Effect of Vertical Pipe Aeration on Phyllostachys violascens Growth Under Mulching

doi:10.11924/j.issn.1000-6850.casb2022-0155

Abstract

Abstract:

The aims are to explore the effect of vertical pipe aeration on the growth of Phyllostachys violascens under mulching, and provide scientific technologies for the intensive management of P. violascens forests. Four treatments were set up in this experiment: no mulching and no aeration (CK), aeration and no mulching (A), mulching and no aeration (M), and mulching with aeration (MA). The soil oxygen concentration, soil mineral elements, and root vitality and photosynthetic parameters of P. violascens under each treatment were analyzed respectively to explore the effect of aeration on the growth and site conditions of intensively managed P. violascens forests. Compared with the no mulching and no aeration (CK), the mulching and no aeration treatment (M) significantly increased the content of organic matter, total nitrogen and total phosphorus of the soil surface. The mulching with aeration treatment (MA) promoted the decomposition of soil organic matter, total nitrogen, total phosphorus and other substances. In the soil layers of 0-10 cm, 10-20 cm, 20-30 cm and 30-40 cm, the soil oxygen content under MA treatment was higher than that under M treatment by 26.19%, 28.36%, 30.77 % and 26.92%, respectively (P<0.05). Compared with M treatment, the root vitality of P. violascens under MA treatment increased by 57.16% (P<0.05), and the net photosynthetic rate of leaves increased by 49.47% (P<0.05). Vertical pipe aeration significantly addressed the issues of soil oxygen deficit, poor growth of the root system, and reduced net photosynthetic rate of P. violascens forest caused by long-term mulching management.

Key words: Phyllostachys violascens, intensive management, aeration, soil physical and chemical properties, photosynthesis, root system

ZHU Ling, DENG Shixin, LEI Lujia, GUI Renyi. Effect of Vertical Pipe Aeration on Phyllostachys violascens Growth Under Mulching[J]. Chinese Agricultural Science Bulletin, 2023, 39(5): 55-62.

Figures/Tables 9

References 45

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处理	不同土层土壤氧气浓度/%
处理	0~10cm	10~20cm	20~30cm	30~40cm
CK	20.6±0.4a	20.04±0.47a	18.44±0.29b	17.57±0.37b
M	16.23±0.43b	15.16±0.49b	14.30±0.23c	14.04±0.66c
A	20.71±0.23a	20.20±0.32a	19.57±0.31a	18.60±0.27a
MA	20.48±0.53a	19.46±0.64a	18.70±0.38b	17.82±0.32ab

处理	不同土层土壤氧气浓度/%
处理	0~10cm	10~20cm	20~30cm	30~40cm
CK	20.6±0.4a	20.04±0.47a	18.44±0.29b	17.57±0.37b
M	16.23±0.43b	15.16±0.49b	14.30±0.23c	14.04±0.66c
A	20.71±0.23a	20.20±0.32a	19.57±0.31a	18.60±0.27a
MA	20.48±0.53a	19.46±0.64a	18.70±0.38b	17.82±0.32ab

处理	不同土层土壤有机质/(g/kg)
处理	0~10cm	10~20cm	20~30cm	30~40cm
CK	29.98±2.24b	25.65±4.06a	19.66±2.81a	14.55±2.01a
M	39.01±0.89a	30.39±2.26a	23.45±2.66a	11.18±1.70a
A	25.85±3.8b	25.29±4.57a	24.72±3.61a	12.23±1.30a
MA	30.81±0.94b	26.99±2.55a	22.71±4.01a	7.95±0.81a

处理	不同土层土壤有机质/(g/kg)
处理	0~10cm	10~20cm	20~30cm	30~40cm
CK	29.98±2.24b	25.65±4.06a	19.66±2.81a	14.55±2.01a
M	39.01±0.89a	30.39±2.26a	23.45±2.66a	11.18±1.70a
A	25.85±3.8b	25.29±4.57a	24.72±3.61a	12.23±1.30a
MA	30.81±0.94b	26.99±2.55a	22.71±4.01a	7.95±0.81a

处理	不同土层土壤全氮/(g/kg)
处理	0~10cm	10~20cm	20~30cm	30~40cm
CK	1.51±0.23b	1.3±0.12b	1.26±0.03a	1.34±0.15a
M	2.28±0.15a	2.17±0.33a	1.37±0.10a	1.34±0.12a
A	1.44±0.16b	1.26±0.24b	1.16±0.14a	1.28±0.13a
MA	1.78±0.15ab	1.75±0.11ab	1.31±0.13a	1.34±0.14a