Soil heavy metal curing agent for controlling accumulation of heavy metals of crops and preparation method thereof

Abstract

The present invention provides a soil heavy metal curing agent for controlling accumulation of heavy metals of crops and its preparation method. The curing agent is made from the following parts of raw materials by weight: 60˜140 parts of substance containing carbon-carbon double bond; 1˜400 parts of sulfo-compound by sulfur; 50˜500 parts of organic matter by 10% water content; 0˜400 parts of water; 0˜100 parts of an initiator; 0˜200 parts of a reducer; and 0˜200 parts of a strong base. The curing agent for heavy metals in the soil according to the present invention can reduce the cadmium, lead and mercury content in the soil and further greatly reduce the roots' absorption of these heavy metals.

Claims

1. A soil heavy metal curing agent for controlling accumulation of heavy metals of crops, being made from the following parts of raw materials by weight: 90˜110 parts of substance containing carbon-carbon double bond, 80˜150 parts of sulfo-compound, 200˜300 parts of organic matter with 10% water content, 100˜200 parts of water, 40˜60 parts of an initiator, 80˜110 parts of a reducer, and 80˜110 parts of a strong base, wherein, the substance containing carbon-carbon double bond is at least one selected from the group consisting of polyisoprene, polyisoprene analog, polyisoprene derived polymer and an unsaturated fatty acid, the polyisoprene analog and the polyisoprene derived polymer are one of natural rubber, natural latex, polyacetylene, polybutadiene or polypentadiene, and the unsaturated fatty acid is one of vegetable oil or gutter oil, wherein the sulfo-compound is at least one selected from the group consisting of sulfur, hydrosulfide, sodium sulfide or ferrous sulfide, wherein the organic matter is at least one selected from the group consisting of colza cake, soybean cake, bean pulp, straw stalks, barley or wheat stalks, sugarcane chip/bagasse, rape stalks, corn or sorghum stalks, wood chins, weed stalks, astragalus sinicus stalks, clover stalks, waste paper or water hyacinth, wherein the initiator is one of hydrogen peroxide, peroxyformic acid or peroxy benzoic acid, wherein the reducer is at least one selected from the group consisting of sodium sulfite, zinc powder, iron powder and magnesium powder.

2. The soil heavy metal curing agent according to claim 1, wherein, the strong base is quicklime, sodium hydroxide or potassium hydroxide.

Description

DETAILED DESCRIPTION

(1) The present invention is further described hereinafter in combination with embodiments.

Embodiment 1

(2) 1) melt 100 parts of the polyisoprene into a liquid state at a temperature of 100° C., 150° C. or 300° C.;

(3) 2) add 300 parts of sulphur into the high-temperature liquid solution obtained in Step 1), boil it for 0.5, 1, 1.5 or 3 h, and also add 50 parts of the hydrogen peroxide and keep mixing it at a constant speed;

(4) 3) cool it to room temperature, add 300 parts of colza cake into the mixed polymer obtained in Step 2), mix and crush it to a uniform size to get the solid mix polymer;

(5) 4) add 150 parts of water, 100 parts of sodium sulfite and 150 parts of quicklime into the solid mix polymer obtained in Step 3), crush it to a uniform size again, place the crushed solid mix polymer in a steam bath and steam for 1, 2 or 3 h, and then cool it to get the solid mix polymer;

(6) 5) put the solid mix polymer obtained in Step 4) to a place of 30° C. 40° C., 60° C. 80° C., or 100√ C. for airing, and drying or exposure to the sun until the water content is no more than 20%;

(7) 6) crush the solid mix polymer obtained in Step 5) to a granularity of 60, 80, 100, 120 or 150 mesh to get the curing agent for heavy metals in the soil to control the accumulation of heavy metals in crops.

(8) The same technical effect as Embodiment 1 can be also achieved if the polyisoprene above is replaced by more than one of polyisoprene, polyisoprene analog, polyisoprene derived polymer and unsaturated fatty acid. The sulphur is replaced by sodium hydrosulphide or sodium sulfide. The hydrogen peroxide is replaced by peroxyformic acid or peroxy benzoic acid, the sodium sulfite is replaced by zinc powder, iron powder or magnesium powder. The quicklime is replaced by sodium hydroxide or potassium hydroxide. The polyisoprene analog and the polyisoprene derived polymer in this embodiment can be natural rubber, natural latex, polyacetylene, polybutadiene or polypentadiene and the unsaturated fatty acid can be vegetable oil or gutter oil.

