原料、炭化温度和生物质炭组分对小白菜生长的影响

doi:10.3864/j.issn.0578-1752.2022.14.008

摘要/Abstract

摘要：

【目的】探究不同原料、炭化温度和生物质炭不同组分对植物生长的影响,进而揭示生物质炭的增产机制。【方法】分别以木屑和玉米秸秆为原料,在350、450、550℃下裂解得到生物质炭。采用热水浸提法将生物质炭中的可溶性组分（浸提液）与难溶性组分（炭骨架）分离。通过盆栽试验,研究不同生物质炭及组分对小白菜生长的影响。【结果】添加玉米秸秆生物质炭及其各组分处理下,小白菜地上部生物量平均为16.1 g/盆,显著高于添加木屑生物质炭及其各组分（13.0 g/盆）和对照处理（13.5 g/盆）。与地上部生物量类似,添加玉米秸秆生物质炭及其各组分处理下小白菜根长、根表面积、根体积和根尖数等形态学指标较木屑生物质炭和对照处理显著改善。添加炭骨架处理下小白菜地上部生物量平均为16.5 g/盆,较添加原状生物质炭和浸提液分别提高26.9%和17.9%。添加炭骨架处理下小白菜根长、根表面积、根体积和根尖数较添加浸提液处理分别提高64.1%、51.1%、38.3%和80.0%。不同炭化温度裂解得到的生物质炭对小白菜地上部生物量和根系生长无显著影响。与添加原状生物质炭处理相比,添加炭骨架处理下小白菜地上部氮含量提高25.9%,而磷和钾含量分别降低39.7%和14.1%。添加玉米秸秆生物质炭及其各组分处理下土壤pH、有机碳、全氮、速效磷和速效钾含量较添加木屑生物质炭处理分别提高0.1个单位、20.3%、19.1%、29.1%和189.2%。与添加原状生物质炭相比,添加生物质炭骨架处理下土壤有机碳、全氮、速效磷和速效钾含量分别降低14.6%、6.6%、41.3%和55.1%,土壤pH升高0.13个单位;而添加生物质炭浸提液处理下土壤有机碳、全氮和速效磷含量分别降低49.8%、18.9%和24.2%,土壤pH和速效钾含量无显著变化。相关分析表明,不同处理下小白菜地上部生物量与根长、表面积、平均直径、根体积、根尖数等根系形态指标和土壤pH呈正相关,与小白菜地上部磷含量呈负相关。【结论】生物质炭制备原料和组成是影响植物生长的重要因素,玉米秸秆生物质炭较木屑生物质炭有更好的增产效果;玉米秸秆生物质炭经热水浸提后再添加至土壤中有更好的增产效果。生物质炭中可溶性组分对根系生长的促进作用是生物质炭增产的主要机制,而可溶性组分对根系促生作用与原料、制备温度和其本身物质组成密切相关。

关键词: 生物质炭浸提液, 小白菜, 产量, 根系形态, 作物增产机制

Abstract:

【Objective】 The objectives of this study were to investigate the effects of biochar feedstocks, pyrolyzing temperatures and biochar components on plant growth and to uncover the mechanism that how biochar increased crop yields. 【Method】 Six biochars were made from sawdust and maize stalk at pyrolyzing temperature of 350, 450, and 550℃. Each biochar was then separated into two parts through hot water extraction method, including the water soluble biochar extract and the washed biochar residue. A pot trial was conducted to investigate the effects of untreated biochar (BC), biochar extract (BE) and washed biochar residue (WB) application on the growth of non-heading Chinese cabbage (Brassica campestris ssp. chinesis). 【Result】 The aboveground biomass of Chinese cabbage under the addition of maize stalk biochars and their components was 16.1 g/pot on average, which was significantly higher than the values under sawdust biochars and their components (13.0 g/pot) amendment and the control (13.5 g/pot). Similarly, the root morphology index of root length, surface area, root volume and number of root tips under the addition of maize stalk biochars and their components improved greatly compared with sawdust biochar and the control. The aboveground biomass under the addition of washed biochar residues was 16.5 g/pot on average, which were 26.9% and 17.9% higher than the values under the addition of untreated biochar and the biochar extracts, respectively. The root length, surface area, root volume and number of root tips under washed biochar residues addition increased by 64.1%, 51.1%, 38.3% and 80.0%, respectively compared with biochar extracts addition. The biochars under different pyrolyzing temperature had no significant effect on the aboveground biomass and root growth of Chinese cabbage. Compared with the untreated biochar, the washed biochar residue addition increased the concentration of nitrogen (N) in aboveground biomass by 25.9%, while the concentration of phosphorus (P) and potassium (K) decreased by 39.7% and 14.1%, respectively. Soil pH, the concentration of soil organic carbon, total N, available P and K under the addition of maize stalk biochar and their components increased by 0.1 unit, 20.3%, 19.1%, 29.1% and 189.2% respectively compared with wood biochar addition. Compared with the untreated biochar, the washed biochar residue addition decreased soil organic carbon, total N, available P and K by 14.6%, 6.6%, 41.3% and 55.1%, respectively, while soil pH increased by 0.13 unit. Soil organic carbon, total N and available P under the addition of biochar extracts decreased by 49.8%, 18.9% and 24.2%, respectively, while soil pH and available K content was not affect. Correlation analysis showed that the aboveground biomass was positively related to root length, surface area, root volume, the number of root tips and soil pH value; while it was negatively correlated to the P concentration in the aboveground of Chinese cabbage. 【Conclusion】The feedstock and biochar component were the two main factors that regulating the response of plant growth to biochar amendment. The biochar from maize stalk was more suitable for soil amendment compared with wood biochar in terms of crop yield increase, and more crop yield could be obtained when maize stalk biochar was amended after hot water extracting. The water-soluble components presented in biochar played a key role in crop yield increase via promoting root growth. The promotion effect was closely related to biochar feedstock, pyrolyzing temperature and the chemical composition in biochar extracts.

Key words: biochar water extract, non-heading Chinese cabbage, crop yield, root morphology, the mechanism that regulating crop yield increase

钟佳霖,许觜妍,张怡云,李婕,刘晓雨,李恋卿,潘根兴. 原料、炭化温度和生物质炭组分对小白菜生长的影响[J]. 中国农业科学, 2022, 55(14): 2775-2785.

ZHONG JiaLin,XU ZiYan,ZHANG YiYun,LI Jie,LIU XiaoYu,LI LianQing,PAN GenXing. Effects of Feedstock, Pyrolyzing Temperature and Biochar Components on the Growth of Chinese Cabbage[J]. Scientia Agricultura Sinica, 2022, 55(14): 2775-2785.

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链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2022.14.008

https://www.chinaagrisci.com/CN/Y2022/V55/I14/2775

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原料 Feedstock	生物质炭组分 Biochar component	炭化温度 Temperature (℃)	pH (H₂O)	有机碳 OC (g·kg^-1)	全氮 TN (g·kg^-1)	速效磷 Available P (mg·kg^-1)	速效钾 Available K (mg·kg^-1)
木屑 Sawdust	BC	350	6.48	346.57	0.94	40.69	0.00
		450	8.14	294.49	1.51	95.39	24.30
		550	7.69	288.33	1.09	91.39	1.39
	BE	350	7.97	503.04	12.98	0.09	0.00
		450	8.19	506.85	11.21	0.41	0.00
		550	7.90	475.58	13.00	0.15	0.00
	WB	350	7.20	580.55	1.00	5.11	0.00
		450	8.14	414.90	1.71	67.27	0.00
		550	7.69	315.19	1.25	15.36	0.00
玉米秸秆 Maize stalk	BC	350	9.74	552.69	17.01	2179.17	39623.25
		450	10.06	558.21	15.84	2014.72	39442.09
		550	10.10	614.09	14.73	2317.22	48393.26
	BE	350	8.81	83.20	24.20	2.38	0.79
		450	8.66	50.60	13.48	2.75	0.85
		550	9.22	80.80	11.90	5.83	1.05
	WB	350	8.84	297.40	16.16	1266.92	2585.81
		450	8.82	190.80	15.56	1145.77	3621.58
		550	9.03	183.80	16.08	565.00	5185.95


根长 Root length	0.572	<0.001
根表面积 Root surface	0.647	<0.001
根直径 Root diameter	0.005	0.961
根体积 Root volume	0.711	<0.001
根尖数 Root tips	0.559	<0.001
土壤pH Soil pH	0.497	<0.001
土壤有机碳 SOC	0.169	0.102
土壤全氮 TN	0.192	0.058
土壤速效磷 Available P	-0.121	0.235
土壤速效钾 Available K	0.143	0.157
植株氮含量 N concentration	0.005	0.958
植株磷含量 P concentration	-0.208	0.040
植株钾含量 K concentration	-0.11	0.282