云南烟区土壤、肥料和烟叶中的放射性核素
摘要
根据成土母质、土壤类型、人为耕作等因素在云南主要产烟区采集土壤样品,并同步采集烟叶样品和烟叶主产区主要使用的复合肥、钾肥、磷肥等肥料。样品消解后用LS-6500液体闪烁计数仪测量样品中的总α和总β放射性。用低本底γ能谱仪测量样品中的~(60)Co、~(137)Cs、~(40)K、~(238)U、~(232)Th、~(226)Ra的放射性比活度。同时进行了磷肥用量对烟叶放射性影响的田间试验。
研究结果如下:
1.土壤中放射性核素含量的高低顺序为~(40)K>~(238)U>~(232)Th>~(226)Ra>~(137)Cs,其含量平均值和变化范围分别为~(40)K:549.14Bq/Kg,151~1170Bq/Kg;~(238)U:77.77Bq/Kg,13.8~281Bq/Kg;~(232)Th:56.43Bq/Kg,12.3~164Bq/Kg:~(220)Ra:48.64Bq/Kg,10.2~159Bq/Kg;~(157)Cs:3.64Bq/Kg,0.488~8.72Bq/Kg。土壤中~(60)Co含量低于仪器探测限。各地土壤中的核素含量不一,其中大理的~(137)Cs,玉溪的~(40)K,红河的~(226)Ra和~(238)U,临沧的~(232)Th含量最高。
2.土壤中的放射性核素含量变化较大,土壤母质和施肥等因素是土壤中放射性核素的重要来源。成土母质的多样性,地形地貌的复杂性、植物根系的富集性及肥料种类的差异性等因素是造成土壤中放射性核素含量变异较大的主要原因。
3.土壤中~(40)K和~(238)U表现为积累型,~(226)Ra和~(232)Th表现为损耗型。放射性核素的积累与损耗与肥料中核素的含量、植物对核素的吸收能力、核素自身的化学性质以及土壤的理化性质如pH值等因素有关。
4.土壤中的总α放射性活度平均值为548.03Bq/Kg,变化于248.74~1047.74Bq/Kg之间;总β放射性活度的平均值为654.49Bq/Kg,变化于244.60~2082.70Bq/Kg之间。除玉溪地区外,土壤中的总α放射性小于总β放射性。
5.在云南烟区三类主要土壤中,红壤的~(137)Cs、~(226)Ra、~(232)Th、~(238)U的含量最高,紫色土的~(40)K和总β最高,水稻土的总α最高。
6.与国内外文献相比较,云南烟区土壤中~(137)Cs的含量低于四川省,总α低于上海市,总β低于四川省和上海市。除~(40)K外,其它天然放射性核素~(226)Ra、~(232)Th、~(238)U的含量均高于全国平均值,其中~(238)U最为显著,高于其它任何地区。~(40)K、~(232)Th、~(238)U的含量均高于世界典型值。
7.供试肥料中,宁夏生产的稀十有机复合肥含~(137)Cs的含量最高,复肥和磷肥其次,钾肥中~(137)Cs的含量最低。几种肥料中~(137)Cs的含量差异不大。
钾肥中~(40)K含量远高于其它肥料。复肥和稀土有机肥中的~(40)K含量低于钾肥,远高于磷肥。磷肥中的~(40)K含量最低。钾肥对土壤中的~(40)K的积累影响最大。
磷肥中~(226)Ra和~(238)U的含量最高,钾肥中~(226)Ra和~(238)U的含量最低,稀土有机复合肥和复肥处于中等水平。虽然磷肥中~(226)Ra的含量低于国家标准规定的限制浓度,但其中的~(226)Ra和~(238)U的含量仍远高于土壤,施用磷肥是农业土壤中~(226)Ra和~(238)U的重要来源。
肥料中~(232)Th的含量在几种天然放射性核素中最低,以稀土有机复合肥中~(232)Th的含量最高。供试肥料中~(232)Th的含量均低于土壤含量,对土壤中~(232)Th的积累影响较小。
磷肥总α放射性最高,钾肥总β放射性最高,复肥总α和总β放射性处于中等水平,稀土有机复合肥在几种肥料中最低。
8.烟叶中各核素的含量平均值为~(137)Cs:1.02Bq/Kg,~(40)K:820.4Bq/Kg,~(226)Ra:3.18Bq/Kg,~(232)2Th:5.74Bq/Kg,~(238)U:30.05Bq/Kg。烟叶中~(60)Co的含量低于仪器探测限。各核素含量高低顺序为
仰》欢业人#枷/>&IE卫
。。K>二。。U>。。。Th>二ZoR。>’1一Cs@ 厄。卜壤中各核索含一高低顺序一致口烟n中习‘K含挝远高}卜
壤,其它核素含量低}”十琐。
烟叶中‘OK含量的变异柠度较小,”’C。、”‘Ra、”’TI。、j’U的变异程度较人。各地烟IZ
的核素含量不同,其中昆明的‘厂Cs;楚硼的川K,临沧的H‘Ra、刀‘TI。以及人lpn‘U含这
最高。
烟叶中总。放射性活度“卜均值为29!S4Bq/他,约为十壤的10,总p放射性活度平均伯
为793刀68丫他,烟叶总。小干总p。各地烟【中总。和总p的变异性不大,前者变异系数
为15.78%,后者变异系数为9.8%。
9.烟叶对士壤中放射性核素的转移系数大*p序为“K>”‘U>”’CS>”’Tll>2’‘RI,转移系数5厂
别为1.49、0.39、0二8。010、0刀7。烟叶对‘’K的富集能力最强,对‘’‘卜a的富集能力最弱-
烟叶对十壤总。和总p的转移系数分别为O臼、1二1。烟叶对土壤总。和总日的转移系数小
同主要是因为烟叶吸收以Off变为主的”‘RO、’”“U、’”’Tll和以p衰变为主的“K的能力有所
差异。
10.烟则和士壤中刀二!。含量的习关性最在,总。的相关性次之,”’*s‘’K’**a”‘U 一
e的相关性较差。根据相X系数推测,烟川中’刀、h和总。放射性主要来源于士壤;驯K和总
p主要来自于施肥:”‘Rs部分来源于十壤,部分来源于肥料;烟草
Soils and tobacco were sampled together according to soil parent materials, soil types and cultivation practices. The a and p radioactivities in the samples were determined by LS-6500 liquid scintillation counter following digestion. And the actives of 60Co, 137Cs, 40K, 238U, 232Th, and 226Ra in soil samples were detected by low background y spectrometer. The measurements of radionuclides and activities were performed similarly in phosphorus, potassium and complex fertilizers. Moreover, the effects of phosphorus fertilizers on radionuclides and activities in tobacco were studied in a field experiment.