Embodiment 2

(9) 1) melt 60 parts of natural rubber into a liquid state at a temperature of 150° C.;

(10) 2) add 50 parts of sodium sulfide into the high-temperature liquid solution obtained in Step 1), boil it for 2.5 h, and also add 20 parts of peroxyformic acid and keep mixing it at a constant speed;

(11) 3) cool it to room temperature, add 50 parts of straw stalks into the polymer mix obtained in Step 2), mix and crush it to a uniform size to get the solid mix polymer;

(12) 4) add 50 parts of water, 50 parts of zinc powder and 20 parts of sodium hydroxide into the solid mixed polymer obtained in Step 3), crush it to a uniform size again, place the crushed solid mix polymer in a steam bath and steam for 1.5 h, and then cool it to get the solid mix polymer;

(13) 5) put the solid mix polymer obtained in Step 4) to a place of 85° C. for airing and drying or exposure to the sun until the water content is no more than 20%;

(14) 6) crush the solid mix polymer obtained in Step 5) to a granularity of 120 mesh to get the curing agent for heavy metals in the soil to control the accumulation of heavy metals in crops.

(15) The same technical effect as Embodiment 1 can be also achieved if the straw stalk above is replaced by one of or a mixture of more than one of colza cake, soybean cake, bean pulp, straw stalks, barley/wheat stalks, sugarcane chip/bagasse, rape stalks, corn/sorghum stalks, wood chips, weed stalks, Astragalus sinicus stalks, clover stalks, waste paper or water hyacinth.

Embodiment 3

(16) 1) melt 140 parts of polybutadiene into a liquid state at a temperature of 150° C.;

(17) 2) add 400 parts of sodium hydrosulphide into the high-temperature liquid solution obtained in Step 1), boil it for 2.5 h, and also add 100 parts of peroxy benzoic acid and keep mixing it at a constant speed;

(18) 3) cool it to room temperature, add 500 parts of waste paper into the polymer mix obtained in Step 2), mix and crush it to a uniform size to get the solid mix polymer;

(19) 4) add 400 parts of water, 200 parts of iron powder and 200 parts of potassium hydroxide into the solid polymer mix obtained in Step 3), crush it to a uniform size again, place the crushed solid polymer mix in a steam bath and steam for 2 h, and then cool it to get the solid mix polymer;

(20) 5) put the solid mix polymer obtained in Step 4) to a place of 20° C. for airing and drying or exposure to the sun until the water content is no more than 20%;

(21) 6) crush the solid mix polymer obtained in Step 5) to a granularity of 100 mesh to get the curing agent for heavy metals in the soil to control the accumulation of heavy metals in crops.

Embodiment 4

(22) 1) melt 80 parts of natural latex into a liquid state at a temperature of 150° C.;

(23) 2) add 200 parts of sodium hydrosulphide into the high-temperature liquid solution obtained in Step 1), boil it for 2.5 h, and also add 80 parts of peroxy benzoic acid and keep mixing it at a constant speed;

(24) 3) cool it to room temperature, add 200 parts of Astragalus sinicus stalks into the mix polymer obtained in Step 2), mix and crush it to a uniform size to get the solid mix polymer;

(25) 4) add 300 parts of water, 150 parts of magnesium powder and 80 parts of potassium hydroxide into the solid mix polymer obtained in Step 3), crush it to a uniform size again, place the crushed solid mix polymer in a steam bath and steam for 0.5 h, and then cool it to get the solid mix polymer;

(26) 5) put the solid mix polymer obtained in Step 4) to a place of 20° C. for airing and drying or exposure to the sun until the water content is no more than 20%;

(27) 6) crush the mix polymer obtained in Step 5) to a granularity of 100 mesh to get the curing agent for heavy metals in the soil to control the accumulation of heavy metals in crops.

