农业工程学报
農業工程學報
농업공정학보
2014年
13期
119-126
,共8页
李彩霞%周新国%孙景生%李新强
李綵霞%週新國%孫景生%李新彊
리채하%주신국%손경생%리신강
灌溉%农作物%水分%沟灌%玉米%气孔阻力%土壤水分
灌溉%農作物%水分%溝灌%玉米%氣孔阻力%土壤水分
관개%농작물%수분%구관%옥미%기공조력%토양수분
irrigation%crops%moisture%furrow irrigation%maize%stomatal resistance%soil moisture
气孔调节在作物适应不同水分环境中起着重要作用,为了阐明作物在不同沟灌措施下的气孔活动规律,在大田分区试验中研究了交替非充分供水与常规沟灌下玉米叶片气孔阻力差异及气孔对水汽传导的贡献。结果表明,在叶片尺度上,玉米叶片气孔阻力自叶基至叶尖处梯度递减;在群体上,叶片气孔阻力自冠层上层向下层呈垂直递增趋势;群体上层叶片气孔阻力相对较小。玉米叶片正面气孔对CO2和水汽的传导贡献大于反面;除玉米苗期外,气孔对CO2和水汽传导贡献的80%以上来自于冠层上、中部叶片。在玉米营养生长阶段,不同叶序的叶片气孔阻力随叶龄的增大而增大,交替非充分供水加大了不同叶龄叶片之间的气孔阻力差异。在玉米生殖生长阶段,较为成熟的玉米叶片气孔阻力受叶龄的影响不明显。与常规沟灌比较,交替非充分供水增大了叶片反面气孔收缩程度,对水分亏缺反应更为敏感,冠层由顶叶至底叶的叶片气孔阻力呈垂直梯度递增,引起气孔导度快速衰减,从而提高了群体上层气孔对水汽的传导贡献。因此,玉米气孔阻力大小受到沟灌方式和土壤水分状况的调控,还与叶龄、叶面积指数等环境因素及气孔自身特性有关,其研究对控制灌溉及土壤-植物-大气连续体(Soil-plant-atmosphere continuum,SPAC)水汽循环研究具有理论意义。
氣孔調節在作物適應不同水分環境中起著重要作用,為瞭闡明作物在不同溝灌措施下的氣孔活動規律,在大田分區試驗中研究瞭交替非充分供水與常規溝灌下玉米葉片氣孔阻力差異及氣孔對水汽傳導的貢獻。結果錶明,在葉片呎度上,玉米葉片氣孔阻力自葉基至葉尖處梯度遞減;在群體上,葉片氣孔阻力自冠層上層嚮下層呈垂直遞增趨勢;群體上層葉片氣孔阻力相對較小。玉米葉片正麵氣孔對CO2和水汽的傳導貢獻大于反麵;除玉米苗期外,氣孔對CO2和水汽傳導貢獻的80%以上來自于冠層上、中部葉片。在玉米營養生長階段,不同葉序的葉片氣孔阻力隨葉齡的增大而增大,交替非充分供水加大瞭不同葉齡葉片之間的氣孔阻力差異。在玉米生殖生長階段,較為成熟的玉米葉片氣孔阻力受葉齡的影響不明顯。與常規溝灌比較,交替非充分供水增大瞭葉片反麵氣孔收縮程度,對水分虧缺反應更為敏感,冠層由頂葉至底葉的葉片氣孔阻力呈垂直梯度遞增,引起氣孔導度快速衰減,從而提高瞭群體上層氣孔對水汽的傳導貢獻。因此,玉米氣孔阻力大小受到溝灌方式和土壤水分狀況的調控,還與葉齡、葉麵積指數等環境因素及氣孔自身特性有關,其研究對控製灌溉及土壤-植物-大氣連續體(Soil-plant-atmosphere continuum,SPAC)水汽循環研究具有理論意義。
기공조절재작물괄응불동수분배경중기착중요작용,위료천명작물재불동구관조시하적기공활동규률,재대전분구시험중연구료교체비충분공수여상규구관하옥미협편기공조력차이급기공대수기전도적공헌。결과표명,재협편척도상,옥미협편기공조력자협기지협첨처제도체감;재군체상,협편기공조력자관층상층향하층정수직체증추세;군체상층협편기공조력상대교소。옥미협편정면기공대CO2화수기적전도공헌대우반면;제옥미묘기외,기공대CO2화수기전도공헌적80%이상래자우관층상、중부협편。재옥미영양생장계단,불동협서적협편기공조력수협령적증대이증대,교체비충분공수가대료불동협령협편지간적기공조력차이。재옥미생식생장계단,교위성숙적옥미협편기공조력수협령적영향불명현。여상규구관비교,교체비충분공수증대료협편반면기공수축정도,대수분우결반응경위민감,관층유정협지저협적협편기공조력정수직제도체증,인기기공도도쾌속쇠감,종이제고료군체상층기공대수기적전도공헌。인차,옥미기공조력대소수도구관방식화토양수분상황적조공,환여협령、협면적지수등배경인소급기공자신특성유관,기연구대공제관개급토양-식물-대기련속체(Soil-plant-atmosphere continuum,SPAC)수기순배연구구유이론의의。
Stomatal regulation plays a pivotal role in the adaption of plants to different water conditions. In order to understand characteristics of stomatal resistance of crops with different irrigation methods, differences in leaf stomatal resistance and contribution of stomatal aperture to water vapor transfer were investigated with a field experiment conducted under alternative deficit water supply and under conventional furrow irrigation. Results indicated that for individual maize leaf, regardless of irrigation methods, the stomatal resistance decreased gradually from the base to the tip of the maize leaf. At the population level, the stomatal resistance of maize leaf increased gradually from canopy top to bottom. For the change of the leaf stomatal resistance in time, diurnal variation of leaf stomatal resistance was in a Wshape. Diurnal and daily changes in the leaf stomatal resistance in the upper canopy were relatively small. The upper surface of maize leaf contributed more to CO2 and water vapor transfer than the ones underside. Except at the seedling stage, the leaves in the upper and middle part of maize canopy contributed more than 80% of the total CO2 and water vapor. Stomatal resistances of maize leaves decreased with the increase in leaf age during the vegetative growth stage. Differences in stomatal resistance among maize leaves of different ages were increased by the alternative deficit water supply. During the reproductive growth phase, leaf age had no significant influence on the stomatal resistance in matured leaves. Compared with the conventional furrow irrigation with sufficient water supply, the alternative deficit water supply increased the ratio of the stomatal resistances between the upper side and underside of maize leaves. The vertical gradient of stomatal resistance from canopy top to bottom increased significantly (P<0.05), decreasing leaf stomatal conductivity rapidly, and improving the contribution of the stomatal aperture in the upper canopy to water vapor transfer. Therefore, the leaf stomatal resistance of maize was regulated by furrow irrigation methods and soil water condition, and it was affected by the leaf age, leaf area index and natural feature of stomatal aperture. The study is useful for controllable irrigation technology and water vapor cycle in soil plant atmosphere continuum (SPAC).