农业工程学报
農業工程學報
농업공정학보
2014年
24期
105-113
,共9页
张芮%成自勇%王旺田%吴玉霞%牛黎莉%张晓霞%高阳%陈娜娜%马奇梅
張芮%成自勇%王旺田%吳玉霞%牛黎莉%張曉霞%高暘%陳娜娜%馬奇梅
장예%성자용%왕왕전%오옥하%우려리%장효하%고양%진나나%마기매
水分%水果%生长%延后栽培葡萄%粒径膨大%产量%水分生产效率%品质
水分%水果%生長%延後栽培葡萄%粒徑膨大%產量%水分生產效率%品質
수분%수과%생장%연후재배포도%립경팽대%산량%수분생산효솔%품질
moisture%fruits%growth%grapes of delayed cultivation%fruit enlargement%yields%WUE%quality
为寻求最佳的葡萄果实产量及品质的水分调控阈值,将延后栽培葡萄划分为萌芽、抽蔓、开花、果实膨大、着色成熟5个生育阶段,各生育期设3个供水水平(即土壤相对含水率为75%~100%、65%~90%、55%~80%),开展了上述3种供水水平下葡萄果实生长、产量、品质及水分生产效率的研究。结果表明,延后栽培葡萄有2个明显的高、低峰膨大周期,第1个高峰期出现在膨大期前16 d,平均横向和纵向膨大速率分别达到0.747和0.959 mm/d;葡萄横径2次膨大高峰出现在膨大期第44~52 d,纵径比横径推迟1 w,平均膨大速率只有0.134 mm/d,比横向小0.063 mm/d。抽蔓期中度水分胁迫处理和开花期中度胁迫处理的膨大速率在果实膨大初期表现出了明显的复水补偿效应,中后期则出现了复水补偿结束后的再减小过程。萌芽期中度胁迫处理对提高葡萄产量、水分生产效率和灌溉水利用效率有利,其值分别达到36333、7.69、10.27 kg/m3,着色成熟期轻度胁迫处理次之。着色成熟期轻度胁迫下,可溶性固形物、维生素C、葡萄糖、总糖等营养成分均显著高于生育期充分供水处理(P<0.05)。综合考虑产量、水分生产效率、灌溉水利用效率及果实品质等指标,最佳延后栽培葡萄水分调控处理为着色成熟期轻度胁迫,即着色成熟期土壤相对含水率为65%~90%、其余生育期土壤相对含水率为75%~100%。该研究可为设施延后栽培葡萄土壤水分精准管理提供依据。
為尋求最佳的葡萄果實產量及品質的水分調控閾值,將延後栽培葡萄劃分為萌芽、抽蔓、開花、果實膨大、著色成熟5箇生育階段,各生育期設3箇供水水平(即土壤相對含水率為75%~100%、65%~90%、55%~80%),開展瞭上述3種供水水平下葡萄果實生長、產量、品質及水分生產效率的研究。結果錶明,延後栽培葡萄有2箇明顯的高、低峰膨大週期,第1箇高峰期齣現在膨大期前16 d,平均橫嚮和縱嚮膨大速率分彆達到0.747和0.959 mm/d;葡萄橫徑2次膨大高峰齣現在膨大期第44~52 d,縱徑比橫徑推遲1 w,平均膨大速率隻有0.134 mm/d,比橫嚮小0.063 mm/d。抽蔓期中度水分脅迫處理和開花期中度脅迫處理的膨大速率在果實膨大初期錶現齣瞭明顯的複水補償效應,中後期則齣現瞭複水補償結束後的再減小過程。萌芽期中度脅迫處理對提高葡萄產量、水分生產效率和灌溉水利用效率有利,其值分彆達到36333、7.69、10.27 kg/m3,著色成熟期輕度脅迫處理次之。著色成熟期輕度脅迫下,可溶性固形物、維生素C、葡萄糖、總糖等營養成分均顯著高于生育期充分供水處理(P<0.05)。綜閤攷慮產量、水分生產效率、灌溉水利用效率及果實品質等指標,最佳延後栽培葡萄水分調控處理為著色成熟期輕度脅迫,即著色成熟期土壤相對含水率為65%~90%、其餘生育期土壤相對含水率為75%~100%。該研究可為設施延後栽培葡萄土壤水分精準管理提供依據。
위심구최가적포도과실산량급품질적수분조공역치,장연후재배포도화분위맹아、추만、개화、과실팽대、착색성숙5개생육계단,각생육기설3개공수수평(즉토양상대함수솔위75%~100%、65%~90%、55%~80%),개전료상술3충공수수평하포도과실생장、산량、품질급수분생산효솔적연구。결과표명,연후재배포도유2개명현적고、저봉팽대주기,제1개고봉기출현재팽대기전16 d,평균횡향화종향팽대속솔분별체도0.747화0.959 mm/d;포도횡경2차팽대고봉출현재팽대기제44~52 d,종경비횡경추지1 w,평균팽대속솔지유0.134 mm/d,비횡향소0.063 mm/d。추만기중도수분협박처리화개화기중도협박처리적팽대속솔재과실팽대초기표현출료명현적복수보상효응,중후기칙출현료복수보상결속후적재감소과정。맹아기중도협박처리대제고포도산량、수분생산효솔화관개수이용효솔유리,기치분별체도36333、7.69、10.27 kg/m3,착색성숙기경도협박처리차지。착색성숙기경도협박하,가용성고형물、유생소C、포도당、총당등영양성분균현저고우생육기충분공수처리(P<0.05)。종합고필산량、수분생산효솔、관개수이용효솔급과실품질등지표,최가연후재배포도수분조공처리위착색성숙기경도협박,즉착색성숙기토양상대함수솔위65%~90%、기여생육기토양상대함수솔위75%~100%。해연구가위설시연후재배포도토양수분정준관리제공의거。
Soil water content is the main factor affecting plant growth and dry matter accumulation. The study of grape fruit enlargement, fruit quality and yield under delayed cultivation facility in cold area is of important significance for fresh grape’s balanced supply. A field experiment was conducted during the grape growing season in Zhang Ye, China in 2013 to investigate the influence of water stress in different growth stages on grape growth and yield under delayed cultivation facility. The growing season of delayed planting grapes was divided into five growth stages including germination, vining, flowering, fruit enlargement and colored mature. Three soil water treatment levels were designed in each growth stage by either drying or adding water to reach the designed soil water content (75%-100% field capacity, 65%-90% field capacity, and 55%-80% field capacity). Grape yield, quality and water