生态环境学报
生態環境學報
생태배경학보
ECOLOGY AND ENVIRONMENT
2014年
6期
1064-1069
,共6页
徐向华%刘传平%唐新莲%雷静%顾明华%李芳柏
徐嚮華%劉傳平%唐新蓮%雷靜%顧明華%李芳柏
서향화%류전평%당신련%뢰정%고명화%리방백
砷%水稻%硒%硅%叶面喷施
砷%水稻%硒%硅%葉麵噴施
신%수도%서%규%협면분시
Arsenic%Rice%Selenium%Silica%Foliar application
砷是一种毒性较强的类金属元素,稻米砷污染是近年来环境科学关注的难点和热点问题。为了控制稻米对砷的吸收积累,利用水热合成法制备了一系列浓度硒掺杂硅复合溶胶。采用盆栽和大田试验结合的方法,研究了硒掺杂纳米硅溶胶对水稻(Oryza sativa L.)砷吸收积累的影响。结果显示,叶面喷施硒掺杂纳米硅溶胶可以有效缓解水稻砷毒害,增加稻米硒含量,抑制稻米砷积累。盆栽试验结果表明:叶面喷施质量分数1%的硒掺杂纳米硅溶胶(1%Se-Si 处理)后,水稻籽粒干质量比对照增加了43.8%,砷含量下降了46%,硒含量由对照的0.050 mg·kg-1增加到0.272 mg·kg-1。且与喷施亚硒酸钠相比(1%Se处理),喷施硒掺杂纳米硅溶胶更有利于水稻生长,抑制稻米砷积累。与喷施硒质量分数1%的亚硒酸钠(1%Se处理)相比,喷施质量分数1%的硒掺杂纳米硅溶胶(1%Se-Si处理)后,水稻籽粒干质量增加了65.4%,砷含量下降了33.1%。大田试验结果也表明:叶面喷施硒硅复合溶胶可以显著抑制稻米砷积累,且随着硒掺杂量的增加,稻米砷含量显著降低、硒含量显著增加;硒的最佳掺杂量质量分数为0.5%,叶面喷施这种硒掺杂硅溶胶,稻米总砷质量分数由对照的0.25 mg·kg-1下降到0.14 mg·kg-1,稻米中硒的质量分数为0.26 mg·kg-1,符合富硒大米标准。砷污染稻田上,叶面喷施硒硅复合溶胶不仅使稻米砷含量达标,而且可以生产出富硒大米。因此,叶面喷施硒硅复合溶胶可能是治理稻米砷污染的新途径。
砷是一種毒性較彊的類金屬元素,稻米砷汙染是近年來環境科學關註的難點和熱點問題。為瞭控製稻米對砷的吸收積纍,利用水熱閤成法製備瞭一繫列濃度硒摻雜硅複閤溶膠。採用盆栽和大田試驗結閤的方法,研究瞭硒摻雜納米硅溶膠對水稻(Oryza sativa L.)砷吸收積纍的影響。結果顯示,葉麵噴施硒摻雜納米硅溶膠可以有效緩解水稻砷毒害,增加稻米硒含量,抑製稻米砷積纍。盆栽試驗結果錶明:葉麵噴施質量分數1%的硒摻雜納米硅溶膠(1%Se-Si 處理)後,水稻籽粒榦質量比對照增加瞭43.8%,砷含量下降瞭46%,硒含量由對照的0.050 mg·kg-1增加到0.272 mg·kg-1。且與噴施亞硒痠鈉相比(1%Se處理),噴施硒摻雜納米硅溶膠更有利于水稻生長,抑製稻米砷積纍。與噴施硒質量分數1%的亞硒痠鈉(1%Se處理)相比,噴施質量分數1%的硒摻雜納米硅溶膠(1%Se-Si處理)後,水稻籽粒榦質量增加瞭65.4%,砷含量下降瞭33.1%。大田試驗結果也錶明:葉麵噴施硒硅複閤溶膠可以顯著抑製稻米砷積纍,且隨著硒摻雜量的增加,稻米砷含量顯著降低、硒含量顯著增加;硒的最佳摻雜量質量分數為0.5%,葉麵噴施這種硒摻雜硅溶膠,稻米總砷質量分數由對照的0.25 mg·kg-1下降到0.14 mg·kg-1,稻米中硒的質量分數為0.26 mg·kg-1,符閤富硒大米標準。砷汙染稻田上,葉麵噴施硒硅複閤溶膠不僅使稻米砷含量達標,而且可以生產齣富硒大米。因此,葉麵噴施硒硅複閤溶膠可能是治理稻米砷汙染的新途徑。
신시일충독성교강적류금속원소,도미신오염시근년래배경과학관주적난점화열점문제。위료공제도미대신적흡수적루,이용수열합성법제비료일계렬농도서참잡규복합용효。채용분재화대전시험결합적방법,연구료서참잡납미규용효대수도(Oryza sativa L.)신흡수적루적영향。결과현시,협면분시서참잡납미규용효가이유효완해수도신독해,증가도미서함량,억제도미신적루。분재시험결과표명:협면분시질량분수1%적서참잡납미규용효(1%Se-Si 처리)후,수도자립간질량비대조증가료43.8%,신함량하강료46%,서함량유대조적0.050 mg·kg-1증가도0.272 mg·kg-1。차여분시아서산납상비(1%Se처리),분시서참잡납미규용효경유리우수도생장,억제도미신적루。여분시서질량분수1%적아서산납(1%Se처리)상비,분시질량분수1%적서참잡납미규용효(1%Se-Si처리)후,수도자립간질량증가료65.4%,신함량하강료33.1%。대전시험결과야표명:협면분시서규복합용효가이현저억제도미신적루,차수착서참잡량적증가,도미신함량현저강저、서함량현저증가;서적최가참잡량질량분수위0.5%,협면분시저충서참잡규용효,도미총신질량분수유대조적0.25 mg·kg-1하강도0.14 mg·kg-1,도미중서적질량분수위0.26 mg·kg-1,부합부서대미표준。신오염도전상,협면분시서규복합용효불부사도미신함량체표,이차가이생산출부서대미。인차,협면분시서규복합용효가능시치리도미신오염적신도경。