Following are the results obtained:
1. The concentrations of radionuclides in soils followed the role of 40K> 238U> 232Th> 226Ra>'37Cs. The means of 40K, 238U, 232Th, 226Ra and l37Cs are .549.14Bq/Kg, 77.77Bq/Kg, 56.43Bq/Kg, 48.64Bq/Kg and 3.64Bq/Kg, respectively. They fluctuated from 151Bq/Kg to 1170Bq/Kg (*%.), 13.8Bq/Kg to 281Bq/Kg (238U), 12.3Bq/Kg to 164Bq/Kg (232Th), 10.2Bq/Kg to 159Bq/Kg (226Ra) and 0.488Bq/Kg to 8.72Bq/Kg (I37Cs). The contents of ^Co were lower than the limit of detector. Furthermore, radionoclides varied in soils and highest concentrations of l37Cs, 40K, 226Ra and 238U and 232Th were found in the soils in Dali, Yuxi, Honghe and Lincang regions, respectively.
2. Great changes of radionuclides were detected in soils and most of them came from, parent materials and fertilizers. The main reason for the variations could be explained by different parent materials, complicate landform, radionuclides absorption by plants, fertilization and cultivation practices.
3. 40K and 238U accumulated, while 226Ra and 232Th depleted in soils. The accumulation and depletion were related to the nuclides in fertilizers, abilities of nuclides absorption by plants, physical and chemical properties of nuclides and soils such as pH and so on.
4. The averages of a and P radioactivities were 548.03Bq/Kg and 654.49Bq/Kg
respectively, which varied from 248.74Bq/Kg to 1047.74Bq/Kg (a) and from 244.60Bq/Kg to 2082.70Bq/Kg (p). It is noticed a radioactivities were less than P radioactivities in soils except those in Yuxi area.
5. The concentrations of 137Cs,226Ra, B2Th and238U were highest in red soils, while highest 40K and |3-radioactivity were observed in purplish ones and a in paddy soils.
6. The conctents of I37Cs and a-radioactivities in tobacco growing soils were lower than Sichuan and Shanghai, respectively, in contrast to p-radioactivities, which was lower than both Sichuan and Shanghai. Moreover the average concentrations of 226Ra, 2j2Th and 238U were higher than those of our country, China, except K, which was relatively low. It is noticed that 238U was higher than those in any other areas in China. These contents of radionuclides in Yunnan were also higher than the volumes in typical areas.
7. In regards to the concentrations of 137Cs in measured fertilizers, they followed the order of rare - organic fertilizer>composite fertilizers>phosphorus fertilizers> potassium fertilizers, but no remarkable differences of 137Cs were detected among these fertilizrs.
The concentration of 40K were in order of potassium fertilizers?composite fertilizers and phosphorus fertilizers?rare - organic fertilizer, indicating the greate influences of 40K in potassium fertilizers on soil 40K.
The measurement showed the higher contents of 226Ra and 2;>8U in phosphrous fertilizers than those in rare - organic fertilizer and in composite fertilizers and than those in potassium fertilizers once more. The concentrations of 226Ra in phosphate fertilizers were much higher than those in soils, enve though they were lower than the national regulation standards, showing that the two radionuclides in soils mainly could come from phophrous fertilizers in the case of large amount of phosphate supplied in tobacco production.
The concentrations of Th were lowest in fertilizers compared to any other radionuclides. 232Th in rare - organic fertilizer was the highest in the fertilizers detected.
研究结果如下:
1.土壤中放射性核素含量的高低顺序为~(40)K>~(238)U>~(232)Th>~(226)Ra>~(137)Cs,其含量平均值和变化范围分别为~(40)K:549.14Bq/Kg,151~1170Bq/Kg;~(238)U:77.77Bq/Kg,13.8~281Bq/Kg;~(232)Th:56.43Bq/Kg,12.3~164Bq/Kg:~(220)Ra:48.64Bq/Kg,10.2~159Bq/Kg;~(157)Cs:3.64Bq/Kg,0.488~8.72Bq/Kg。土壤中~(60)Co含量低于仪器探测限。各地土壤中的核素含量不一,其中大理的~(137)Cs,玉溪的~(40)K,红河的~(226)Ra和~(238)U,临沧的~(232)Th含量最高。
2.土壤中的放射性核素含量变化较大,土壤母质和施肥等因素是土壤中放射性核素的重要来源。成土母质的多样性,地形地貌的复杂性、植物根系的富集性及肥料种类的差异性等因素是造成土壤中放射性核素含量变异较大的主要原因。
3.土壤中~(40)K和~(238)U表现为积累型,~(226)Ra和~(232)Th表现为损耗型。放射性核素的积累与损耗与肥料中核素的含量、植物对核素的吸收能力、核素自身的化学性质以及土壤的理化性质如pH值等因素有关。
4.土壤中的总α放射性活度平均值为548.03Bq/Kg,变化于248.74~1047.74Bq/Kg之间;总β放射性活度的平均值为654.49Bq/Kg,变化于244.60~2082.70Bq/Kg之间。除玉溪地区外,土壤中的总α放射性小于总β放射性。
5.在云南烟区三类主要土壤中,红壤的~(137)Cs、~(226)Ra、~(232)Th、~(238)U的含量最高,紫色土的~(40)K和总β最高,水稻土的总α最高。
6.与国内外文献相比较,云南烟区土壤中~(137)Cs的含量低于四川省,总α低于上海市,总β低于四川省和上海市。除~(40)K外,其它天然放射性核素~(226)Ra、~(232)Th、~(238)U的含量均高于全国平均值,其中~(238)U最为显著,高于其它任何地区。~(40)K、~(232)Th、~(238)U的含量均高于世界典型值。
7.供试肥料中,宁夏生产的稀十有机复合肥含~(137)Cs的含量最高,复肥和磷肥其次,钾肥中~(137)Cs的含量最低。几种肥料中~(137)Cs的含量差异不大。
钾肥中~(40)K含量远高于其它肥料。复肥和稀土有机肥中的~(40)K含量低于钾肥,远高于磷肥。磷肥中的~(40)K含量最低。钾肥对土壤中的~(40)K的积累影响最大。
磷肥中~(226)Ra和~(238)U的含量最高,钾肥中~(226)Ra和~(238)U的含量最低,稀土有机复合肥和复肥处于中等水平。虽然磷肥中~(226)Ra的含量低于国家标准规定的限制浓度,但其中的~(226)Ra和~(238)U的含量仍远高于土壤,施用磷肥是农业土壤中~(226)Ra和~(238)U的重要来源。
肥料中~(232)Th的含量在几种天然放射性核素中最低,以稀土有机复合肥中~(232)Th的含量最高。供试肥料中~(232)Th的含量均低于土壤含量,对土壤中~(232)Th的积累影响较小。
磷肥总α放射性最高,钾肥总β放射性最高,复肥总α和总β放射性处于中等水平,稀土有机复合肥在几种肥料中最低。
