Crops ›› 2025, Vol. 41 ›› Issue (5): 239-246.doi: 10.16035/j.issn.1001-7283.2025.05.031

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Effects of Relay Intercropping Corn after Tobacco on Crop Production and Soil Nutrients

Liu Di1,2(), Song Laigui2, Tian Linqing1, Li Zhigang1, Ma Junmei2, Li Zuosen2, Nian Fuzhao2, Jiao Jian1(), Deng Xiaopeng3   

  1. 1 Yiliang Branch of Kunming Company, Yunnan Tobacco Company, Kunming 652100, Yunnan, China
    2 College of Tobacco Science, Yunnan Agricultural University, Kunming 650000, Yunnan, China
    3 Yunnan Academy of Tobacco Agricultural Sciences, Kunming 650032, Yunnan, China
  • Received:2024-06-03 Revised:2024-09-26 Online:2025-10-15 Published:2025-10-21

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Abstract:

In order to screen out fresh-eating corn varieties suitable for intercropping after flue-cured tobacco, five fresh-eating corn varieties, including Dagujingnuo VIII, Shibainuo 1, Yanuo 69, Jinnuo 1805, and Caitiannuo 6, were used as experimental materials, and their growth period, agronomic traits, yield, and quality were determined and analyzed, it was preliminarily determined that Shibainuo 1 had higher yield, better quality, and shorter growth period, and was suitable for intercropping of flue-cured tobacco. Intercropping of flue-cured tobacco Honghuadajinyuan after the end of second shed tobacco leaves with Shibainuo 1, the effects of interplanting fresh corn on tobacco yield and quality, soil nutrients and related enzyme activities were analyzed. The results showed that compared with flue-cured tobacco monoculture, intercropping fresh-eating corn at the late stage of flue-cured tobacco optimized the coordination of the upper leaves of flue-cured tobacco and improved the quality of tobacco leaves, improved the activity of acid phosphatase in rhizosphere soil of tobacco, increased the contents of soil organic matter and alkali-hydrolyzed nitrogen, and decreased the content of chloride ions.

Key words: Relay intercropping corn after tobacco, Soil enzyme activity, Variety selection, Soil nutrient

Table 1

Agronomic traits of different fresh-eating corn varieties at maturity"

品种
Variety		 株高
Plant height (cm)		 茎围
Stem circumference (cm)		 叶片数
Leaf number		 叶长
Leaf length (cm)		 叶宽
Leaf width (cm)
大谷京糯八号DGJN 163.00±4.62ab 10.99±0.23a 13.20±0.25a 59.95±2.46a 10.13±0.25a
石白糯1号SBN 172.27±10.70a 9.33±0.33c 12.73±0.41a 60.54±4.33a 8.81±0.95a
雅糯69 YN 144.13±5.90ab 10.59±0.17ab 11.67±0.30b 58.82±1.55a 10.35±0.40a
金糯1805 JN 150.00±10.07ab 10.95±0.30a 11.07±0.16b 58.10±3.73a 9.97±0.36a
彩甜糯6号CTN 134.40±14.63b 9.84±0.39bc 11.73±0.45b 59.47±1.38a 9.96±0.58a

Table 2

Yield and growth period of different fresh corn varieties"

品种
Variety		 生育期
Growth period (d)		 平均单株穗数
Average number of ears per plant		 平均穗重
Average ear weight (kg)		 产量
Yield (kg/hm2)
大谷京糯八号DGJN 86 1 0.52±0.02a 16 255.22±111.29b
石白糯1号SBN 90 2 0.36±0.02b 22 507.25±259.05a
雅糯69 YN 92 1 0.49±0.04ab 15 317.45±352.54c
金糯1805 JN 95 1 0.20±0.05c 6252.00±304.61d
彩甜糯6号CTN 98 1 0.47±0.04ab 14 692.20±381.94c

Fig.1

Quality analysis of different fresh-eating corn varieties The different lowercase letters indicate significant difference at P < 0.05 level, the same below."

Table 3

Sensory test of different fresh-eating corn varieties"

品种
Variety		 外观品质
(10)
Appearance quality		 气味
(10)
Scents		 色泽
(10)
Color		 甜糯性
(15)
Sweetness		 果皮厚度
(15)
Pericarp thickness		 柔嫩性
(20)
Tenderness		 风味
(20)
Flavour		 总分
(100)
Total score
大谷京糯八号DGJN 8.00±0.00ab 8.67±0.58a 8.17±0.76a 9.67±1.53b 13.00±0.00a 17.00±0.00a 18.33±0.58a 82.83±1.76a
石白糯1号SBN 9.00±0.00a 8.17±0.29ab 8.50±0.87a 13.67±0.58a 12.33±1.53a 18.00±0.00a 17.67±0.58ab 87.33±1.53a
雅糯69 YN 7.33±0.58b 7.67±0.29b 7.17±0.76ab 11.33±1.15b 11.00±1.00ab 15.67±0.58ab 15.6±1.54bc 75.83±2.25b
金糯1805 JN 6.17±1.04c 7.00±0.00c 8.33±1.15a 11.00±1.73b 9.67±1.53b 14.00±1.00bc 13.67±0.58c 69.83±3.88c
彩甜糯6号CTN 5.67±0.58c 6.00±0.00d 6.00±1.00b 9.00±1.00b 10.00±1.00b 12.67±2.52c 13.67±2.08c 63.00±3.00d

Fig.2

Effects of intercropping flue-cured tobacco and corn on the physicochemical properties of rhizosphere soil *: P < 0.05, **: P < 0.01, ***: P < 0.001, the same below."

Fig.3

Effects of intercropping between flue-cured tobacco and corn on enzyme activities in rhizosphere soil"

Fig.4

Correlation between physicochemical properties and enzyme activities of rhizosphere soil in intercropping flue-cured tobacco and corn “*”and“**”indicate significant correlation at P < 0.05 and P < 0.01 levels, respectively."

Table 4

The effects of intercropping tobacco with maize on the chemical composition of upper leaves of flue-cured tobacco"

处理
Treatment		 总糖
Total sugar
(%)		 还原糖
Reducing
sugar (%)		 总氮
Total
nitrogen (%)		 烟碱
Nicotine
(%)		 氧化钾
Potassium
chloride (%)
Chlorine
(%)		 钾氯比
Potassium-
chloride ratio		 氮碱比
Nitrogen-
alkali ratio
T1 18.82±0.16 15.62±0.15* 2.78±0.02 4.41±0.06 2.46±0.02* 0.34±0.01* 7.23±0.13 0.63±0.006
T2 18.55±0.19 15.01±0.10 2.82±0.03 4.25±0.03 2.33±0.03 0.30±0.01 7.70±0.21* 0.66±0.003*

Table 5

Yield and production value of upper leaves of flue-cured tobacco in single cropping and intercropping"

处理
Treatment		 产量
Yield (kg/hm2)		 产值(元/hm2
Production value (yuan/hm2)
T1 612.00±13.44 11 830.80±288.14
T2 553.17±10.65 10 277.80±396.11
T3 13 422.27±527.59 67 111.33±2637.96
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