Embodiment 5

(28) 1) melt 110 parts of polyacetylene into a liquid state at a temperature of 100° C.;

(29) 2) add 150 parts of sodium hydrosulphide into the high-temperature liquid solution obtained in Step 1), boil it for 3 h, and also add 40 parts of peroxy benzoic acid and keep mixing it at a constant speed;

(30) 3) cool it to room temperature, add 250 parts of clover stalks into the mix polymer obtained in Step 2), mix and crush it to a uniform size to get the solid mix polymer;

(31) 4) add 250 parts of water, 120 parts of magnesium powder and zinc powder, respectively, and 120 parts of potassium hydroxide into the solid mix polymer obtained in Step 3), crush it to a uniform size again, place the crushed solid mix polymer in a steam bath and steam for 2 h, and then cool it to get the solid mix polymer;

(32) 5) put the solid mix polymer obtained in Step 4) to a place of 20° C. for airing and drying or exposure to the sun until the water content is no more than 20%;

(33) 6) crush the solid mix polymer obtained in Step 5) to a granularity of 100 mesh to get the curing agent for heavy metals in the soil to control the accumulation of heavy metals in crops.

Embodiment 6

(34) 1) melt 100 parts of polyisoprene into a liquid state at a temperature of 160° C.;

(35) 2) add 200 parts of sulphur powder into the high-temperature liquid solution obtained in Step 1), boil it for 1 h and keep mixing it at a constant speed;

(36) 3) cool it to room temperature, add 250 parts of colza cake into the mix polymer obtained in Step 2), mix and crush it to a uniform size to get the solid mix polymer;

(37) 4) add 100 parts of magnesium powder and 100 parts of potassium hydroxide into the solid mix polymer obtained in Step 3), crush it to a uniform size again, place the crushed solid mix polymer in a steam bath and steam for 2 h, and then cool it to get the solid mix polymer;

(38) 5) put the solid mix polymer obtained in Step 4) to a place of 20° C. for airing and drying or exposure to the sun until the water content is no more than 20%;

(39) 6) crush the solid mix, polymer obtained in Step 5) to a granularity of 100 mesh to get the curing agent for heavy metals in the soil to control the accumulation of heavy metals in crops.

Embodiment 7

(40) 1) melt 120 parts of vegetable oil or gutter oil into a liquid state at a temperature of 250° C.

(41) 2) add 120 parts of sodium sulfide and 25 parts of hydrogen peroxide into the high-temperature liquid solution obtained in Step 1), boil it for 1.5 h and keep mixing it at a constant speed;

(42) 3) cool it to room temperature, mix and crush it to a uniform size to get the powdered solid mix polymer, then add 120 parts of water, 100 parts of zinc powder and 150 parts of quicklime into the powdered solid mix polymer, place the resulting mixture in a steam bath and steam for 1.5 h or boil for 0.8 h, and then cool it to get the semi-jelly mixture;

(43) 4) add 380 parts soybean cake into the semi-jelly mixture obtained in Step 3), thoroughly mix to get the jelly mixture;

(44) 5) put the jelly mixture obtained in Step 4) to a place of 80° C. for airing and drying or exposure to the sun until the water content is no more than 20%;

(45) 6) crush the solid mix polymer obtained in Step 5) to a granularity of 120 mesh to get the curing agent for heavy metals in the soil to control the accumulation of heavy metals in crops.

Embodiment 8

(46) 1) melt 85 parts of vegetable oil (peanut oil, bean oil, linseed oil, castor oil or rapeseed oil, etc.) into a liquid state at a temperature of 350° C.;

(47) 2) add 60 parts of ferrous sulfide, 60 parts of sulphur and 70 parts of peroxy benzoic acid into the high-temperature liquid solution obtained in Step 1), boil it for 2.5 h and keep mixing it at a constant speed;

(48) 3) cool it to room temperature, mix and crush it to a uniform size to get the powdered solid mix polymer, then add 220 parts of water, 50 parts of zinc powder, 60 parts of magnesium powder and 150 parts of quicklime into the powdered solid mix polymer, place the resulting mixture in a steam bath and steam for 1.5 h or boil for 0.8 h, and then cool it to get the semi-jelly mixture;

(49) 4) add 60 parts of soybean cake, 70 parts of bean pulp and 80 parts of waste paper into the semi-jelly mixture obtained in Step 3), thoroughly mix to get the jelly mixture;

(50) 5) put the jelly mixture obtained in Step 4) to a place of 80° C. for airing and drying or exposure to the sun until the water content is no more than 20%;

(51) 6) crush the solid mixed polymer obtained in Step 5) to a granularity of 120 mesh to get the curing agent for heavy metals in the soil to control the accumulation of heavy metals in crops.