8.烟叶中各核素的含量平均值为~(137)Cs:1.02Bq/Kg,~(40)K:820.4Bq/Kg,~(226)Ra:3.18Bq/Kg,~(232)2Th:5.74Bq/Kg,~(238)U:30.05Bq/Kg。烟叶中~(60)Co的含量低于仪器探测限。各核素含量高低顺序为
仰》欢业人#枷/>&IE卫
。。K>二。。U>。。。Th>二ZoR。>’1一Cs@ 厄。卜壤中各核索含一高低顺序一致口烟n中习‘K含挝远高}卜
壤,其它核素含量低}”十琐。
烟叶中‘OK含量的变异柠度较小,”’C。、”‘Ra、”’TI。、j’U的变异程度较人。各地烟IZ
的核素含量不同,其中昆明的‘厂Cs;楚硼的川K,临沧的H‘Ra、刀‘TI。以及人lpn‘U含这
最高。
烟叶中总。放射性活度“卜均值为29!S4Bq/他,约为十壤的10,总p放射性活度平均伯
为793刀68丫他,烟叶总。小干总p。各地烟【中总。和总p的变异性不大,前者变异系数
为15.78%,后者变异系数为9.8%。
9.烟叶对士壤中放射性核素的转移系数大*p序为“K>”‘U>”’CS>”’Tll>2’‘RI,转移系数5厂
别为1.49、0.39、0二8。010、0刀7。烟叶对‘’K的富集能力最强,对‘’‘卜a的富集能力最弱-
烟叶对十壤总。和总p的转移系数分别为O臼、1二1。烟叶对土壤总。和总日的转移系数小
同主要是因为烟叶吸收以Off变为主的”‘RO、’”“U、’”’Tll和以p衰变为主的“K的能力有所
差异。
10.烟则和士壤中刀二!。含量的习关性最在,总。的相关性次之,”’*s‘’K’**a”‘U 一
e的相关性较差。根据相X系数推测,烟川中’刀、h和总。放射性主要来源于士壤;驯K和总
p主要来自于施肥:”‘Rs部分来源于十壤,部分来源于肥料;烟草
Soils and tobacco were sampled together according to soil parent materials, soil types and cultivation practices. The a and p radioactivities in the samples were determined by LS-6500 liquid scintillation counter following digestion. And the actives of 60Co, 137Cs, 40K, 238U, 232Th, and 226Ra in soil samples were detected by low background y spectrometer. The measurements of radionuclides and activities were performed similarly in phosphorus, potassium and complex fertilizers. Moreover, the effects of phosphorus fertilizers on radionuclides and activities in tobacco were studied in a field experiment.
Following are the results obtained:
1. The concentrations of radionuclides in soils followed the role of 40K> 238U> 232Th> 226Ra>'37Cs. The means of 40K, 238U, 232Th, 226Ra and l37Cs are .549.14Bq/Kg, 77.77Bq/Kg, 56.43Bq/Kg, 48.64Bq/Kg and 3.64Bq/Kg, respectively. They fluctuated from 151Bq/Kg to 1170Bq/Kg (*%.), 13.8Bq/Kg to 281Bq/Kg (238U), 12.3Bq/Kg to 164Bq/Kg (232Th), 10.2Bq/Kg to 159Bq/Kg (226Ra) and 0.488Bq/Kg to 8.72Bq/Kg (I37Cs). The contents of ^Co were lower than the limit of detector. Furthermore, radionoclides varied in soils and highest concentrations of l37Cs, 40K, 226Ra and 238U and 232Th were found in the soils in Dali, Yuxi, Honghe and Lincang regions, respectively.
2. Great changes of radionuclides were detected in soils and most of them came from, parent materials and fertilizers. The main reason for the variations could be explained by different parent materials, complicate landform, radionuclides absorption by plants, fertilization and cultivation practices.
3. 40K and 238U accumulated, while 226Ra and 232Th depleted in soils. The accumulation and depletion were related to the nuclides in fertilizers, abilities of nuclides absorption by plants, physical and chemical properties of nuclides and soils such as pH and so on.
4. The averages of a and P radioactivities were 548.03Bq/Kg and 654.49Bq/Kg
respectively, which varied from 248.74Bq/Kg to 1047.74Bq/Kg (a) and from 244.60Bq/Kg to 2082.70Bq/Kg (p). It is noticed a radioactivities were less than P radioactivities in soils except those in Yuxi area.
5. The concentrations of 137Cs,226Ra, B2Th and238U were highest in red soils, while highest 40K and |3-radioactivity were observed in purplish ones and a in paddy soils.
6. The conctents of I37Cs and a-radioactivities in tobacco growing soils were lower than Sichuan and Shanghai, respectively, in contrast to p-radioactivities, which was lower than both Sichuan and Shanghai. Moreover the average concentrations of 226Ra, 2j2Th and 238U were higher than those of our country, China, except K, which was relatively low. It is noticed that 238U was higher than those in any other areas in China. These contents of radionuclides in Yunnan were also higher than the volumes in typical areas.
7. In regards to the concentrations of 137Cs in measured fertilizers, they followed the order of rare - organic fertilizer>composite fertilizers>phosphorus fertilizers> potassium fertilizers, but no remarkable differences of 137Cs were detected among these fertilizrs.
The concentration of 40K were in order of potassium fertilizers?composite fertilizers and phosphorus fertilizers?rare - organic fertilizer, indicating the greate influences of 40K in potassium fertilizers on soil 40K.
The measurement showed the higher contents of 226Ra and 2;>8U in phosphrous fertilizers than those in rare - organic fertilizer and in composite fertilizers and than those in potassium fertilizers once more. The concentrations of 226Ra in phosphate fertilizers were much higher than those in soils, enve though they were lower than the national regulation standards, showing that the two radionuclides in soils mainly could come from phophrous fertilizers in the case of large amount of phosphate supplied in tobacco production.
The concentrations of Th were lowest in fertilizers compared to any other radionuclides. 232Th in rare - organic fertilizer was the highest in the fertilizers detected.
