575≤0.01

For stem under IT + IC treatment, the peak accumulation speed was improved; the peak accumulation time was postponed compared to IT and advanced compared to CK; the quick accumulation period was prolonged in comparison with IT and CK.

3.4 Influence of CO2 concentration increasing and temperature increasing on potato aboveground dry matter accumulation

The potato aboveground dry matter accumulation in IT + IC was 12.2%-42.2% (averagely 24.4%) higher than IT, and 23.4%-56.2% (averagely 35.8%) higher than CK. The potato aboveground dry matter accumulation in IT was 23.4%56.2% (averagely 35.8%) higher than CK (Figure 4).

Figure 4 Dynamic simulation curve of dry matter accumulation for potato aboveground part in different treatments.
Figure 4

Dynamic simulation curve of dry matter accumulation for potato aboveground part in different treatments.

It reveals that from seedling stage to harvestable stage, the potato aboveground dry matter accumulation in IT + IC was averagely 24.4% and 35.8% higher than IT and CK respectively, while the accumulation in IT treatment is averagely 35.8% higher than CK.

The dynamic simulating curve (Table. 4) shows that the peak dry matter accumulation time for potato aboveground part in IT + IC was at the 105th day after sowing, 9 days and 8 days respectively later than IT and CK; the peak dry matter accumulation speed was 4.7 g/(m2·d), which was 1.3 g/(m2·d) and 1.1 g/(m2·d) higher than IT and CK, respectively. The aboveground dry matter accumulation was transferred from slow process to quick process at the 75th day after sowing, which was postponed by 7 days and 4 days compared to IT and CK, respectively. Then the aboveground dry matter accumulation was transferred from quick process to slow process at the 134th day after sowing, which was postponed by 10 days and 12 days compared to IT and CK, respectively. The quick aboveground dry matter accumulation period was 59 days, 3 days longer than IT and 8 days longer than CK.

Table 4

Dynamic simulation and characteristic parameters of dry matter accumulation for potato aboveground part in different treatments.

TreatmentDry matter accumulation modelFirst derivativeTmax/dVmax/ g/(m2·d)X1/dX2/d(X2- X1) /dFP
ITy=287.23/(1+e4.538-0.0472x)dy/dx=13.557 e4.538-0.0472x /(1+ e4.538-0.0472x)2963.4681245623.625≤0.01
IT + ICy=419.56/(1+e4.704-0.0449x)dy/dx=18.838 e4.704-0.0449x /(1+ e4.704-0.0449x)1054.7751345917.815≤0.01
CKy=277.42/(1+e5.065-0.0525x)dy/dx=14.565 e5.065-0.0525x /(1+ e5.065-0.0525x)2973.6711225167.468≤0.01

The peak dry matter accumulation speed for potato aboveground part in IC+IT was improved in comparison with IT and CK. The peak accumulation time was postponed in comparison with IT and CK. The quick accumulation period was prolonged than IT and CK.

3.5 Influence of CO2 concentration increasing and temperature increasing on potato root dry matter accumulation

From potato sowing stage to branching stage, the dry matter accumulation for potato root in IT + IC was 1.3%1.8% (averagely 1.7%) (Figure 5) lower than IT, 3.1%17.7% and averagely 10.4% lower than CK; the dry matter accumulation in IT was 1.42%-16.21% (averagely 8.8%) lower than CK. From inflorescence formation stage to harvestable stage, the dry matter accumulation in IT + IC was 0.97%-5.6% (averagely 3.4%) higher than IT, and 4.2%-43.2% (averagely 28.3%) higher than CK. The dry matter accumulation in IT was 5.6%-35.6% (averagely 25.4%) higher than CK.

Figure 5 Dynamic simulation curve of dry matter accumulation for potato root in different treatments.
Figure 5

Dynamic simulation curve of dry matter accumulation for potato root in different treatments.

From sowing stage to branching stage, the potato root dry matter accumulation in IT + IC was lower than IT and CK. From inflorescence formation stage to harvestable stage, the potato root dry matter accumulation in IT + IC was higher than IT and significantly higher than CK.