Embodiment 9

(52) Experiment on the absorption of solution cadmium, lead and mercury for the curing agent: take the curing agent prepared according to Embodiment 1 as the test agent. Prepare 6 L of cadmium, lead and mercury solution with concentrations of 5, 30 and 0.5 mg/kg, respectively. Place the 6 L of solution in 6 clean black plastic barrels, each barrel containing 1 L. Set up CK and 0.5 g/barrel for two treatments for the curing agent and repeat three times. Add the curing agent, mix thoroughly and keep this state for 8 h stirring occasionally. Take 50 mL of the solution, keep centrifugation for 10 min with a centrifuge at a speed of 4000 and take the supernatant and then measure the cadmium, lead and mercury with an ICP-AES and an atomic fluorescence spectrophotometer, respectively. The result shows that the concentrations of solution cadmium, lead and mercury treated by the curing agent are 0.21±0.017, 1.38±0.099 and 0.03±0.001 mg/kg, respectively (three duplicate values); while those from CK are 4.87, 30.8 and 0.51 mg/kg, respectively. After treatment with the curing agent, the concentrations of cadmium, lead and mercury in solution are reduced greatly, exhibiting that the curing agent has very strong curing or adsorption capacity for cadmium, lead and mercury in solution.

(53) Make the experiment under the same condition as in Embodiment 9 to the curing agent prepared according to Embodiment 2-8. The concentrations of cadmium, lead and mercury in the resultant solution are below 0.21, 1.38 and 0.03 mg/kg.

Embodiment 10

(54) Experiment of absorption of soil cadmium for the curing agent: take the paddy field soil contaminated by cadmium which was previously prepared and was devoted to rice cultivation for many years as the material, where the total cadmium content is 5.76 mg/kg. Air to dry and crush the soil and sieve it at the opening size of 60 mesh. Take 6 clean beakers whose volume is 1 L, take 1 kg dry soil accurately weighed and put it into the beakers, respectively. Add 1 L of distilled water into the beakers, mix thoroughly and keep them for 3 days.

(55) Take the curing agent prepared according to Embodiment 5 as the study material, set up CK and 0.5 g/beaker for the curing agent, and allow three repetitions. After adding to the beakers, mix thoroughly and keep for another 3 days. Take 20 g of wet soil, place it into a centrifuge tube, keep centrifugation for 15 min with a high-speed centrifuge at a speed of 8000, and take the supernatant for element measurement (obtain sufficient supernatant by multiple repeated samplings and centrifugation). The measurement result shows that upon treatment with the curing agent, the concentration of cadmium in soil solution is 0.17±0.06 mg/kg, while without applying the curing agent is 1.46±0.19 mg/kg. After treatment by the curing agent, the concentration of cadmium in the soil solution is reduced greatly, exhibiting that the curing agent has a very strong curing or adsorption capacity for cadmium in the soil.

(56) Make the experiment under the same condition as in Embodiment 10 to the curing agent prepared according to Embodiments 1, 2, 3, 4, 6, 7 and 8. The concentration of cadmium in the resulting soil solution is below 0.17 mg/kg.

Embodiment 11

(57) Experimental Material: Miyang 46

(58) Experimental soil: use the soil from the test fields of the China National Rice Research Institute (Fuyang of Zhejiang), dry the soil in the sun and then crush to 60 mesh, add cadmium sulfate to make the cadmium content in the soil become 25 mg/kg. Weigh 4.5 kg of cadmium-contaminated soil into a black plastic barrel of 5 L, add water and mix thoroughly. Keep the soil in a wet state for 2 weeks for further use.

(59) Experiment treatment: set up CK (the curing agent not added), conduct surface application (application on surface and mixing up on surface) and deep application (thoroughly mixing up). Treatment of the curing agent: add 1.25 g of the curing agent prepared according to Embodiment 7 in the barrel, and let it rest for a night. Transplant the rice seedlings with the leaf age in the period of three leaves and one core, each pot containing 4 holes and each hole containing 3 seedlings. During the growth of the paddy rice, keep a 1 cm thick water layer.