引文
1.包国章,李向林,谢忠雷等.2001,生物放大作用的危害及预防.中国环境管理(3):10~12.
2.常宏等.1999.伴生放射性矿物资源开发应用中的环境问题与管理.甘肃环境研究与监测.12(3):147~149,158.
3.陈传群,徐寅良,孙志明.1990,小麦对~(134)C_s吸收的研究.环境科学.11(6):10~14.
4.陈迪云,王湘云,陈永亨.2000.铀矿区附近牛对放射性核素环境转移的指示.中国环境科学.20(4):465~468.
5.陈景坚,朱永懿,杨俊城等.1991.磷肥中的放射性核素及其在土壤和作物中的积累规律.温贤芳,姚允.同位素示综技术农业应用研究进展.北京:中国农业科技出版社.1991:7~19.
6.陈克玲,陈榜根,张孝珍等.1990.湖北省食品和水中天然放射性核素水平.中国环境科学.10(1)71~75.
7.范仲学,徐世明,赵文虎等.1998.水稻对~(157)C_s的叶面吸收.农业环境保护.17(1):8~10.
8.高薇薇,易莲芳,王玉琴等.1991.福建省土壤中天然放射性水平的调查.环境科学.11(1):75~79.
9.国家统计局.2000.中国统计年签.239.
10.郭伯生等.1988.农业中的稀土.北京:中国农业科技出版社.
11.郭立本,王心明,胡晓林等.青海省土壤中天然放射性核素含量凋查研究.辐射防护.14(3):226~229.
12.韩华峰,颛淑菊,刘洪卿等.1994.河南省土壤中天然放射性核素含量调查研究.辐射防护.14(1):60~62,66.
13.韩寿岭.1998.施用磷肥对农田放射性污染的探讨.磷肥与复肥.(5)66~67.
14.靖玉佩,王力,田毅等.1995.宁夏回族自治区土壤中天然放射性核素含量调查研究.辐射防护.15(2):125~128.
15.李长兴,李钟伟,冯志国等.1997.大庆地区土壤环境放射性水平的调查.环境科学.18(4):72~75.
16.李贵宝,单保庆,孙克刚等.2000.粉煤灰的农业利用研究进展.磷肥与复肥.15(6):59~60
17.李新德,郑永红,吴向荣等.1993.江西省土壤中天然放射性核素含量调查.辐射防护.13(4):291~294.
18.林忠辉等.2000.磷肥杂质对生态环境的影响.生态农业研究.8(2)48~50.
19.刘琼英,邝炎华.1990,环境中放射性核素经根吸收向农作物转移的研究.农业环境保护9(4):44~46.
20.刘志和,赵淑权,胡志力.1989.山东省主要农产品中放射性核素浓度及其浓集特性.中国环境监测.5(4):49~50.
21.吕志文,郝国凡,张福山等.1993.吉林省土壤中天然放射性核素含量调查研究.辐射防护.13(6):449~452.
22.马斯纳H.(德)著,曹一平,陆景陵等译.1991.高等植物的矿质营养.北京:北京农业大学出版社.
23.马玉琴等.1980.磷肥放射性水平及其对水源的影响.环境保护.(2)23~25.
24.聂辉兰,陈淑怡,朱利群等.1983.稀土定位试验中水稻、大豆对天然放射性核素的积累.农业环境保护.(3):7~9.
25.普拉萨德K.N.1984.人体放射生物学.北京:原子能出版社.
26.钱马懿,陈旭明,朱锡荣.1999.中国肿瘤.8(3):110~111.
27.全国土壤普查办公室.1998.中国土壤.北京:中国农业出版社.
28.全国土壤普查办公室.1996.中国土种志(第六卷).中国农业出版社.北京:2~62,352~360.
29.任礼华,裴永法,李金全等.1991.上海市土壤放射性水平的调查.上海环境科学.10(12):28~30.
30.盛青等.1997.核工业理化工程研究院燃煤的辐射环境影响.城市环境与城市生态.10(增刊):36~38.
31.帅震清.1987.煤电厂和核电厂对环境的影响比较.四川环境.6(1):8~10,14.
32.孙克刚,张学斌,汪立刚.2001.杂交油菜施用粉煤灰磁化肥的效应.土壤与环境.10(3)224~226.
33.孙冶,李玉先,李广通等.1993.云南省土壤中天然放射性核素含量调查研究.辐射防护.13(2):127~130.
34.孙冶.2000.磷酸盐工业中的放射性污染及其防治.云南环境科学.19(1):46~47.
35.唐文浩.1991.凉山州天然放射性水平及其分布.环境科学.12(1):82~86.
36.唐绪兴,梁维华,田金池.1993.天津市土壤中天然放射性核素含量调查研究.辐射防护.13(3):213~217.
37.王菊芬.1992.浙江省磷肥中~(226)Ra的含量及其卫生学评价.中华放射医学与防护杂志.12(4):258~260.
38.王亮,侯振海,谷雅琴等.1990.稻米食物链中放射性核素的分布和转移.环境科学.10(4):31~24.
39.王少仁,夏培桢.1991.含磷化肥的α和β比放活性及其对农业土壤的影响.农业环境保护.10(6):241~243,259.
40.王文富主编.1996.云南土壤.昆明:云南科技出版社.
41.温贤芳.1999.中国核农学.河南:河南科学技术出版社.
42.吴成祥,董善武,赵德峰.1993.黑龙江省土壤中天然放射性核素含量调查.辐射防护.13(4):295~298.
43.吴家华,刘宝山,董云中等.1995.粉煤灰改土效应研究.土壤学报.32(3)334~340.
44.吴锦海,李金全,周天豹.1989.我国原煤及煤渣、粉煤灰的放射性水平调查.上海环境科学.8(1)28,17.
45.吴宇,何清平.1990.四川省土壤中放射性核素含量及总β调查研究.重庆环境科学.12(1):42~45.
46.吴宇等.1993.四川省土壤中天然放射性核素含量调查研究.辐射防护.13(5):376~379.
47.项亮等.1996.切尔诺贝利核事故泄露~(157)Cs在苏皖地区湖泊沉积物中的蓄积及时标意义.海洋与湖沼.27(2):132~137.
48.徐冠仁.1997.核农学导论.原子能出版社.北京:14~29,289~329.
49.徐寅良,陈凯旋,陈传群.1996.离子浓度对生物吸收~(134)Cs的影响.农业环境保护.15(2):49~52.