The peak time of dry matter accumulation for potato root in IT + IC is at the 82nd day after sowing, which was 7 days and 32 days later than IT and CK, respectively. While the peak speed of dry matter accumulation was 0.19 g/(m2·d), which was 0.01 g/(m2·d) and 0.09 g/(m2·d) higher than IT and CK, respectively. The dry matter accumulation in root was transferred from slow process to quick process at the 32nd day after sowing, which was 4 days and 2 days later than IT and CK, respectively. Then it was transferred from quick process to slow process at the 131st day after sowing, which was 9 days and 17 days later than IT and CK, respectively. The quick accumulation period of dry matter in root under IT + IC is 99 days, which was prolonged by 4 days and 15 days in comparison with IT and CK. (Table 5).

Table 5

Dynamic simulation and characteristic parameters of dry matter accumulation for potato root in different treatments.

TreatmentDry matter accumulation modelFirst derivativeTmax/dVmax/ g/(m2·d)X1/dX2/d(X2- X1) /dFP
ITy=25.96/(1+e2.098-0.0279x)dy/dx=0.724 e2.098-0.0279x / (1+ e2.098-0.0279x)2750.18281229416.246≤0.01
IT + ICy=28.12/(1+e2.177-0.0266x)dy/dx=0.748 e2.177-0.0266x / (1+ e2.177-0.0266x)820.19321319918.367≤0.01
CKy=19.36/(1+e1.034-0.0206x)dy/dx=0.399 e1.034-0.0206x / (1+ e1.034-0.0206x)2500.1030114847.267≤0.05

For root under IT + IC treatment, the peak accumulation time was postponed; the peak accumulation speed was improved; the quick accumulation period was prolonged.

3.6 Influence of CO2 concentration increasing and temperature increasing on potato tuber (fresh weight) accumulation

The fresh weight accumulation in potato tuber under IT + IC was 0.7%-25.0% (averagely 8.0%) higher than CK (Figure 6). In IT + IC, the fresh weight accumulation in potato tuber was different from IT at each growing stage. In the early stage of potato tuber accumulation, the fresh weight accumulation in IT is 8.8%-89.7% (averagely 58.5%) lower than IT + IC. In the middle stage, the fresh weight accumulation in IT was 1.7%-7.1% (averagely 4.4%) higher than IT + IC. In the late stage, the fresh weight accumulation in IT was 8.6%-19.4% (averagely 14.5%) lower than IT + IC.

Figure 6 Dynamic simulation curve of fresh potato tuber in different treatments.
Figure 6

Dynamic simulation curve of fresh potato tuber in different treatments.

The fresh weight accumulation of tuber in IT + IC was higher than CK. The fresh weight accumulation of tuber in IT + IC was lower than IT in the middle stage of tuber accumulation, but higher than IT in other stages of tuber accumulation.

The peak time for fresh weight accumulation of potato tuber in IT + IC was at the 127th day after sowing, which was 6 days later than IT and basically close to CK. While the peak speed of fresh weight accumulation for potato tuber was 61.5 g/(m2·d), which was 12.1g/(m2·d) lower than IT and basically close to CK. The fresh weight accumulation of tuber in IT + IC was transferred from slow process to quick process at the 111st day after sowing, which was close to IT and CK. Then it transferred from quick process to slow process at the 144th day after sowing, which was 13 days later than IT and basically close to CK. The quick fresh weight accumulation period of tuber was 33 days, which was prolonged by 12 days in comparison with IT and close to CK (Table 6).

Table 6

Dynamic simulation and characteristic parameters of fresh potato tuber in different treatments.

TreatmentDry matter accumulation modelFirst derivativeTmax/dVmax/ g/(m2·d)X1/dX2/d(X2- X1) /dFP
ITy=2375.25/(1+e14.959- 0.1239x)dy/dx=294.29 e14.959-0.1239x / (1+ e14.959-0.1239x)212173.611013121222.299≤0.01
IT + ICy=3081.56/(1+e10.165- 0.0798x)dy/dx=245.91 e10.165-0.0798x / (1+ e10.165-0.0798x)12761.51111443352.579≤0.01
CKy=2950.36/(1+e10.598- 0.0838x)dy/dx=247.24 e10.598-0.0838x / (1+ e10.598-0.0838x)212661.81111423148.010≤0.01

For potato tuber under IT + IC treatment, the peak accumulation period was later than IT, and the quick accumulation period was longer than IT but close to CK.

