生物炭与磷肥配施对水稻生长发育及产量的影响

doi:10.16035/j.issn.1001-7283.2023.05.034

摘要/Abstract

摘要：

为探明生物炭与磷肥配施对水稻生长发育及产量的影响，为黑土区保障粮食安全、提升化肥利用效率提供理论依据。采用盆栽试验，生物炭和磷肥用量各设置3个水平，分别为0（B1）、28（B2）、55t/hm²（B3）和20（P1）、40（P2）、60kg/hm²（P3），共9个水平组合，不施用生物炭和磷肥的常规处理（CK）作对照，研究控制灌溉条件下水稻生长发育与产量对生物炭和磷肥的响应。结果表明，B3P2处理较CK处理增产46.53%;相关分析表明，水稻光合效率与产量无显著相关关系，灌浆期叶面积指数、抽穗期地上部干物质积累量、有效穗数、穗粒数与产量有显著正相关关系，结实率与产量呈显著负相关。生物炭与磷肥配施能够提高水稻抽穗期和灌浆期株高，增大水稻各生育阶段叶面积指数，增加分蘖期和拔节期干物质积累量，提升拔节期水稻光合作用;B3P2处理各指标最佳;生物炭与磷肥配施能够有效增加水稻穗长，提高有效穗数、穗粒数、千粒重，进而显著提高水稻产量。试验区最佳生物炭、磷肥配施模式为生物炭用量56t/hm²、磷肥用量43.75kg/hm²。

关键词: 生物炭, 磷肥, 水稻, 农艺性状, 光合作用, 产量

Abstract:

To investigate the effects of biochar combined with phosphorus fertilizer on the growth, development, and yield of rice, in order to provide a theoretical basis for ensuring food security and improving fertilizer utilization efficiency in black soil areas, using a pot experiment, three levels of biochar (0, 28, 55t/ha) and phosphorus fertilizer (20, 40, 60kg/ha) were set, a total of nine combinations, and the conventional treatment (CK) without biochar and phosphorus fertilizer as control, to study the response of rice growth, development, and yield to biochar and phosphorus fertilizer under controlled irrigation conditions. The results showed that the treatment (biochar was 55t/ha, phosphorus was 40kg/ha, B3P2) increased yield by 46.53% compared to CK treatment. Correlation analysis showed that there was no significant correlation between photosynthetic efficiency and yield, but there was a significant positive correlation between leaf area index during filling stage, aboveground dry matter accumulation during heading stage, effective panicles, and grains per panicle with yield, while there was a significant negative correlation between seed-setting rate and yield. The combination application of biochar and phosphorus fertilizer could improve the plant height during the heading and filling stages of rice, increase the leaf area index at each growth stage of rice, increase the accumulation of dry matter during the tillering and jointing stages, and enhance the photosynthesis of rice during the jointing stage. B3P2 treatment was the best treatment for all indicators. The combination of biochar and phosphorus fertilizer can effectively increase the length of rice panicles, increase the number of effective panicles, grains per panicle, and 1000-grain weight, thereby significantly improving rice yield. The optimal combination application mode of biochar and phosphorus fertilizer in the experimental area was 56t/ha of biochar and 43.75kg/ha of phosphorus fertilizer.

Key words: Biochar, Phosphate fertilizer, Rice, Agronomic traits, Photosynthesis, Yield

刘慧, 龙学毅, 焦岩, 王丽红. 生物炭与磷肥配施对水稻生长发育及产量的影响[J]. 作物杂志, 2023 (5): 238–248

Liu Hui, Long Xueyi, Jiao Yan, Wang Lihong. Effects of Combined Application of Biochar and Phosphate Fertilizer on Rice Growth and Yield[J]. Crops, 2023(5): 238–248

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项目 Item	分蘖前期 Early tillering stage	分蘖中期 Middle tillering stage	分蘖末期 Late tillering stage	拔节期 Jointing stage	抽穗期 Heading stage	灌浆期 Filling stage	成熟期 Mature stage
灌溉上限Irrigation maximum	50mm	50mm	100%	35mm	40mm	100%	20mm
灌溉下限Irrigation minimum	90%	85%	60%	85%	10mm	70%	60%

因素 Factor	分蘖期 Tillering stage	拔节期 Jointing stage	抽穗期 Heading stage	灌浆期 Filling stage	成熟期 Maturity stage
B	2.36	2.00	25.39^**	23.57^**	7.70^**
P	8.35^**	8.61^**	4.86^*	9.92^**	0.56
B×P	0.31	3.50^*	5.75^**	5.83^**	7.35^**

因素 Factor	分蘖期 Tillering stage	拔节期 Jointing stage	抽穗期 Heading stage	灌浆期 Filling stage	成熟期 Mature stage
B	8.14^**	6.22^**	33.74^**	42.72^**	34.86^**
P	4.65^*	26.21^**	80.11^**	34.51^**	4.18^*
B×P	3.49^*	9.37^**	11.75^**	3.49^*	2.74

因素Factor	P_n	G_s	T_r	C_i
B	4.06^*	5.26^*	101.01^**	14.81^**
P	16.47^**	4.51^*	20.86^**	11.71^**
B×P	11.95^**	8.14^**	25.42^**	10.81^**

处理 Treatment		分蘖期 Tillering stage	拔节期 Jointing stage	抽穗期 Heading stage	灌浆期 Filling stage	成熟期 Maturity stage
B1P1		3.00±0.80bcd	4.05±0.20d	7.65±1.42d	19.24±1.70e	30.69±1.67de
B1P2		3.20±0.40bc	4.23±0.46d	11.60±2.08ab	21.13±3.32de	32.13±1.53cde
B1P3		2.45±0.38cde	4.59±0.34c	10.35±1.15bc	25.01±2.15cd	31.32±2.71cde
B2P1		1.79±0.22e	4.40±0.71d	8.38±1.82cd	19.81±4.11e	30.97±3.61cde
B2P2		2.40±0.42e	5.02±0.28b	9.58±0.54bc	18.97±2.62ef	31.73±1.86cde
B2P3		3.96±0.70ab	6.39±0.46b	8.44±1.39cd	26.76±4.08bc	34.87±0.43bcd
B3P1		2.60±0.48de	4.16±0.63d	11.99±1.56ab	27.88±0.68bc	35.28±3.36bc
B3P2		4.65±0.23a	7.24±0.42a	14.00±0.78a	30.04±3.10b	38.45±2.35b
B3P3		2.95±0.42cde	5.17±0.27c	10.77±1.84bc	37.44±1.66a	43.36±2.10a
CK		1.85±0.17e	3.31±0.08e	6.58±0.87d	17.83±0.19f	28.07±0.99e
F值F-value	B	3.71^*	23.33^**	10.98^**	40.06^**	27.35^**
	P	8.54^**	56.37^**	8.62^**	19.71^**	7.14^**
	B×P	12.41^**	27.81^**	1.40	1.29	2.15