50.焉文祉,任礼华,吴锦海等.1981.燃煤电厂烟道放出的放射性物质初步探讨.环境科学.2(5):23~25.
51.杨刚,廖赤武.1983.天然放射性核素在使用含铀磷肥作物中的蓄积规律.环境科学.4(6):10~17.
52.杨鹤鸣,眭光凯.1994.上海市土壤中天然放射性核素含量调查研究.辐射防护.14(2):123~126.
53.杨名生等.1993.广西壮族自治区土壤中天然放射性核素含量调查研究.辐射防护.13(4):299~302.
54.杨宇虹,崔国明,黄必志.1999.钙对烤烟产质量及其主要植物学性状的影响.云南农业大学学报.14(2):148~152.
55.杨子文,张永红,郭桂枝等.1990.兰州地区块根、块茎类作物中天然放射性含量及其所致内照射剂量估量.农业环境保护.9(2):34~37.
56.叶崇开,黎旺生,钱位成等.1982.煤对环境的放射性污染.环境科学.3(1):49~53.
57.俞誉福.1993.环境放射性概论.上海:复旦大学出版社.
58.曾德崇,白见林,谢明义等.1988.四川省主要食品和饮水放射性水平及所致居民照射剂量的评价.重庆环境科学.10(2):38~43.
59.曾而康.1986.农用化肥的放射性.农业环境保护.(1):27~29.
60.曾庆卓,陈联光,郑伟.1993.广东省土壤中天然放射性核素含量调查研究.辐射防护.13(5):372~375.
61.张大道.1985.化肥污染的趋势与对策.环境科学.6(6):54~59.
62.张金明,陈宝田,张润润等.1990.山西省土壤中天然放射性核素含量调查研究.辐射防护.10(6)460~465.
63.张聚敬,韦继管,徐红等.1989.新疆核试验场周围居民区食品中钚的放射性水平.环境科学研究.2(2)27~31
64.张梅英,杜平,耿明等.1993.山东省土壤中天然放射性核素含量调查研究.辐射防护.13(2):123~126.
65.张晓海,雷永和,殷端等.1997.应用~(86)Ru研究烤烟的钾素营养.烟草科技.6:31~34.
66.张钟先,田均良,郝玉怀等.1993.黄土区土壤中天然放射性背景值研究.中国环境科学.13(4)288~292.
67.张钟先,田均良,郝玉怀等.1993.黄土区土壤中天然放射性元素背景值研究.中国环境科学。13(4):288~291.
68.张钟先,涂杰峰,田均良等.1995.中国黄土地区土壤中天然放射性元素的生物地球化学.土壤学报.32(4):353~361.
69.张钟先,王农,郝玉怀等.1993.黄土区土壤放射性的生物循环.应用生态学报.4(4):381~387.
70.章文英,吴增新,郑汝宽等.1993.北京市土壤中天然放射性核素含量调查研究.辐射防护.13(5):369~371.
71.中国农业年签编辑委员会.2000.中国农业年签.北京:中国农业出版社.396.
72.中华人民共和国卫生部.1984.放射卫生防护基本标准.GB4792-84.
73.中华人民共和国卫生部.1988.磷肥放射性镭—226限量卫生标准.GB8921-88.
74.中华人民共和国卫生部.1994.食品中放射性物质限制浓度标准.GB14882-94.
75.周连江,王国兴,王昕等.1985.河北省环境土壤的γ辐射水平.上海环境科学(3):27~28.
76.朱江.1991.烟毒的幽灵—放射性元素.食品与生活(1):32~33.
77.朱永懿,陈景坚,杨俊城等.1993.施用稀土后土壤和农作物中天然放射性活度的变化.核农学通报.14(4):181~184.
78.朱永懿,陈景坚,杨俊城等.1995.农用稀土天然放射性及其对土壤和作物污染的评价.核农学报.9(3):163~167.
79.朱永懿,裘同才.1991,裂变产物~(90)Sr、~(137)Cs、~(144)Ce在土壤—植物系统中的行为.中国环境科学.11(4)266~270.
80.訾大镇,郭月清.1996.烟草栽培.北京:中国农业出版社.
81. Aarkrog A. 1994. Past and recent trends in radioecology. Environmental international. 20(5):633~643.
82. Ahman B, et al. 1999. Transfer of radiocaesium via reindeer meat to man-effects of countermeasures applied in Sweden following the Chernobyl accident. J. Environ. Radioactivity. 46(1):113~120.
83. Andersson KG, et al. 1994. The behavior of Chernogyl ~(137)Cs, ~(134)Cs and ~(106)Ru in undisturbed soil: implications for external radiation. J. Environ. Radioactivity. 22(3):183~196.
84. Andersson KG, et al.1994.Removal of radioactive fallout from surface of soil and graded surfaces using peelable coatings. J. Environ. Radioactivity. 22(3):197~203.
85. Andrew N Tyler and Kate V Heal. 2000. Predicting areas of ~(137)Cs loss and accumulation in upland catchments. Water, Air Soil Pollut. 121 (1/4): 271~288.
86. Cartenjr C T, 2000, Radiocesicum discharges and subsequent environmental transport at the major US weapons production facilities. Science of total environment 255(3/1):55~73.
87. Douka C E & Xenoulis AC. 1991. Radioactive Isotope Uptake in a Grass-Legume Association. Environ. Pollut. 73(1):11~23.
88. Entry J A, et al. 1999. Accumulation of ~(137)Cs and ~(90)Sr from contaminated soil by three grass species inoculated with mycorrhizal fungi. Environ. Pollut. 104(3):449~457.
89. Evans C V, et al. 1997. Pedologic Assessment of Radionuclide Distributiongs:Use of a Radio-Pedogenic Index. Soil Sci. Soc. Am.J.61:1440-1449.
90. Hansen R O, Stout Perry R. 1968. Isotopic distribution of uranium and thorium in soils. Soil Science, 105(1):44~50.
91. Horrill A D.1990.The influence of grassland management on the radionuclide inventory of soils in West Cumbria, UK. J. Environ. Radioactivity. 12(2):143~165.
92. Jasinska M, et al. 1998. Radionuclide content in the upper Vistula River sediments in a coal mining region in Poland(East-central Europe). Water, Air Soil Pollut. 102(3/4):355~360.
93. Jeng-Jong Wang, et al. 1998. Transfer factors of ~(90)Sr and ~(137)Cs from paddy soil to the rice plant in Taiwan. J. Environ. Radioactivity. 39(1):23~24.