4 Discussion

From the seedling stage to the branching stage, the ambient temperature is lower than the suitable threshold for potato growth, the leading factor determining the biomass accumulation is the air temperature. The biomass accumulation of potato leaves and petiole is promoted by single temperature increasing. Biomass accumulation speed is higher than CK and the combined IT+IC treatment. In inflorescence formation stage, with the enlargement of leaf area index, the temperature increasing effect is gradually reduced. The intercellular CO2 concentration is increased by the combined IT+IC treatment [25]. This causes the sufficient material supply for potato leaf photosynthesis, and the net photosynthesis rate is improved as well [26] As a result, the biomass accumulation on leaf and petiole is quickened and much larger than CK and IT. But the leaf aging in IT treatment is also quickened. The biomass accumulation is not only lower than combined IT+IC treatment, but also lower than CK [11,27].

From inflorescence formation stage to harvestable stage, the net photosynthesis rate was improved by the combined treatment with elevated temperature and CO2 concentration[17]; the biomass accumulation in the leaf and petiole is significantly improved. When the peak biomass and dry matter accumulation time are postponed, the peak accumulation speed is improved correspondingly. A slight increase in stage for accumulation in the leaf has significantly prolonged petiole, and the quick accumulation period is distinctly shortened.

The characteristic of biomass accumulation changes vary in potato stem, leaf and petiole. From seedling stage to harvestable stage, the potato stem dry matter accumulation under combined IT+IC treatment is averagely 34.4% and 21.0% higher than IT and CK, respectively. Due to the leading effect of stem biomass accumulation from seedling stage to harvestable stage, the biomass accumulation for potato aboveground part under the combined IT+IC treatment is higher than IT and CK [11, 12, 13, 14, 15].

The tuber accumulation under the combined IT+IC treatment is lower than IT only in middle stage but higher in other stages. The fresh weight accumulation of tuber under the combined IT+IC treatment is higher than CK. The accumulation in IT treatment is higher than CK only in middle stage but lower in other stages. Potato is suitable to grow in a cool condition. For IT treatment, ambient temperature increases above the suitable threshold temperature for potato growth in later tuber expansion stage, which will inhibit the tuber formation. On the other hand, elevated temperature and elevated CO2 concentration simultaneously will promote the organic accumulation, which can accelerate the tuber expansion and improve the yield [9,16,17]. The increase of CO2 concentration is beneficial to the improvement and production of potato and other tuber crops in the future, and is conducive to the improvement of crop water use efficiency [14, 21].

The experiment has clarified the main characteristics of the co-influence of elevated temperature and elevated CO2 concentration on potato biomass, and created potato biomass accumulation models for different treatments. But it still need further study on impact and mechanism of future climate change [17, 29, 30].

5 Conclusion

Elevated temperature can stimulate the accumulation of dry matter, accelerate the growth of leaf, and increase the accumulation of biomass. For the leaf and petiole treated by this combined treatment, the peak accumulation time was postponed; the peak accumulation speed was improved; the quick accumulation period was shortened.

In the whole growth stages, the dry matter accumulation for potato stem and aboveground part in the combined IT+IC treatment is significantly higher than CK and IT. For potato stem and aboveground part with this combined treatment, in comparison with IT and CK, the peak dry matter accumulation is postponed; the peak accumulation speed is improved; the quick accumulation period is prolonged.

The tuber accumulation in the combined treatment group is lower than IT treatment only in middle stage but higher in other stages. The tuber fresh weight accumulation in the combined treatment group is higher than CK. In the combined treatment group, the peak accumulation time was postponed and the quick accumulation period was prolonged in comparison with IT treatment, but was close to CK.