Arsenic is a non-threshold carcinogenic metalloid. It becomes a growing public concern on amelioration the As contamination in paddy soils and reduction the As transfer to rice in recent years. In order to reduce the accumulation of arsenic in rice (Oryza sativa L.), a series of concentrations of selenium doped silica sols were prepared by hydrothermal synthesis method. The effects of foliar application of selenium-silica sols on the arsenic accumulation in rice were investigated with pot and field experiments. The results showed that foliar application of selenium doped silicon sol was effective in alleviating the arsenic toxicity to rice, increasing selenium content of rice, and inhibiting the accumulation of arsenic in rice. Comparing with the control in the pot experiments, 1%Se doped silica sol (1%Se-Si) foliar application increased the rice grain dry weight by 43.8%, while decreased the arsenic concentration in rice grain by 46% and increased Se concentration in rice grain from 0.050 mg·kg-1 to 0.272 mg·kg-1. Comparing with 1% sodium selenite foliar application (1%Se) in the pot experiments, the dry weight of rice grain increased by 65.4%, while the As concentration in rice grain decreased by 33.1% with 1% Se doped silica sol (1%Se-Si) treatment. Field experiment results showed that foliar application of selenium-silicon composite sol could significantly inhibit the accumulation of arsenic in rice. With the foliar application of selenium-silica composite sols, the arsenic concentration of rice grain decreased with the increasing doping amount of selenium added into the selenium-silica sols, while the selenium content increased significantly with the increasing doping amount of selenium. The optimal doping of selenium was 0.5%, foliar application of this kind of Se doped silica sol, the total arsenic concentration of rice decreased from 0.25 mg·kg-1 of control to 0.14 mg·kg-1, and the selenium concentration in rice grain was 0.26 mg·kg-1, which was accorded with the standard of selenium enriched rice. It should be concluded that foliar application Se doped silica sol should be an effective method for As risk control for rice in As contaminated soil.