94. Kudo A, 1998, Global transport rates of ~(137)Cs and ~(239+240)pu originating from the Nagasaki A-bomb in 1945 as determined from analysis of Canadian Arctic ice cores. Journal of Environmental Radioactivity. 40(3):289~298.
95. Lisalata Paul. 1994. Uranium and thorium decay series radionuclides in human and animal foodchains-a review. Journal of environment quality:23(4)633~642.
96. Manolopoulou M, et a1.1992. Behavior of natural radionuclides in lignites and fly
ashes.J.Environ.Radioactivity.16: 261~271.
97. Marti nez-Aguirre A,et al.1998. Soil to plant transfer of 226Ra in a marsh area: modeling application.J.Environ.Radioactivity.39(2) : 199-213.
98. Miyao K.1998. Temporal variation of l37Cs and 239+240pu in the Sea of Japan.Journal of Environmental Radioactivity.40(30) : 239-250.
99. Momoshima N,et al.1994. The radial distribution of 90Sr and 137Cs in trees.J.Environ.Radioactivity.22 (2) : 93-109.
100. Monte L,et al.1990. The behavior of 137Cs in some edible fruits.J.Environ. Radioactivity.1(3) : 207-214.
101. Pham Zuy Hien,et al.1994. Variations of caesium isotope concentrations in air and fallout at Dalat,south Vietnam.J.Environ.Radioactivity.22 (1) : 55-62.
102. Poiarkov V A,1995,Post-Chernobyl radiomonitoring of Ukrainian forest ecosystems.Journal of Environmental Radioactivity.23 (3) : 259-271.
103. Rosen K,et al.1995. Transfer of radiocaesium from soil to vegetation and to grazing lambs in a mountain area in northen Sweden.J.Environ.Radioactivity.26 (3) : 237-257.
104. Sam A K.1995. The natural radioactivity in phosphate deposits from Sudan. Sci.Total Environ.162(2/3) : 209-213.
105. Santos P L,et al.l995. Human occupational radioactive contamination from the use of phosphated fertilizers.Sci.Total Environ.162(1) : 19-22.
l06. Schnug E,et al.1996. Issues of natural radioactivity in phosphates.Commun.Soil. Sci.Plant.Anal.27(3&4) : 829-841.
107. Shukla V K,et al.1994. Natural and fallout radioactivity in milk and diet samples in Bombay and population dose rate estimates.J.Environ.Radioactivity.25(3) : 229-237.
108. Smith J T,et al.1999. Temporal change in fallout 137Cs in terrestrial and aquatic systems: a whole ecosystem approach.Environ.Sci.& Technol.33(1) :49~45.
109. Smolders E,et al.1997. Concentrations of l37Cs and K in soil solution predict the plant availability of 137Cs in soils.Environ.Sci.& Technol.31 (12) :3432~3438.
110. Vanden Bygaart A.J,1999,Gamma radioactivity in podzolic soils of northern Ontario,Canada.J.Environ.Radioactivity .42(1) :51~64.
111. XIONG LIMING et al.1997. Suitability of Isotope Kinetic Approach to Assess Phosphorus Status and Bioavailability of Major Acidic Soils in Subtropical China. Pedosphere.7(2) :111-118.
112. Yoshiada S,1994,Radiocesium concentrations in mushrooms collected in Japan. Journal of Environmental Radioactivity.22(2) : 141-154.
113. Yoshida S,et al.1994. Radiocesium concentrations in mushrooms collected in Japan.J.Environ.Radioactivity.22(2) : 141-154.
2.常宏等.1999.伴生放射性矿物资源开发应用中的环境问题与管理.甘肃环境研究与监测.12(3):147~149,158.
3.陈传群,徐寅良,孙志明.1990,小麦对~(134)C_s吸收的研究.环境科学.11(6):10~14.
4.陈迪云,王湘云,陈永亨.2000.铀矿区附近牛对放射性核素环境转移的指示.中国环境科学.20(4):465~468.
5.陈景坚,朱永懿,杨俊城等.1991.磷肥中的放射性核素及其在土壤和作物中的积累规律.温贤芳,姚允.同位素示综技术农业应用研究进展.北京:中国农业科技出版社.1991:7~19.
6.陈克玲,陈榜根,张孝珍等.1990.湖北省食品和水中天然放射性核素水平.中国环境科学.10(1)71~75.
7.范仲学,徐世明,赵文虎等.1998.水稻对~(157)C_s的叶面吸收.农业环境保护.17(1):8~10.
8.高薇薇,易莲芳,王玉琴等.1991.福建省土壤中天然放射性水平的调查.环境科学.11(1):75~79.
9.国家统计局.2000.中国统计年签.239.
10.郭伯生等.1988.农业中的稀土.北京:中国农业科技出版社.
11.郭立本,王心明,胡晓林等.青海省土壤中天然放射性核素含量凋查研究.辐射防护.14(3):226~229.
12.韩华峰,颛淑菊,刘洪卿等.1994.河南省土壤中天然放射性核素含量调查研究.辐射防护.14(1):60~62,66.
13.韩寿岭.1998.施用磷肥对农田放射性污染的探讨.磷肥与复肥.(5)66~67.
14.靖玉佩,王力,田毅等.1995.宁夏回族自治区土壤中天然放射性核素含量调查研究.辐射防护.15(2):125~128.
15.李长兴,李钟伟,冯志国等.1997.大庆地区土壤环境放射性水平的调查.环境科学.18(4):72~75.
16.李贵宝,单保庆,孙克刚等.2000.粉煤灰的农业利用研究进展.磷肥与复肥.15(6):59~60
17.李新德,郑永红,吴向荣等.1993.江西省土壤中天然放射性核素含量调查.辐射防护.13(4):291~294.
18.林忠辉等.2000.磷肥杂质对生态环境的影响.生态农业研究.8(2)48~50.
19.刘琼英,邝炎华.1990,环境中放射性核素经根吸收向农作物转移的研究.农业环境保护9(4):44~46.
20.刘志和,赵淑权,胡志力.1989.山东省主要农产品中放射性核素浓度及其浓集特性.中国环境监测.5(4):49~50.
21.吕志文,郝国凡,张福山等.1993.吉林省土壤中天然放射性核素含量调查研究.辐射防护.13(6):449~452.
22.马斯纳H.(德)著,曹一平,陆景陵等译.1991.高等植物的矿质营养.北京:北京农业大学出版社.
23.马玉琴等.1980.磷肥放射性水平及其对水源的影响.环境保护.(2)23~25.
24.聂辉兰,陈淑怡,朱利群等.1983.稀土定位试验中水稻、大豆对天然放射性核素的积累.农业环境保护.(3):7~9.