  1. Project funded by

    National Natural Science Fund (41575149, 41505099); Special scientific research project (one of Major special projects) of Public Welfare Industry (Meteorology) (GYHY201506001-6); National Program on Key Basic Research Project (973 Program) (2013CB430206)

  2. Conflict of interest

    Authors declare no conflict of interest.

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Received: 2018-12-18
Accepted: 2019-04-05
Published Online: 2019-09-25

© 2019 Yao Yubi et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 Public License.

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https://doi.org/10.1515/chem-2019-0085
Keywords for this article
climate change; CO2 increase; combined treatment; biomass change; potato
Creative Commons
BY 4.0

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  33. Chiral and Achiral Enantiomeric Separation of (±)-Alprenolol
  34. Correlation of Water Fluoride with Body Fluids, Dental Fluorosis and FT4, FT3 –TSH Disruption among Children in an Endemic Fluorosis area in Pakistan
  35. A one-step incubation ELISA kit for rapid determination of dibutyl phthalate in water, beverage and liquor
  36. Free Radical Scavenging Activity of Essential Oil of Eugenia caryophylata from Amboina Island and Derivatives of Eugenol
  37. Effects of Blue and Red Light On Growth And Nitrate Metabolism In Pakchoi
  38. miRNA-199a-5p functions as a tumor suppressor in prolactinomas
  39. Solar photodegradation of carbamazepine from aqueous solutions using a compound parabolic concentrator equipped with a sun tracking system
  40. Influence of sub-inhibitory concentration of selected plant essential oils on the physical and biochemical properties of Pseudomonas orientalis
  41. Preparation and spectroscopic studies of Fe(II), Ru(II), Pd(II) and Zn(II) complexes of Schiff base containing terephthalaldehyde and their transfer hydrogenation and Suzuki-Miyaura coupling reaction
  42. Complex formation in a liquid-liquid extraction-chromogenic system for vanadium(IV)
  43. Synthesis, characterization (IR, 1H, 13C & 31P NMR), fungicidal, herbicidal and molecular docking evaluation of steroid phosphorus compounds
  44. Analysis and Biological Evaluation of Arisaema Amuremse Maxim Essential Oil
  45. A preliminary assessment of potential ecological risk and soil contamination by heavy metals around a cement factory, western Saudi Arabia
  46. Anti- inflammatory effect of Prunus tomentosa Thunb total flavones in LPS-induced RAW264.7 cells
  47. Collaborative Influence of Elevated CO2 Concentration and High Temperature on Potato Biomass Accumulation and Characteristics
  48. Methods of extraction, physicochemical properties of alginates and their applications in biomedical field – a review
  49. Characteristics of liposomes derived from egg yolk
  50. Preparation of ternary ZnO/Ag/cellulose and its enhanced photocatalytic degradation property on phenol and benzene in VOCs
  51. Influence of Human Serum Albumin Glycation on the Binding Affinities for Natural Flavonoids
  52. Synthesis and antioxidant activity of 2-methylthio-pyrido[3,2-e][1,2,4] triazolo[1,5-a]pyrimidines
  53. Comparative study on the antioxidant activities of ten common flower teas from China
  54. Molecular Properties of Symmetrical Networks Using Topological Polynomials
  55. Synthesis of Co3O4 Nano Aggregates by Co-precipitation Method and its Catalytic and Fuel Additive Applications
  56. Phytochemical analysis, Antioxidant and Antiprotoscolices potential of ethanol extracts of selected plants species against Echinococcus granulosus: In-vitro study
  57. Silver nanoparticles enhanced fluorescence for sensitive determination of fluoroquinolones in water solutions
  58. Simultaneous Quantification of the New Psychoactive Substances 3-FMC, 3-FPM, 4-CEC, and 4-BMC in Human Blood using GC-MS
  59. Biodiesel Production by Lipids From Indonesian strain of Microalgae Chlorella vulgaris
  60. Miscibility studies of polystyrene/polyvinyl chloride blend in presence of organoclay
