Preliminary Study on Effect of Tobacco Stalk Biochar in Passivation of Soil Cadmium

doi:10.11924/j.issn.1000-6850.casb2024-0384

Abstract

Abstract:

It is valuable to compare the effects of different amounts of tobacco stalk biochar on Cd bioactivity in acidic soil, which may contribute to the safe planting of polluted farmland, and provide theoretical support for the resource utilization of a large amount of tobacco stalk waste as well. In this study, a series of tobacco stalk biochar (0, 5, 15 and 30 g/kg, denoted as B0, B5, B15 and B30, respectively) were applied to typical Cd-polluted acidic soil collected from the local region, and then C. coronarium and C. endivia were planted continuously in pots. The results showed that the biochar amendment significantly improved the soil physiochemical characters. All the parameters such as pH, TOC, CEC, available P and K in the biochar-amended soil were significantly higher than those of the control soil (P<0.05). Biochar addition promoted the transition from acid-soluble (Cd_acid) to the reducible Cd fraction (Cd_red) in the soil. The proportion of Cd_acid in the total was decreased from 64.03%-71.91% to 52.94%-56.51%, which indicated the large reduction of Cd bioavailability. Cd content in both above- and below-ground tissues of C. coronarium and C. endivia were significantly decreased by 53.47%-91.71% and 56.32%-87.95%, respectively. The biological cumulative factor (BCF) values for both crops were also significantly decreased by 54.47%-89.54%. The transfer factor (TF) values of C. coronarium in all treatments were highly similarity, no significant difference was observed. However, TF of C. endivia increased by 2.94%-86.76% compared to those in control. In addition, the larger rate of biochar amendment induced the greater changes in those parameters. The crop of C. coronarium is more sensitive to biochar addition than C. endivia. With the addition of 30 g/kg biochar (B30), Cd content in edible parts of both C. coronarium and C. endivia were decreased to 0.11 mg/kg and 0.20 mg/kg respectively, which were lower than the national limit for food. It was concluded that adding suitable rate of tobacco stalk biochar (5-15 g/kg) could not only improve soil properties like pH, organic C and CEC, but also promote the transformation of acid-extractable Cd to reducible Cd, and reduce the Cd bioavailability. Biochar addition reduced the Cd content in both C. coronarium and C. endivia, and strongly enhanced vegetable biomass production. C. coronarium was more sensitive to the biochar addition than that of C. endivia.

Key words: acidic soil, Cd, passivation, tobacco stalk, biochar, C. coronarium, C. endivia.

HE Defei, CHEN Weisheng, LIANG Jiecong, HUANG Xurong, LU Congxu, LIU Zhongzhen, HUANG Yufen. Preliminary Study on Effect of Tobacco Stalk Biochar in Passivation of Soil Cadmium[J]. Chinese Agricultural Science Bulletin, 2025, 41(2): 83-90.

Figures/Tables 5

References 40

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处理	pH		有机碳/ (g/kg)		阳离子交换量/ (cmol/kg)		速效钾/ (mg/kg)		有效磷/ (mg/kg)		交换性钙/ (mg/kg)		交换性镁/ (mg/kg)
处理	茼蒿	苦麦菜	茼蒿	苦麦菜	茼蒿	苦麦菜	茼蒿	苦麦菜	茼蒿	苦麦菜	茼蒿	苦麦菜	茼蒿	苦麦菜
B0	5.91d	5.85d	10.7d	11.4d	4.49d	4.64c	461c	242d	141.2d	105.2c	1036.6b	830.2d	125.3b	96.6bc
B5	6.09cd	6.23c	14.8c	15.4c	5.00c	4.77c	662c	450c	195.3c	110.1c	1019.3b	853.7cd	103.4b	95.5c
B15	6.36bc	6.73b	19.5b	20.7b	5.31b	5.24b	1254b	1089b	220.4b	135.1b	1110.7ab	921.5b	128.2b	102.0b
B30	6.67a	7.33a	28.2a	28.4a	5.87a	5.99a	3067a	1998a	281.0a	171.4a	1242.0a	997.0a	148.2a	116.0a

处理	pH		有机碳/ (g/kg)		阳离子交换量/ (cmol/kg)		速效钾/ (mg/kg)		有效磷/ (mg/kg)		交换性钙/ (mg/kg)		交换性镁/ (mg/kg)
处理	茼蒿	苦麦菜	茼蒿	苦麦菜	茼蒿	苦麦菜	茼蒿	苦麦菜	茼蒿	苦麦菜	茼蒿	苦麦菜	茼蒿	苦麦菜
B0	5.91d	5.85d	10.7d	11.4d	4.49d	4.64c	461c	242d	141.2d	105.2c	1036.6b	830.2d	125.3b	96.6bc
B5	6.09cd	6.23c	14.8c	15.4c	5.00c	4.77c	662c	450c	195.3c	110.1c	1019.3b	853.7cd	103.4b	95.5c
B15	6.36bc	6.73b	19.5b	20.7b	5.31b	5.24b	1254b	1089b	220.4b	135.1b	1110.7ab	921.5b	128.2b	102.0b
B30	6.67a	7.33a	28.2a	28.4a	5.87a	5.99a	3067a	1998a	281.0a	171.4a	1242.0a	997.0a	148.2a	116.0a

处理	茼蒿		苦麦菜
处理	生物富集系数(BCF)	转移系数(TF)	生物富集系数(BCF)	转移系数(TF)
B0	4.97±0.23a	0.16±0.01b	1.23±0.05a	0.68±0.06c
B5	2.09±0.06b	0.17±0.01b	0.56±0.02b	0.95±0.05b
B15	1.06±0.05c	0.23±0.02a	0.32±0.01c	1.27±0.01a
B30	0.52±0.01d	0.11±0.01c	0.22±0.01d	0.70±0.04c

处理	茼蒿		苦麦菜
处理	生物富集系数(BCF)	转移系数(TF)	生物富集系数(BCF)	转移系数(TF)
B0	4.97±0.23a	0.16±0.01b	1.23±0.05a	0.68±0.06c
B5	2.09±0.06b	0.17±0.01b	0.56±0.02b	0.95±0.05b
B15	1.06±0.05c	0.23±0.02a	0.32±0.01c	1.27±0.01a
B30	0.52±0.01d	0.11±0.01c	0.22±0.01d	0.70±0.04c