25.普拉萨德K.N.1984.人体放射生物学.北京:原子能出版社.
26.钱马懿,陈旭明,朱锡荣.1999.中国肿瘤.8(3):110~111.
27.全国土壤普查办公室.1998.中国土壤.北京:中国农业出版社.
28.全国土壤普查办公室.1996.中国土种志(第六卷).中国农业出版社.北京:2~62,352~360.
29.任礼华,裴永法,李金全等.1991.上海市土壤放射性水平的调查.上海环境科学.10(12):28~30.
30.盛青等.1997.核工业理化工程研究院燃煤的辐射环境影响.城市环境与城市生态.10(增刊):36~38.
31.帅震清.1987.煤电厂和核电厂对环境的影响比较.四川环境.6(1):8~10,14.
32.孙克刚,张学斌,汪立刚.2001.杂交油菜施用粉煤灰磁化肥的效应.土壤与环境.10(3)224~226.
33.孙冶,李玉先,李广通等.1993.云南省土壤中天然放射性核素含量调查研究.辐射防护.13(2):127~130.
34.孙冶.2000.磷酸盐工业中的放射性污染及其防治.云南环境科学.19(1):46~47.
35.唐文浩.1991.凉山州天然放射性水平及其分布.环境科学.12(1):82~86.
36.唐绪兴,梁维华,田金池.1993.天津市土壤中天然放射性核素含量调查研究.辐射防护.13(3):213~217.
37.王菊芬.1992.浙江省磷肥中~(226)Ra的含量及其卫生学评价.中华放射医学与防护杂志.12(4):258~260.
38.王亮,侯振海,谷雅琴等.1990.稻米食物链中放射性核素的分布和转移.环境科学.10(4):31~24.
39.王少仁,夏培桢.1991.含磷化肥的α和β比放活性及其对农业土壤的影响.农业环境保护.10(6):241~243,259.
40.王文富主编.1996.云南土壤.昆明:云南科技出版社.
41.温贤芳.1999.中国核农学.河南:河南科学技术出版社.
42.吴成祥,董善武,赵德峰.1993.黑龙江省土壤中天然放射性核素含量调查.辐射防护.13(4):295~298.
43.吴家华,刘宝山,董云中等.1995.粉煤灰改土效应研究.土壤学报.32(3)334~340.
44.吴锦海,李金全,周天豹.1989.我国原煤及煤渣、粉煤灰的放射性水平调查.上海环境科学.8(1)28,17.
45.吴宇,何清平.1990.四川省土壤中放射性核素含量及总β调查研究.重庆环境科学.12(1):42~45.
46.吴宇等.1993.四川省土壤中天然放射性核素含量调查研究.辐射防护.13(5):376~379.
47.项亮等.1996.切尔诺贝利核事故泄露~(157)Cs在苏皖地区湖泊沉积物中的蓄积及时标意义.海洋与湖沼.27(2):132~137.
48.徐冠仁.1997.核农学导论.原子能出版社.北京:14~29,289~329.
49.徐寅良,陈凯旋,陈传群.1996.离子浓度对生物吸收~(134)Cs的影响.农业环境保护.15(2):49~52.
50.焉文祉,任礼华,吴锦海等.1981.燃煤电厂烟道放出的放射性物质初步探讨.环境科学.2(5):23~25.
51.杨刚,廖赤武.1983.天然放射性核素在使用含铀磷肥作物中的蓄积规律.环境科学.4(6):10~17.
52.杨鹤鸣,眭光凯.1994.上海市土壤中天然放射性核素含量调查研究.辐射防护.14(2):123~126.
53.杨名生等.1993.广西壮族自治区土壤中天然放射性核素含量调查研究.辐射防护.13(4):299~302.
54.杨宇虹,崔国明,黄必志.1999.钙对烤烟产质量及其主要植物学性状的影响.云南农业大学学报.14(2):148~152.
55.杨子文,张永红,郭桂枝等.1990.兰州地区块根、块茎类作物中天然放射性含量及其所致内照射剂量估量.农业环境保护.9(2):34~37.
56.叶崇开,黎旺生,钱位成等.1982.煤对环境的放射性污染.环境科学.3(1):49~53.
57.俞誉福.1993.环境放射性概论.上海:复旦大学出版社.
58.曾德崇,白见林,谢明义等.1988.四川省主要食品和饮水放射性水平及所致居民照射剂量的评价.重庆环境科学.10(2):38~43.
59.曾而康.1986.农用化肥的放射性.农业环境保护.(1):27~29.
60.曾庆卓,陈联光,郑伟.1993.广东省土壤中天然放射性核素含量调查研究.辐射防护.13(5):372~375.
61.张大道.1985.化肥污染的趋势与对策.环境科学.6(6):54~59.
62.张金明,陈宝田,张润润等.1990.山西省土壤中天然放射性核素含量调查研究.辐射防护.10(6)460~465.
63.张聚敬,韦继管,徐红等.1989.新疆核试验场周围居民区食品中钚的放射性水平.环境科学研究.2(2)27~31
64.张梅英,杜平,耿明等.1993.山东省土壤中天然放射性核素含量调查研究.辐射防护.13(2):123~126.
65.张晓海,雷永和,殷端等.1997.应用~(86)Ru研究烤烟的钾素营养.烟草科技.6:31~34.
66.张钟先,田均良,郝玉怀等.1993.黄土区土壤中天然放射性背景值研究.中国环境科学.13(4)288~292.
67.张钟先,田均良,郝玉怀等.1993.黄土区土壤中天然放射性元素背景值研究.中国环境科学。13(4):288~291.
68.张钟先,涂杰峰,田均良等.1995.中国黄土地区土壤中天然放射性元素的生物地球化学.土壤学报.32(4):353~361.
69.张钟先,王农,郝玉怀等.1993.黄土区土壤放射性的生物循环.应用生态学报.4(4):381~387.
70.章文英,吴增新,郑汝宽等.1993.北京市土壤中天然放射性核素含量调查研究.辐射防护.13(5):369~371.
71.中国农业年签编辑委员会.2000.中国农业年签.北京:中国农业出版社.396.
72.中华人民共和国卫生部.1984.放射卫生防护基本标准.GB4792-84.
73.中华人民共和国卫生部.1988.磷肥放射性镭—226限量卫生标准.GB8921-88.
74.中华人民共和国卫生部.1994.食品中放射性物质限制浓度标准.GB14882-94.
75.周连江,王国兴,王昕等.1985.河北省环境土壤的γ辐射水平.上海环境科学(3):27~28.