(60) Determination items: 30 days after the planting of the seedlings, take the soil on top, rinse it from 2-3 times in 0.1% diluted flood water, roast for 2 h at a temperature of 120° C. and then dry at a temperature of 60° C. until a constant mass is obtained. Crush the dry sample to powder, weigh 0.5000 g of the powder, nitrate-boil it with a mixing solution of concentrated nitric acid and perchloric acid (1:3), and then add redistilled water until a total volume of 25 mL is reached. Finally, measure the contents of elements such as Mn, Pb, Cd, Fe, Cu and Zn with a full-spectrum direct-reading inductively coupled plasma atomic emission spectrometry (ICP-AES).

(61) Results and Analysis:

(62) TABLE-US-00001 TABLE 1 Influences of the curing agent to the absorption and accumulation of elements such as Cd in paddy rice Lead Copper Iron Zinc Cadmium (mg/ (mg/ Manganese (mg/ (mg/ Treatment (mg/kg) kg) kg) (mg/kg) kg) kg) CK 0.76 0.21 29.9 632.85 125.0 71.74 CK 0.79 0.75 30.42 706.22 152.36 76.87 Shallow 0.59 0.21 29.58 669.21 127.07 74.31 application on surface Shallow 0.59 0.27 52.58 715.14 167.97 67.21 application on surface Deep 0.28 0.18 23.5 594.09 122.41 61.19 application and thorough mixing Deep 0.38 0.22 28.0 643.0 130.66 65.62 application and thorough mixing

(63) After the curing agent is shallowly applied on the surface, cadmium in the plant is reduced by 23.87%; while after deep application and thorough mixing, it is reduced by 57.42%, showing a highly significant effect. No matter the shallow application on the surface or a deep application and thorough mixing, the accumulation of elements such as iron, manganese, copper and zinc in plants caused by the curing agent has no significant difference. The result shows that the curing agent has a strong control effect on the accumulation of cadmium in paddy rice.

(64) Make the experiment under the same condition as in Embodiment 11 to the curing agent prepared according to Embodiments 1, 2, 3, 4, 5, 6 and 8. After a shallow application of the curing agent on the surface, cadmium in the plant is reduced by over 23%; while upon deep application and thorough mixing, cadmium in plant is reduced by over 57%, showing a highly significant effect.

Embodiment 12

(65) Experiment Design:

(66) Carefully select 500 seeds of tobacco type K326, use 2% H2O2 for surface disinfection for 20 min, then wash the seeds with distilled water, soak them for 3 h at 25° C., keep accelerating germination for 1 d at 25° C., then place them in the greenhouse of Zijingang Campus of Zhejiang University, use vermiculite for plug seeding at a temperature of 25° C./20° C. (day/night). The four-leaf period comes 60 d after seeding. Select seedlings in the consistent growth condition and transplant them to the treated soil (April 19). Mix Cd and soil thoroughly 14 d before transplanting, treat the curing agent 7 d before transplanting and keep the soil wet. Use 5 L plastic barrels for the experiment with each barrel containing 4.5 kg of soil, 4 plants, 3 repetitions, 4 barrels/treatment, a total of 144 plants (9×4×4), and then take samples in the 6-leaf period 20 d after transplanting (May 9), where only the top part is sampled. A total of 9 treatments are set up: 1. CK, Cd and the curing agent not added; 2. A, 1.25 gA/pot; 3. B. 1.25 gB/pot; 4. Cd1, 1 mg/kg CdCl2; 5. Cd1+A, 1 mg/kg CdCl2+1.25 gA/pot 6. Cd1+B, 1 mg/kg CdCl2+1.25 gB/pot 7. Cd2, 5 mg/kg CdCl2; 8. Cd2+A, 5 mg/kg CdCl2+1.25 gA/pot 9. Cd2+B, 5 mg/kg CdCl2+1.25 gB/pot

(67) B is the curing agent prepared according to Embodiment 7; A is the raw materials used in Embodiment 7, which are obtained by simple mixing and then high-temperature distillation and used for control.