  61. Antibacterial Activities of Transition Metal complexes of Mesocyclic Amidine 1,4-diazacycloheptane (DACH)
  62. Novel 1,8-Naphthyridine Derivatives: Design, Synthesis and in vitro screening of their cytotoxic activity against MCF7 cell line
  63. Investigation of Stress Corrosion Cracking Behaviour of Mg-Al-Zn Alloys in Different pH Environments by SSRT Method
  64. Various Combinations of Flame Retardants for Poly (vinyl chloride)
  65. Phenolic compounds and biological activities of rye (Secale cereale L.) grains
  66. Oxidative degradation of gentamicin present in water by an electro-Fenton process and biodegradability improvement
  67. Optimizing Suitable Conditions for the Removal of Ammonium Nitrogen by a Microbe Isolated from Chicken Manure
  68. Anti-inflammatory, antipyretic, analgesic, and antioxidant activities of Haloxylon salicornicum aqueous fraction
  69. The anti-corrosion behaviour of Satureja montana L. extract on iron in NaCl solution
  70. Interleukin-4, hemopexin, and lipoprotein-associated phospholipase A2 are significantly increased in patients with unstable carotid plaque
  71. A comparative study of the crystal structures of 2-(4-(2-(4-(3-chlorophenyl)pipera -zinyl)ethyl) benzyl)isoindoline-1,3-dione by synchrotron radiation X-ray powder diffraction and single-crystal X-ray diffraction
  72. Conceptual DFT as a Novel Chemoinformatics Tool for Studying the Chemical Reactivity Properties of the Amatoxin Family of Fungal Peptides
  73. Occurrence of Aflatoxin M1 in Milk-based Mithae samples from Pakistan
  74. Kinetics of Iron Removal From Ti-Extraction Blast Furnace Slag by Chlorination Calcination
  75. Increasing the activity of DNAzyme based on the telomeric sequence: 2’-OMe-RNA and LNA modifications
  76. Exploring the optoelectronic properties of a chromene-appended pyrimidone derivative for photovoltaic applications
  77. Effect of He Qi San on DNA Methylation in Type 2 Diabetes Mellitus Patients with Phlegm-blood Stasis Syndrome
  78. Cyclodextrin potentiometric sensors based on selective recognition sites for procainamide: Comparative and theoretical study
  79. Greener synthesis of dimethyl carbonate from carbon dioxide and methanol using a tunable ionic liquid catalyst
  80. Nonisothermal Cold Crystallization Kinetics of Poly(lactic acid)/Bacterial Poly(hydroxyoctanoate) (PHO)/Talc
  81. Enhanced adsorption of sulfonamide antibiotics in water by modified biochar derived from bagasse
  82. Study on the Mechanism of Shugan Xiaozhi Fang on Cells with Non-alcoholic Fatty Liver Disease
  83. Comparative Effects of Salt and Alkali Stress on Antioxidant System in Cotton (Gossypium Hirsutum L.) Leaves
  84. Optimization of chromatographic systems for analysis of selected psychotropic drugs and their metabolites in serum and saliva by HPLC in order to monitor therapeutic drugs
  85. Electrocatalytic Properties of Ni-Doped BaFe12O19 for Oxygen Evolution in Alkaline Solution
  86. Study on the removal of high contents of ammonium from piggery wastewater by clinoptilolite and the corresponding mechanisms
  87. Phytochemistry and toxicological assessment of Bryonia dioica roots used in north-African alternative medicine
  88. The essential oil composition of selected Hemerocallis cultivars and their biological activity
  89. Mechanical Properties of Carbon Fiber Reinforced Nanocrystalline Nickel Composite Electroforming Deposit
  90. Anti-c-myc efficacy block EGFL7 induced prolactinoma tumorigenesis
  91. Topical Issue on Applications of Mathematics in Chemistry
  92. Zagreb Connection Number Index of Nanotubes and Regular Hexagonal Lattice
  93. The Sanskruti index of trees and unicyclic graphs
  94. Valency-based molecular descriptors of Bakelite network BNmn
  95. Computing Topological Indices for Para-Line Graphs of Anthracene
  96. Zagreb Polynomials and redefined Zagreb indices of Dendrimers and Polyomino Chains
  97. Topological Descriptor of 2-Dimensional Silicon Carbons and Their Applications