76.朱江.1991.烟毒的幽灵—放射性元素.食品与生活(1):32~33.
77.朱永懿,陈景坚,杨俊城等.1993.施用稀土后土壤和农作物中天然放射性活度的变化.核农学通报.14(4):181~184.
78.朱永懿,陈景坚,杨俊城等.1995.农用稀土天然放射性及其对土壤和作物污染的评价.核农学报.9(3):163~167.
79.朱永懿,裘同才.1991,裂变产物~(90)Sr、~(137)Cs、~(144)Ce在土壤—植物系统中的行为.中国环境科学.11(4)266~270.
80.訾大镇,郭月清.1996.烟草栽培.北京:中国农业出版社.
81. Aarkrog A. 1994. Past and recent trends in radioecology. Environmental international. 20(5):633~643.
82. Ahman B, et al. 1999. Transfer of radiocaesium via reindeer meat to man-effects of countermeasures applied in Sweden following the Chernobyl accident. J. Environ. Radioactivity. 46(1):113~120.
83. Andersson KG, et al. 1994. The behavior of Chernogyl ~(137)Cs, ~(134)Cs and ~(106)Ru in undisturbed soil: implications for external radiation. J. Environ. Radioactivity. 22(3):183~196.
84. Andersson KG, et al.1994.Removal of radioactive fallout from surface of soil and graded surfaces using peelable coatings. J. Environ. Radioactivity. 22(3):197~203.
85. Andrew N Tyler and Kate V Heal. 2000. Predicting areas of ~(137)Cs loss and accumulation in upland catchments. Water, Air Soil Pollut. 121 (1/4): 271~288.
86. Cartenjr C T, 2000, Radiocesicum discharges and subsequent environmental transport at the major US weapons production facilities. Science of total environment 255(3/1):55~73.
87. Douka C E & Xenoulis AC. 1991. Radioactive Isotope Uptake in a Grass-Legume Association. Environ. Pollut. 73(1):11~23.
88. Entry J A, et al. 1999. Accumulation of ~(137)Cs and ~(90)Sr from contaminated soil by three grass species inoculated with mycorrhizal fungi. Environ. Pollut. 104(3):449~457.
89. Evans C V, et al. 1997. Pedologic Assessment of Radionuclide Distributiongs:Use of a Radio-Pedogenic Index. Soil Sci. Soc. Am.J.61:1440-1449.
90. Hansen R O, Stout Perry R. 1968. Isotopic distribution of uranium and thorium in soils. Soil Science, 105(1):44~50.
91. Horrill A D.1990.The influence of grassland management on the radionuclide inventory of soils in West Cumbria, UK. J. Environ. Radioactivity. 12(2):143~165.
92. Jasinska M, et al. 1998. Radionuclide content in the upper Vistula River sediments in a coal mining region in Poland(East-central Europe). Water, Air Soil Pollut. 102(3/4):355~360.
93. Jeng-Jong Wang, et al. 1998. Transfer factors of ~(90)Sr and ~(137)Cs from paddy soil to the rice plant in Taiwan. J. Environ. Radioactivity. 39(1):23~24.
94. Kudo A, 1998, Global transport rates of ~(137)Cs and ~(239+240)pu originating from the Nagasaki A-bomb in 1945 as determined from analysis of Canadian Arctic ice cores. Journal of Environmental Radioactivity. 40(3):289~298.
95. Lisalata Paul. 1994. Uranium and thorium decay series radionuclides in human and animal foodchains-a review. Journal of environment quality:23(4)633~642.
96. Manolopoulou M, et a1.1992. Behavior of natural radionuclides in lignites and fly
ashes.J.Environ.Radioactivity.16: 261~271.
97. Marti nez-Aguirre A,et al.1998. Soil to plant transfer of 226Ra in a marsh area: modeling application.J.Environ.Radioactivity.39(2) : 199-213.
98. Miyao K.1998. Temporal variation of l37Cs and 239+240pu in the Sea of Japan.Journal of Environmental Radioactivity.40(30) : 239-250.
99. Momoshima N,et al.1994. The radial distribution of 90Sr and 137Cs in trees.J.Environ.Radioactivity.22 (2) : 93-109.
100. Monte L,et al.1990. The behavior of 137Cs in some edible fruits.J.Environ. Radioactivity.1(3) : 207-214.
101. Pham Zuy Hien,et al.1994. Variations of caesium isotope concentrations in air and fallout at Dalat,south Vietnam.J.Environ.Radioactivity.22 (1) : 55-62.
102. Poiarkov V A,1995,Post-Chernobyl radiomonitoring of Ukrainian forest ecosystems.Journal of Environmental Radioactivity.23 (3) : 259-271.
103. Rosen K,et al.1995. Transfer of radiocaesium from soil to vegetation and to grazing lambs in a mountain area in northen Sweden.J.Environ.Radioactivity.26 (3) : 237-257.
104. Sam A K.1995. The natural radioactivity in phosphate deposits from Sudan. Sci.Total Environ.162(2/3) : 209-213.
105. Santos P L,et al.l995. Human occupational radioactive contamination from the use of phosphated fertilizers.Sci.Total Environ.162(1) : 19-22.
l06. Schnug E,et al.1996. Issues of natural radioactivity in phosphates.Commun.Soil. Sci.Plant.Anal.27(3&4) : 829-841.
107. Shukla V K,et al.1994. Natural and fallout radioactivity in milk and diet samples in Bombay and population dose rate estimates.J.Environ.Radioactivity.25(3) : 229-237.
108. Smith J T,et al.1999. Temporal change in fallout 137Cs in terrestrial and aquatic systems: a whole ecosystem approach.Environ.Sci.& Technol.33(1) :49~45.
109. Smolders E,et al.1997. Concentrations of l37Cs and K in soil solution predict the plant availability of 137Cs in soils.Environ.Sci.& Technol.31 (12) :3432~3438.
110. Vanden Bygaart A.J,1999,Gamma radioactivity in podzolic soils of northern Ontario,Canada.J.Environ.Radioactivity .42(1) :51~64.
111. XIONG LIMING et al.1997. Suitability of Isotope Kinetic Approach to Assess Phosphorus Status and Bioavailability of Major Acidic Soils in Subtropical China. Pedosphere.7(2) :111-118.
112. Yoshiada S,1994,Radiocesium concentrations in mushrooms collected in Japan. Journal of Environmental Radioactivity.22(2) : 141-154.
113. Yoshida S,et al.1994. Radiocesium concentrations in mushrooms collected in Japan.J.Environ.Radioactivity.22(2) : 141-154.