草业学报
草業學報
초업학보
PRATACULTURAL SCIENCE
2015年
5期
75-83
,共9页
张明锦%陈良华%胡相伟%徐睿%张健
張明錦%陳良華%鬍相偉%徐睿%張健
장명금%진량화%호상위%서예%장건
巨能草%水肥耦合%生长%光合色素
巨能草%水肥耦閤%生長%光閤色素
거능초%수비우합%생장%광합색소
Puelia sinese%water and fertilizer coupling%growth%photosynthetic pigments
采用盆栽控制实验的方式,利用控水、控肥的实验方法,设计了干旱(25% FC)、对照(75% FC)和水淹(100%FC)3个水分梯度以及低、中、高3个养分水平的完全随机组合实验,研究了不同水肥耦合条件对巨能草生长与光合色素的影响。结果表明,巨能草的地上生物量、地下生物量、生物总量和根冠比都受到了水肥交互作用的显著影响。在正常水分条件下,高肥处理下的分蘖数、株高、地下生物量、地上生物量和生物总量都是最大的,是9种水肥配比中巨能草生物量积累最佳的水肥配比。可见,良好的水肥条件是巨能草获得高产的前提。水淹和干旱都不利于植株的分蘖和高生长,但干旱条件下可通过施肥提高植株的分蘖能力。水淹环境下,不宜施用过多肥料,中等施肥量最有利于巨能草地下生物量的积累,其根冠比显著增大,有利于植物根系适应水淹条件下的缺氧环境。与水淹条件相比,干旱条件更不利于巨能草地上生物量的积累,为了适应干旱环境,巨能草会把更多的同化物质分配给地下部分,进而增大根冠比,从而表现出较高的生理可塑性以适应极端的干旱环境。有趣的是,水分胁迫下的光合色素含量显著高于正常水分,且随着施肥量的增加,光合色素的含量都有所增加,干旱处理下的增加尤为显著。由此可见,在水分胁迫环境下,巨能草会通过其各种形态和生理适应机制来适应环境,表现出一定的耐涝性和抗旱性,且施肥能够在一定程度上降低水分胁迫对植物生长的影响。
採用盆栽控製實驗的方式,利用控水、控肥的實驗方法,設計瞭榦旱(25% FC)、對照(75% FC)和水淹(100%FC)3箇水分梯度以及低、中、高3箇養分水平的完全隨機組閤實驗,研究瞭不同水肥耦閤條件對巨能草生長與光閤色素的影響。結果錶明,巨能草的地上生物量、地下生物量、生物總量和根冠比都受到瞭水肥交互作用的顯著影響。在正常水分條件下,高肥處理下的分蘗數、株高、地下生物量、地上生物量和生物總量都是最大的,是9種水肥配比中巨能草生物量積纍最佳的水肥配比。可見,良好的水肥條件是巨能草穫得高產的前提。水淹和榦旱都不利于植株的分蘗和高生長,但榦旱條件下可通過施肥提高植株的分蘗能力。水淹環境下,不宜施用過多肥料,中等施肥量最有利于巨能草地下生物量的積纍,其根冠比顯著增大,有利于植物根繫適應水淹條件下的缺氧環境。與水淹條件相比,榦旱條件更不利于巨能草地上生物量的積纍,為瞭適應榦旱環境,巨能草會把更多的同化物質分配給地下部分,進而增大根冠比,從而錶現齣較高的生理可塑性以適應極耑的榦旱環境。有趣的是,水分脅迫下的光閤色素含量顯著高于正常水分,且隨著施肥量的增加,光閤色素的含量都有所增加,榦旱處理下的增加尤為顯著。由此可見,在水分脅迫環境下,巨能草會通過其各種形態和生理適應機製來適應環境,錶現齣一定的耐澇性和抗旱性,且施肥能夠在一定程度上降低水分脅迫對植物生長的影響。
채용분재공제실험적방식,이용공수、공비적실험방법,설계료간한(25% FC)、대조(75% FC)화수엄(100%FC)3개수분제도이급저、중、고3개양분수평적완전수궤조합실험,연구료불동수비우합조건대거능초생장여광합색소적영향。결과표명,거능초적지상생물량、지하생물량、생물총량화근관비도수도료수비교호작용적현저영향。재정상수분조건하,고비처리하적분얼수、주고、지하생물량、지상생물량화생물총량도시최대적,시9충수비배비중거능초생물량적루최가적수비배비。가견,량호적수비조건시거능초획득고산적전제。수엄화간한도불리우식주적분얼화고생장,단간한조건하가통과시비제고식주적분얼능력。수엄배경하,불의시용과다비료,중등시비량최유리우거능초지하생물량적적루,기근관비현저증대,유리우식물근계괄응수엄조건하적결양배경。여수엄조건상비,간한조건경불리우거능초지상생물량적적루,위료괄응간한배경,거능초회파경다적동화물질분배급지하부분,진이증대근관비,종이표현출교고적생리가소성이괄응겁단적간한배경。유취적시,수분협박하적광합색소함량현저고우정상수분,차수착시비량적증가,광합색소적함량도유소증가,간한처리하적증가우위현저。유차가견,재수분협박배경하,거능초회통과기각충형태화생리괄응궤제래괄응배경,표현출일정적내로성화항한성,차시비능구재일정정도상강저수분협박대식물생장적영향。
A pot experiment was conducted to detect the interaction effect of water and fertilizer on growth and photosynthetic pigments of Puelia sinense .The experiment was a completely randomized design with 9 factori-al combinations of 3 levels of water [drought,25% field capacity (FC);control,75% FC;flooding,100%FC)]and fertilizer (low,moderate,high levels of fertilizer).Above-ground biomass,below-ground biomass, total biomass,and root:shoot ratio were significantly affected by the interaction of water and fertilizer.For the control water treatment,a high level of fertilization led to increased tiller number and plant height,and greater below-ground,above-ground,and total plant biomass.This combination was the best among the 9 combinations.These results indicate that normal supply of water and high nutrient supply are the optimal con-ditions to achieve a high yield for this species.Both flooding and drought were detrimental to tillering and growth.However,under water deficit where a tillering reduction was observed,tillering capacity could be im-proved through fertilization.Under flooding,high fertilization was not beneficial and a moderate amount of fer-tilizer was sufficient for optimal accumulation of below-ground biomass.Plants in these conditions had a higher root to shoot ratio,possibly a plant response to hypoxic conditions.Compared to flooding,drought was more detrimental to the accumulation of above-ground biomass.In order to adapt to drought,P .sinense allocated more assimilate to the belowground organs.The increased root:shoot ratio was presumably advantageous for plant water capture and so to adaptation to drought.Interestingly,under water deficit stress,concentrations of photosynthetic pigments were significantly higher than those under control conditions.With increase in fertili-zation,contents of photosynthetic pigments also increased,especially when exposed to drought at the same time.These results elucidated some morphological and physiological adaptive mechanisms of this species when responding to water-deficit.Increased fertilization could mitigate the detrimental effects of water deficit stress on plant growth to some degree.