efficiency were studied under above water regimes. The results showed that there were two distinct high and low peaks in delayed planting grapes enlargement cycle. The first enlargement peak appeared in the former 16 days of enlargement period, and the average horizontal and vertical enlargement rate reached 0.747 and 0.959 mm/d. The grapes’ second transverses enlargement peak appeared in the first 44-52 days, the vertical diameter was postponed one week, and the average rate of inflation was only 0.134 mm/d, which was smaller than the transverse by 0.063 mm/d. There was significantly positive correlation between grape fruit’s transverse diameter enlargement rate and longitudinal diameter enlargement rate at the same time except in fruit expanding period of 52-59 days, and the grape fruit transverse and longitudinal enlargement were strongly synchronous. In the early fruit enlargement stage, fruit enlargement rate showed evident re-watering compensation effects under the VS (moderate water stress in grape’s vining stage) and FS (moderate water stress in flowering stage) treatments, and later the rate was slow again. Before July 30th (within 30 days of fruit enlargement stage) the processing of fruit growth rate of FS treatment has been at a high level, and the fruit cumulative transverse diameter and longitudinal diameter enlargement were up to 16.82 mm and 20.16 mm in this period, respectively, which reached 71.1% and 78.23% of the final grape fruit sizes. That meant fruit enlargement rate of early enlarging period determined the final grape fruit size, which must be paid attention to in the process of grape plant. Grape yield, water use efficiency (WUE), irrigation water use efficiency (IWUE) of GS (moderate water stress in germination stage) were higher than other treatments, and its value reached 36 333 kg/hm2, 7.69 kg/m3, 10.27 kg/m3, respectively;and CM treatment (mild stress in coloring maturity stage) ranked second. So from the yield, WUE and IWUE point of view, the best water treatment was carrying out moderate water stress in germination period (the minimum soil water content was 55%field capacity, upper limit was 80%field capacity), and the rest of the growth period carried out sufficient water supply (the minimum soil water content was 75%, upper limit was field capacity). Grapes soluble solids, VC, fructose, glucose, total sugar of CM treatment were 19.0%, 1.66 mg/50 mL, 9.64%, 13.46%, 24.76%, respectively, which were significantly higher than CK (P<0.05). Therefore, with a comprehensive consideration of yield, WUE, IWUE and fruit quality indicators, the optimal water regulation treatment under delayed cultivation was CM, namely mild water stress (soil water content was 65% field capacity-90% field capacity) in ripe period, and sufficient water supply (soil water content was 75%field capacity-100% field capacity) in other periods. The research can provide valuble information for precise management of soil moisture in grape’s growth period, and to achieve the purposes of water saving and grape quality and production improvement.