(68) Experiment Results:

(69) 1. Agronomic Properties:

(70) TABLE-US-00002 TABLE 2 Agronomic properties in the experiment for heavy metal cadmium to be relieved by the curing agent in tobacco Treatment Plant height (cm) Fresh weight (g) Dry weight (g) SPAD Cond stomatal 24.80 ± 0.71 a 9.59 ± 0.95 ab 2.338 ± 0.18 ab 33.64 ± 1.73 a conductivity A 23.53 ± 4.81 ab 8.86 ± 0.85 ab 2.462 ± 0.22 a 32.78 ± 1.54 ab B 24.27 ± 2.56 ab 10.2 ± 1.33 ab 2.651 ± 0.39 a  33.4 ± 1.48 a Cd1 19.70 ± 1.48 cd 7.91 ± 0.77 a 1.894 ± 0.26 c 33.02 ± 2.00 ab Cd1 + A 20.50 ± 1.97 bcd 8.36 ± 1.33 b 2.021 ± 0.38 bc 33.64 ± 2.55 a Cd1 + B 22.70 ± 0.46 abc 9.65 ± 1.21 b 2.075 ± 0.45 bc 33.44 ± 0.68 a Cd2 21.47 ± 2.42 abc 8.95 ± 1.30 ab 1.990 ± 0.21 bc 32.72 ± 1.26 ab Cd2 + A 17.53 ± 0.58 d 6.82 ± 0.09 b 1.809 ± 0.21 c  34.1 ± 1.80 a Cd2 + B 17.30 ± 1.39 d 7.85 ± 0.72 ab 1.936 ± 0.40 c  31.0 ± 0.75 b Note: the letters in the table show significant level, the same as in the report.

(71) Concentration of heavy metal cadmium:

(72) TABLE-US-00003 TABLE 3 Contents of cadmium in various treatments to be relieved by the curing agent in tobacco Content of fertilizer Cd sulfur (g/pot) Cd concentration (μg/g) Code (mg/kg) A B Repeat I Repeat II Repeat III Average CK 0 0 0 0.019 0.020 0.016 0.018 A 0 1.25 0 0.007 0.005 0.003 0.005 B 0 0 1.25 0.020 0.016 0.016 0.018 Cd1 1.0 0 0 0.584 0.764 0.670 0.673 Cd1 + A 1.0 1.25 0 0.354 0.158 0.406 0.306 Cd1 + B 1.0 0 1.25 0.146 0.136 0.197 0.160 Cd2 5.0 0 0 1.432 2.356 2.960 2.249 Cd2 + A 5.0 1.25 0 2.419 3.825 1.848 2.698 Cd2 + B 5.0 0 1.25 1.420 2.119 0.651 1.396

(73) 3. Light and Parameters

(74) TABLE-US-00004 TABLE 4 Photosynthetic parameters of tobacco leaves Stomatal Intercellular CO2 Photosynthetic rate conductivity concentration Transpiration rate Code (μmol CO2 m-2 s-1) (mol H2O m-2 s-1) (μmol CO2 mol-1) (mmol H2O m-2 s-1) CK 15.28 ± 1.25 a 0.2716 ± 0.05 bc 310.8 ± 13.29 e 3.348 ± 0.77 bc A 15.16 ± 1.61 ab 0.3062 ± 0.13 abc 313.2 ± 16.27 e 3.696 ± 1.29 ab B 14.06 ± 0.50 cd 0.3464 ± 0.09 ab 322.2 ± 10.99 de 4.458 ± 0.57 a Cd1 13.78 ± 0.52 d 0.2614 ± 0.07 c   344 ± 10.63 ab 2.676 ± 0.87 c Cd1 + A 14.14 ± 0.79 bcd  0.332 ± 0.05 abc 328.6 ± 5.94  cd 3.942 ± 0.67 ab Cd1 + B 14.96 ± 0.48 abc 0.3618 ± 0.04 a  337 ± 6.52 bc  4.06 ± 0.43 ab Cd2 12.52 ± 0.55 e 0.3328 ± 0.00 abc 329.6 ± 4.56  cd 4.374 ± 0.23 a Cd2 + A 11.42 ± 0.77 f 0.3038 ± 0.03 abc 351.4 ± 7.64  a  4.62 ± 0.82 a Cd2 + B 12.46 ± 0.44 ef  0.272 ± 0.01 bc  320 ± 1.87 de  4.49 ± 0.07 a