  98. Topological invariants for the line graphs of some classes of graphs
  99. Words for maximal Subgroups of Fi24
  100. Generators of Maximal Subgroups of Harada-Norton and some Linear Groups
  101. Special Issue on POKOCHA 2018
  102. Influence of Production Parameters on the Content of Polyphenolic Compounds in Extruded Porridge Enriched with Chokeberry Fruit (Aronia melanocarpa (Michx.) Elliott)
  103. Effects of Supercritical Carbon Dioxide Extraction (SC-CO2) on the content of tiliroside in the extracts from Tilia L. flowers
  104. Impact of xanthan gum addition on phenolic acids composition and selected properties of new gluten-free maize-field bean pasta
  105. Impact of storage temperature and time on Moldavian dragonhead oil – spectroscopic and chemometric analysis
  106. The effect of selected substances on the stability of standard solutions in voltammetric analysis of ascorbic acid in fruit juices
  107. Determination of the content of Pb, Cd, Cu, Zn in dairy products from various regions of Poland
  108. Special Issue on IC3PE 2018 Conference
  109. The Photocatalytic Activity of Zns-TiO2 on a Carbon Fiber Prepared by Chemical Bath Deposition
  110. N-octyl chitosan derivatives as amphiphilic carrier agents for herbicide formulations
  111. Kinetics and Mechanistic Study of Hydrolysis of Adenosine Monophosphate Disodium Salt (AMPNa2) in Acidic and Alkaline Media
  112. Antimalarial Activity of Andrographis Paniculata Ness‘s N-hexane Extract and Its Major Compounds
  113. Special Issue on ABB2018 Conference
  114. Special Issue on ICCESEN 2017
  115. Theoretical Diagnostics of Second and Third-order Hyperpolarizabilities of Several Acid Derivatives
  116. Determination of Gamma Rays Efficiency Against Rhizoctonia solani in Potatoes
  117. Studies On Compatibilization Of Recycled Polyethylene/Thermoplastic Starch Blends By Using Different Compatibilizer
  118. Liquid−Liquid Extraction of Linalool from Methyl Eugenol with 1-Ethyl-3-methylimidazolium Hydrogen Sulfate [EMIM][HSO4] Ionic Liquid
  119. Synthesis of Graphene Oxide Through Ultrasonic Assisted Electrochemical Exfoliation
  120. Special Issue on ISCMP 2018
  121. Synthesis and antiproliferative evaluation of some 1,4-naphthoquinone derivatives against human cervical cancer cells
  122. The influence of the grafted aryl groups on the solvation properties of the graphyne and graphdiyne - a MD study
  123. Electrochemical modification of platinum and glassy carbon surfaces with pyridine layers and their use as complexing agents for copper (II) ions
  124. Effect of Electrospinning Process on Total Antioxidant Activity of Electrospun Nanofibers Containing Grape Seed Extract
  125. Effect Of Thermal Treatment Of Trepel At Temperature Range 800-1200˚C
  126. Topical Issue on Agriculture
  127. The effect of Cladophora glomerata exudates on the amino acid composition of Cladophora fracta and Rhizoclonium sp.
  128. Influence of the Static Magnetic Field and Algal Extract on the Germination of Soybean Seeds
  129. The use of UV-induced fluorescence for the assessment of homogeneity of granular mixtures
  130. The use of microorganisms as bio-fertilizers in the cultivation of white lupine
  131. Lyophilized apples on flax oil and ethyl esters of flax oil - stability and antioxidant evaluation
  132. Production of phosphorus biofertilizer based on the renewable materials in large laboratory scale
  133. Human health risk assessment of potential toxic elements in paddy soil and rice (Oryza sativa) from Ugbawka fields, Enugu, Nigeria
  134. Recovery of phosphates(V) from wastewaters of different chemical composition
  135. Special Issue on the 4th Green Chemistry 2018
  136. Dead zone for hydrogenation of propylene reaction carried out on commercial catalyst pellets
  137. Improved thermally stable oligoetherols from 6-aminouracil, ethylene carbonate and boric acid
  138. The role of a chemical loop in removal of hazardous contaminants from coke oven wastewater during its treatment
