Crops ›› 2020, Vol. 36 ›› Issue (6): 132-136.doi: 10.16035/j.issn.1001-7283.2020.06.019

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Effects of Root Promoting Agent on the Development and Yield in Single Bud of Sugarcane

Xu Lin(), Wu Kaichao, Pang Tian, Deng Zhinian, Zhang Ronghua, Huang Chengfeng, Huang Hairong, Li Yijie, Liu Xiaoyan, Qin Wenxian, Wang Weizan()   

  1. Sugarcane Research Institute, Guangxi Academy of Agricultural Sciences/Key Laboratory of Sugarcane Biotechnology and Genetic Improvement (Guangxi), Ministry of Agriculture and Rural Affairs, Nanning 530007, Guangxi, China
  • Received:2020-03-20 Revised:2020-07-15 Online:2020-12-15 Published:2020-12-09
  • Contact: Wang Weizan E-mail:xulin1105@126.com;wwz003411@126.com

Abstract:

In order to innovate and to optimize the high-yield and high-efficiency cultivation technology of sugarcane, the effects of root promoting agents on agronomic characters, physiological and biochemical indexes, quality and yield of sugarcane were studied. The results showed that coating+50mg/L root promoting agent (T1), coating+100mg/L root promoting agent (T2) and coating (CK1) significantly increased the germination rate, tillering rate, plant height and number of millable stalks, by compared with not coating (CK2). The sugarcane yield of T1, T2 and CK1 were significant higher than CK2 by 27.5%, 9.2% and 8.2% respectively, and the sugar yield per hectare were higher than CK2 by 27.4%, 9.2% and 8.3%, respectively. At the same time, root promoting agents had certain effect on the growth rate of sugarcane. The content of soluble protein, soluble sugar and proline in sugarcane were improved, and there was no significant difference among the treatments. The results showed that the root promoting agents had positive effect on the growth of sugarcane, the yield and sugar yield of sugarcane with 100mg/L of the best concentration.

Key words: Sugarcane, Root promoting agent, Single bud of sugarcane, Agronomic characteristic, Yield

Table 1

The agronomic characteristics indexes of sugarcane growing under different treatments"

处理
Treatment
出苗率(%)
Germination rate
分蘖率(%)
Tillering rate
株高(cm)
Plant height
茎径(cm)
Stem diameter
有效茎数(条/hm2
Millable stalks (tiao/hm2)
T1 79.6±2.0abA 216.9±30.7aA 224.4±11.2abA 2.56±0.48aA 74 799±22.4aAB
T2 84.8±9.5aA 213.7±4.2aA 232.2±10.1aA 2.60±0.03aA 81 231±19.2aA
CK1 79.3±1.5abA 189.8±14.6aA 217.0±5.4bA 2.53±1.16aA 73 608±22.7aAB
CK2 77.7±9.0bA 129.9±22.6bB 215.6±4.2bA 2.53±0.15aA 64 317±22.7bB

Fig.1

The dynamic of plant height of sugarcane under different treatments"

Fig.2

The dynamic of stem diameter of sugarcane under different treatments"

Table 2

The physiological and biochemical indexes of different treatments at sugarcane elongating stage"

处理Treatment 可溶性蛋白质Soluble protein (mg/g) 可溶性糖Soluble sugar (%) MDA (mmol/g) 脯氨酸Pro (%)
T1 14.993±2.4aA 4.851±1.8aA 3.838±0.9aA 0.0074±0.001aA
T2 15.588±1.4aA 5.181±1.2aA 4.445±0.3aA 0.0104±0.007aA
CK1 14.451±0.5aA 4.562±1.0aA 4.037±1.0aA 0.0076±0.001aA
CK2 14.406±1.7aA 4.247±0.9aA 3.929±1.1aA 0.0073±0.065aA

Table 3

The performance of quality and yield of sugarcane under different treatments"

处理
Treatment
蔗汁重力纯度
Purity of sugarcane
juice (%)
蔗汁锤度
Sugarcane juice
brix (°Bx)
蔗汁蔗糖分
Sugarcane juice
sucrose content (%)
甘蔗糖分
Sugar
content (%)
产量
Yield
(t/hm2)
产糖量
Sugar yield
(t/hm2)
T1 90.83±1.08abA 21.64±0.49aA 21.05±0.12aA 16.91±0.16aA 78.2±1.71abA 13.22±0.28abA
T2 91.28±0.16aA 22.93±0.25aA 21.06±0.40aA 16.95±0.24aA 91.3±13.24aA 15.43±0.24aA
CK1 89.67±0.52bB 22.31±0.21aA 21.04±0.55aA 16.89±0.12aA 77.5±5.88abA 13.11±0.99abA
CK2 90.46±0.75abA 22.19±0.64aA 21.05±0.55aA 16.89±0.14aA 71.6±8.446bA 12.11±1.43bA
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