(75) Result Analysis:

(76) 1. Influences of A and B on the growth of tobacco seedlings under cadmium stress

(77) A negative correlation is found between the concentration of cadmium and the inhibition to growth 20 d after transplanting (Table 2). High-concentration cadmium facilitates the growth of the top part of the tobacco, but not significantly. Meanwhile, upon the treatment with low-concentration cadmium, A and B effectively relieve the inhibition to the growth of tobacco. With high-concentration cadmium, A and B aggravate the inhibition to the growth of tobacco, which shows that the curing agent in this condition facilitates the accumulation of cadmium in the tobacco leaf, thus further causing the aggravated inhibition to the growth of tobacco after the tobacco is contaminated by cadmium. This indicates that, antagonism occurs between sulfur and cadmium when cadmium is in low concentrations and synergy occurs when cadmium is in high concentration. This may be caused by the curing agent which facilitates the accumulation of cadmium in the roots and stems to transfer to the leaves (An Zhizhuang et al, 2004), while Fertilizer A has a higher transfer effect to cadmium than Fertilizer B.

(78) 2. Influences of A and B on the chlorophyll content (SPAD value) of tobacco seedlings under cadmium stress

(79) A positive correlation is found between the SPAD value of leaves and the chlorophyll content. The measuring result is a relative value reflecting the chlorophyll content of the leaves. In this experiment, cadmium treatment reduces the chlorophyll content of tobacco leaves (Table 2), but not significantly. The application of A and B increases the chlorophyll content of leaves, but still not significantly. This may be because the low cadmium concentration in the leaves cannot lead to big destruction of the chlorophyll structure.

(80) 3. Influences of A and B on the cadmium content in tobacco seedlings under the cadmium stress

(81) After cadmium is absorbed by the plants, most cadmium enriches the roots and little cadmium transfers to the aboveground part (Table 3). With the low-concentration cadmium, both A and B can significantly reduce the concentration of cadmium in tobacco seedlings, especially under the treatment of B, the aboveground cadmium content is reduced by 76% than the single-cadmium treatment. Under the treatment of high-concentration cadmium, Fertilizer B significantly reduces the accumulated cadmium content at the roots only. This shows that Fertilizer A is effective only for the reduction of the aboveground cadmium content under the treatment of low-concentration cadmium, but Fertilizer B is effective in the reduction of the cadmium content under the treatment of cadmium with different concentrations.

(82) 4. Influences of A and B on the photosynthetic parameters of tobacco leaves under cadmium stress

(83) Compared with the control level, the cadmium stress reduces the photosynthetic rate (9.81% in Cd1, 18.1% in Cd2), as shown in Table 4. Both A and B in Cd1 increase the photosynthetic rate, but the application of A in Cd2 significantly reduces the photosynthetic rate. However, it is worth mentioning that application B leads to the photosynthetic rate to be restored to almost the control level. B effectively relieves the reduction of the photosynthetic rate caused by the cadmium.

(84) The cadmium treatment has a complicated impact on the stomatal conductivity of tobacco. The stomatal conductivity is reduced in Cd 1, increased in Cd2, but both not significantly. A and B have inhibition effect on the stomatal conductivity only when the cadmium concentration is high. No matter the increase or reduction of the stomatal conductivity, B is more significant than A.

(85) Cadmium also increases intercellular CO.sub.2 concentration in the leaves. Between the two fertilizers, A is more susceptible to the concentration of cadmium. Under the cadmium stress with two concentrations, B can reduce inter-cellular CO.sub.2 concentration, but not significantly.

(86) After the cadmium treatment, compared with the control level, the transpiration rate in Cd1 is significantly reduced while that in Cd2 is significantly increased. Under the cadmium treatment with different concentrations, both A and B can increase the transpiration rate (both showing significant increase in Cd1), but the increase in the transpiration rate for A is higher than that for B only in Cd2, A and B have also inconsistent change of the transpiration rate under the cadmium treatment with the two concentrations.