  139. Combating paraben pollution in surface waters with a variety of photocatalyzed systems: Looking for the most efficient technology
  140. Special Issue on Chemistry Today for Tomorrow 2019
  141. Applying Discriminant and Cluster Analyses to Separate Allergenic from Non-allergenic Proteins
  142. Chemometric Expertise Of Clinical Monitoring Data Of Prolactinoma Patients
  143. Chemomertic Risk Assessment of Soil Pollution
  144. New composite sorbent for speciation analysis of soluble chromium in textiles
  145. Photocatalytic activity of NiFe2O4 and Zn0.5Ni0.5Fe2O4 modified by Eu(III) and Tb(III) for decomposition of Malachite Green
  146. Photophysical and antibacterial activity of light-activated quaternary eosin Y
  147. Spectral properties and biological activity of La(III) and Nd(III) Monensinates
  148. Special Issue on Monitoring, Risk Assessment and Sustainable Management for the Exposure to Environmental Toxins
  149. Soil organic carbon mineralization in relation to microbial dynamics in subtropical red soils dominated by differently sized aggregates
  150. A potential reusable fluorescent aptasensor based on magnetic nanoparticles for ochratoxin A analysis
  151. Special Issue on 13th JCC 2018
  152. Fluorescence study of 5-nitroisatin Schiff base immobilized on SBA-15 for sensing Fe3+
  153. Thermal and Morphology Properties of Cellulose Nanofiber from TEMPO-oxidized Lower part of Empty Fruit Bunches (LEFB)
  154. Encapsulation of Vitamin C in Sesame Liposomes: Computational and Experimental Studies
  155. A comparative study of the utilization of synthetic foaming agent and aluminum powder as pore-forming agents in lightweight geopolymer synthesis
  156. Synthesis of high surface area mesoporous silica SBA-15 by adjusting hydrothermal treatment time and the amount of polyvinyl alcohol
  157. Review of large-pore mesostructured cellular foam (MCF) silica and its applications
  158. Ion Exchange of Benzoate in Ni-Al-Benzoate Layered Double Hydroxide by Amoxicillin
  159. Synthesis And Characterization Of CoMo/Mordenite Catalyst For Hydrotreatment Of Lignin Compound Models
  160. Production of Biodiesel from Nyamplung (Calophyllum inophyllum L.) using Microwave with CaO Catalyst from Eggshell Waste: Optimization of Transesterification Process Parameters
  161. The Study of the Optical Properties of C60 Fullerene in Different Organic Solvents
  162. Composite Material Consisting of HKUST-1 and Indonesian Activated Natural Zeolite and its Application in CO2 Capture
  163. Topical Issue on Environmental Chemistry
  164. Ionic liquids modified cobalt/ZSM-5 as a highly efficient catalyst for enhancing the selectivity towards KA oil in the aerobic oxidation of cyclohexane
  165. Application of Thermal Resistant Gemini Surfactants in Highly Thixotropic Water-in-oil Drilling Fluid System
  166. Screening Study on Rheological Behavior and Phase Transition Point of Polymer-containing Fluids produced under the Oil Freezing Point Temperature
  167. The Chemical Softening Effect and Mechanism of Low Rank Coal Soaked in Alkaline Solution
  168. The Influence Of NO/O2 On The NOx Storage Properties Over A Pt-Ba-Ce/γ-Al2O3 Catalyst
  169. Special Issue on the International conference CosCI 2018
  170. Design of SiO2/TiO2 that Synergistically Increases The Hydrophobicity of Methyltrimethoxysilane Coated Glass
  171. Antidiabetes and Antioxidant agents from Clausena excavata root as medicinal plant of Myanmar
  172. Development of a Gold Immunochromatographic Assay Method Using Candida Biofilm Antigen as a Bioreceptor for Candidiasis in Rats
  173. Special Issue on Applied Biochemistry and Biotechnology 2019
  174. Adsorption of copper ions on Magnolia officinalis residues after solid-phase fermentation with Phanerochaete chrysosporium
  175. Erratum
  176. Erratum to: Sand Dune Characterization For Preparing Metallurgical Grade Silicon
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