生态环境
生態環境
생태배경
ECOLOGY AND ENVIRONMENT
2008年
6期
2426-2432
,共7页
乌尼木仁%樗木直也%陈能场%稻永醇二
烏尼木仁%樗木直也%陳能場%稻永醇二
오니목인%저목직야%진능장%도영순이
15N%有机化%无机化%氮的行为%根箱%根际%甜椒
15N%有機化%無機化%氮的行為%根箱%根際%甜椒
15N%유궤화%무궤화%담적행위%근상%근제%첨초
15N%immobilization%mineralization%N behavior%rhizobox%rhizosphere%sweet pepper
为研究甜椒根际土壤中氮的行为,与既报同样的方法进行研究,即,利用15NH4+,15NO3-双标记的硝胺(NH,4>15NO3,15NH4NO3),在温室里对甜椒进行6周的根箱栽培.收割后,对土壤全氮,NO3-N,水溶性NH4-N,KCl抽出NH4-N和其各自的15N atom%进行测定.结果表明,土壤全氮从非根际到根际逐渐增加,与栽培前相比,土壤全氮在非根际中减少,却在根际中增大.土壤NO3-N浓度朝根际增加到离根际2 mm处,然后激减到根际.NO3-N的来自施给NO3-N的比例靠近根际逐渐升高,在根际达到了69%,反而,来自施给NH4-N的比例靠近根际逐渐降低,在根际将至7%左右.水溶性NH4-N和KCl抽出NH4-N浓度靠近根际逐渐降低,而且,从非根际到根际,二者匀保持3∶10的比例.KCl抽出NH4-N的来自施给NO3-N的比例靠近根际逐渐升高,但在根际仍低于3%,反而,其来自施给NH4-N的比例在非根际约为47%~55%,在根际降到41%.在整个根箱里,施用NO3-N的有機率达到62%,但其值在根际比非根圈要低.相反,施用NH4-N的有機率仅11%左右,但其值在根际比非根际要高.以上结果表明,在甜椒根际土壤中氮的无机化-有机化活性与水稻相比显著低.
為研究甜椒根際土壤中氮的行為,與既報同樣的方法進行研究,即,利用15NH4+,15NO3-雙標記的硝胺(NH,4>15NO3,15NH4NO3),在溫室裏對甜椒進行6週的根箱栽培.收割後,對土壤全氮,NO3-N,水溶性NH4-N,KCl抽齣NH4-N和其各自的15N atom%進行測定.結果錶明,土壤全氮從非根際到根際逐漸增加,與栽培前相比,土壤全氮在非根際中減少,卻在根際中增大.土壤NO3-N濃度朝根際增加到離根際2 mm處,然後激減到根際.NO3-N的來自施給NO3-N的比例靠近根際逐漸升高,在根際達到瞭69%,反而,來自施給NH4-N的比例靠近根際逐漸降低,在根際將至7%左右.水溶性NH4-N和KCl抽齣NH4-N濃度靠近根際逐漸降低,而且,從非根際到根際,二者勻保持3∶10的比例.KCl抽齣NH4-N的來自施給NO3-N的比例靠近根際逐漸升高,但在根際仍低于3%,反而,其來自施給NH4-N的比例在非根際約為47%~55%,在根際降到41%.在整箇根箱裏,施用NO3-N的有機率達到62%,但其值在根際比非根圈要低.相反,施用NH4-N的有機率僅11%左右,但其值在根際比非根際要高.以上結果錶明,在甜椒根際土壤中氮的無機化-有機化活性與水稻相比顯著低.
위연구첨초근제토양중담적행위,여기보동양적방법진행연구,즉,이용15NH4+,15NO3-쌍표기적초알(NH,4>15NO3,15NH4NO3),재온실리대첨초진행6주적근상재배.수할후,대토양전담,NO3-N,수용성NH4-N,KCl추출NH4-N화기각자적15N atom%진행측정.결과표명,토양전담종비근제도근제축점증가,여재배전상비,토양전담재비근제중감소,각재근제중증대.토양NO3-N농도조근제증가도리근제2 mm처,연후격감도근제.NO3-N적래자시급NO3-N적비례고근근제축점승고,재근제체도료69%,반이,래자시급NH4-N적비례고근근제축점강저,재근제장지7%좌우.수용성NH4-N화KCl추출NH4-N농도고근근제축점강저,이차,종비근제도근제,이자균보지3∶10적비례.KCl추출NH4-N적래자시급NO3-N적비례고근근제축점승고,단재근제잉저우3%,반이,기래자시급NH4-N적비례재비근제약위47%~55%,재근제강도41%.재정개근상리,시용NO3-N적유기솔체도62%,단기치재근제비비근권요저.상반,시용NH4-N적유기솔부11%좌우,단기치재근제비비근제요고.이상결과표명,재첨초근제토양중담적무궤화-유궤화활성여수도상비현저저.
The behavior of N in the rhizosphere of sweet pepper (Capsicum annuum L.) plant was investigated using a rhizobox sys-tem filled with a shirasu soil applied with NH415NO3 or 15NH4NO3. The rhizobox consisted of one 2 mm width center compart-ment(CC), five 1-mm width compartments (C1~C5), and one bulk compartment (BC) on both sides of CC. Sweet pepper was sowed and grown in CC. After six weeks of cultivation, the soil from each compartment were collected and analyzed for contents of the soil T-N, NO3-N, water-soluble NH4-N and KCl-extractable NH4-N and their 15N excess%. The obtained results were summa-rized as follows: 1. Although the T-N content of soil decreased in from BC to Cl compared to before cultivation, it gradually increased from BC toward the CC and it was higher before cultivation in the CC. 2. The NO3-N contents of soil increased from BC to C2, then rapidly decreased from C2 to CC. The ratio of NO3-N which de-rived from fertilizer NO3-N increased from BC toward the CC and it reached 69% in the CC. On the contrary, the ratio of NO3-N which derived from fertilizer NH4-N decreased from the BC toward the CC and it was 7% in the CC. 3. The water-soluble NH4-N and KCl-extractable NH4-N contents of soil decreased from the BC toward the CC and the ratio of water-soluble NH4-N to KCl-extractahle NH4-N are 3:10 in all compartments. The ratio of NH4-N which derived from fertilizer NO3-N increased from BC toward the CC, but it was only 3% in the CC. The ratio of NH4-N which derived from fertilizer NH4-N was 47~55% in the compartments from BC to Cl, but it was low at 41% in the CC. 4. The immobilization of fertilizer NO3-N reached 62% in the whole rhizobox, but the rate was lower in the CC than in the other compartments. On the other hand, the immobilization of fertilizer NH4-N was only about 11% in the whole rhizobox, while the rate was higher in the CC than in other compartments.
