农业工程学报
農業工程學報
농업공정학보
2013年
4期
174-182
,共9页
赖勇林%杨旭健%吴道铭%沈宏%贾志红%易建华%蒲文宣%孙在军%汪耀富
賴勇林%楊旭健%吳道銘%瀋宏%賈誌紅%易建華%蒲文宣%孫在軍%汪耀富
뢰용림%양욱건%오도명%침굉%가지홍%역건화%포문선%손재군%왕요부
土壤%生长%可观察性%根箱装置%非扰动观测%烟草%根系
土壤%生長%可觀察性%根箱裝置%非擾動觀測%煙草%根繫
토양%생장%가관찰성%근상장치%비우동관측%연초%근계
soils%growth%observability%rhizobox%non-invasive observation%tobacco%root system
原位观察土壤中根系的生长情况是一个难题.该文提出了一种土壤栽培条件下根系生长非扰动观测根箱,并以栽种烟草为例说明其应用.该装置由生长室、水肥供应系统、图像捕获与分析系统构成.烟草根系在生长室中生长,水肥供应系统独立调节各分室的水肥供应.利用数码相机定期捕获观察面的根系图像,再用 Image J 软件分析数据,即可实现根系的定量观测.结果表明,烟草根系伸长速率在移栽后第35天和第46天出现2个增长高峰,其峰值分别为54.58和185.69 cm/d.根系深度与宽度的比值随生长时间呈现“V”形曲线.根系的快速生长区域具有下移的趋势.比较生长室观察面所得数据和挖掘根箱获得的数据,结果表明,>20~40 cm 土层根系最多,2种方法所得到的根长在各土层的分布趋势基本一致、相关性显著,表明本装置可应用于土壤栽培条件下根系生长的非扰动观测.
原位觀察土壤中根繫的生長情況是一箇難題.該文提齣瞭一種土壤栽培條件下根繫生長非擾動觀測根箱,併以栽種煙草為例說明其應用.該裝置由生長室、水肥供應繫統、圖像捕穫與分析繫統構成.煙草根繫在生長室中生長,水肥供應繫統獨立調節各分室的水肥供應.利用數碼相機定期捕穫觀察麵的根繫圖像,再用 Image J 軟件分析數據,即可實現根繫的定量觀測.結果錶明,煙草根繫伸長速率在移栽後第35天和第46天齣現2箇增長高峰,其峰值分彆為54.58和185.69 cm/d.根繫深度與寬度的比值隨生長時間呈現“V”形麯線.根繫的快速生長區域具有下移的趨勢.比較生長室觀察麵所得數據和挖掘根箱穫得的數據,結果錶明,>20~40 cm 土層根繫最多,2種方法所得到的根長在各土層的分佈趨勢基本一緻、相關性顯著,錶明本裝置可應用于土壤栽培條件下根繫生長的非擾動觀測.
원위관찰토양중근계적생장정황시일개난제.해문제출료일충토양재배조건하근계생장비우동관측근상,병이재충연초위례설명기응용.해장치유생장실、수비공응계통、도상포획여분석계통구성.연초근계재생장실중생장,수비공응계통독립조절각분실적수비공응.이용수마상궤정기포획관찰면적근계도상,재용 Image J 연건분석수거,즉가실현근계적정량관측.결과표명,연초근계신장속솔재이재후제35천화제46천출현2개증장고봉,기봉치분별위54.58화185.69 cm/d.근계심도여관도적비치수생장시간정현“V”형곡선.근계적쾌속생장구역구유하이적추세.비교생장실관찰면소득수거화알굴근상획득적수거,결과표명,>20~40 cm 토층근계최다,2충방법소득도적근장재각토층적분포추세기본일치、상관성현저,표명본장치가응용우토양재배조건하근계생장적비우동관측.
Observing the dynamic changes of root growth under soil conditions is challenging. In this study, a new type of rhizobox for non-invasively observing root growth under soil conditions is presented. Variations in tobacco seedling root growth were studied as an example of its application. The apparatus consisted of a growth chamber, a nutrient solution-supplying system and an image capture-analysis system. Three subchambers with outer dimensions of 60×30×3 cm were assembled in the shape of a “Y”as the growth chamber. A tobacco seedling was transplanted to the central space of the growth chamber filled with sandy soil, and its root could extend to the soil of three subchambers. Therefore, the growth chamber could both induce two-dimensional root development and facilitate root observation. The soil water content and nutrient concentration in the growth chamber were controlled by supplying a nutrient solution in a designed concentration and volume through a nutrient solution-supplying system, independently. The nutrient solution-supplying system consisted of a solution storage bottle, a pipe, a flux controller and a dripper buried in the soil. The dripper was a J-shape pipe with a funnel to prevent it from being blocked by soil particles. This kind of dripper can make a nutrient solution spread uniformly and avoid clay particle eluviation and illuviation in the soil of the growth chamber. A camera was used to capture images of tobacco roots through a transparent pane during the course of the experiment and root parameters such as root number, root length, root width and root depth were analyzed by Image J software. In our experiment, the roots were observed to appear on the transparent panes of the growth chamber on the 10th day after transplanting (DAT), and the lateral roots appeared on the 24th DAT. Results indicated that tobacco roots had two growth peaks after transplanting. The maximal values of root growth rate were 54.58 cm/d and 185.69 cm/d, respectively. The roots reached the maximum depth on the 46th DAT, while the root width still showed a nearly linear increment on the 53rd DAT. Interestingly, the relation between root depth/root width and growth time showed a “V”feature. The ratio of root depth and root width reached the minimal value of 1.47 on the 24th DAT. It was also found that most of the root distributed in the 0-10 cm soil layer before the 35th DAT. After that, the most-rapid-elongation area of the root moved downward constantly. All seedling roots were excavated from the rhizobox in order to analyze the root parameters at the end of the experiment. The data acquired from the transparent pane were compared with those obtained from the rhizobox excavation. It was found that most of the tobacco roots were distributed in the>20~40 cm soil layer and the root length distribution had a similar pattern with the two methods. The root length data of the different soil layers acquired from the transparent pane was significantly correlated with those obtained by the rhizobox excavation. The correlation coefficient of each soil layer was over 0.9. Our results indicated the apparatus can be used for non-invasive observation of root growth dynamics under soil conditions. In the end, advantages and disadvantages of the new type of rhizobox are discussed.