植物水分含量检测综述

doi:10.11924/j.issn.1000-6850.casb14100128

摘要/Abstract

摘要： 水分作为植物生长和发育的要素之一,其含量的检测与诊断是植物学及农业、林业等领域的重要研究课题。植物水分含量诊断主要是通过对比植物特定性状指标与正常生长环境下的指标来实现。随着植物生理、生化研究的深入以及传感、检测技术的进步,发展出众多的植物水分含量检测方法。从最初通过检测细胞液浓度来直接反映水分含量,到测量植物蒸腾速率、茎流流速、叶片水势、冠层温度、茎秆直径、特定化学物质含量等间接反映水分含量,以致现在以图像、光谱分析为基础的机器视觉等新方法成为主流。本文在充分调研国内外研究和文献的基础上,详细介绍主要的水分含量检测方法原理,分析其优缺点,试图把握植物水分检测的发展趋势和研究方向,为相关科研和应用提供有益参考。

关键词: 发芽糙米, 发芽糙米, γ-氨基丁酸, HPLC, 柱前衍生, 邻苯二甲醛, 丹磺酰氯

Abstract: Moisture is one of the elements of plant growth and development. Detection and diagnosis of plant’s moisture content is an important research topic in botany, agriculture, forestry and other fields. By detecting the moisture content, the scientists can know the state of the plant’s growth, menstrual cycles for learning the relationship of moisture content and plant growth. Through detecting plant’s specific traits index and comparing it with the same kind index which was gotten from the plants that grow up in normal environment is the main way of plant’s moisture content detection. Science and technology always shows up before method. With the development of plant physiology, biochemistry and the improvement of the technology of sensor and detection, scientists have developed a large number of methods which are used for the detection of plant moisture content. At the beginning, scientists directly showed the content of plant moisture by detecting the cell sap concentration. But the way is full of discommodiousness and hard to carry out in the outdoor environment. Then, scientists got the content of plant moisture indirectly by detecting plant transpiration rate, stem flow velocity, leaf water potential, crown layer temperature, stem diameter, and the changes of the specific chemicals content in plants, etc. Up to now, new approaches of the plant’s moisture content detection called machine vision which is based on images and spectral analysis become the major ways for scientific activity. This paper introduced some primary ways and principles of plant water content on the basis of full research studies and literatures at home and abroad, and analyzed their advantages and weaknesses, tried to grasp the trends and research directions of plant moisture detection, provided a useful reference for related research and application.

陆元洲,江朝晖,李想,祁钊. 植物水分含量检测综述[J]. 中国农学通报, 2015, 31(9): 168-177.

陆元洲,, and . The Review of Plant Moisture Content Detection[J]. Chinese Agricultural Science Bulletin, 2015, 31(9): 168-177.

参考文献

[1] 徐祝龄,王汶. 玉米水分亏缺监测诊断的研究[J]. 北京农业大学学报, 1995, 21(3): 291-298.
[2] 陈铭德.细胞液浓度与细胞吸水力的关系[J].生物学杂志,1986,(1):-.
[3] 洛薄夫,余叔文.植物细胞液汁浓度与生长的关系[J].植物生理学通讯,1955,(20:-.
[4] 陶益寿.以农作物的细胞液浓度作为灌水指标的研究[J].节水灌溉,1988,(4):-.
[5] Eaton F M.The water requirement and cell-sap concentration of Australian saltbush and wheat as related to the salinity of the soil[J].American Journal of Botany,1927:212-226.
[6] 申卫军,彭少麟.热脉冲 (Heat pulse) 法原理及其应用[J].资源生态环境网络研究动态,2000,11(2): 22-27.
[7] ?ermák J, Deml M, Penka M.A new method of sap flow rate determination in trees[J].Biologia Plantarum,1973,15(3):171-178.
[8] 白云岗,宋郁东,周宏飞,等.热脉冲法对胡杨树干液流的监测与蒸腾过程模拟[J].水土保持学报,2007,21(3):188-192.
[9] 胡雅杰,闫业庆,张旭昇,等.应用热平衡法对黄土高原玉米茎流变化规律的研究[J].安徽农业科学,2010,38(22):11893-11894,12258.
[10] 王淑庆,张岁岐,王小林.黄土塬区不同栽培模式下玉米蒸腾耗水规律的研究[J].中国生态农业学报,2013,21(4):432-439.
[11] 高阳,段爱旺,邱新强,等.应用热平衡法测定玉米/大豆间作群体内作物的蒸腾量[J].The journal of Journal of applied ecology,2010,21(5):1283-1288.
[12] Granier A, Claustres J P.Water relations of a Norway spruce (Picea abies) tree growing in natural condition:Variation within the tree[J].Acta Oecologica,1989,10(3):295-310.
[13] 龙秋波,贾绍凤.茎流计发展及应用综述[J].水资源与水工程学报,2012,23(4):18-23.
[14] 刘鑫.热扩散式茎流计在测定植物蒸腾耗水中的应用[J].山西林业科技,2009,38(4):30-33.
[15] 尚爱军,冯光惠.热扩散探针(TDP)茎流计在测算树干液流中的应用[J].湖北农业科学,2008, 47(7):838-842.
[16] 张佳薇,季虹,李明宝.基于热比率(HRM)法的低速率茎流测量技术[J].机电产品开发与创新,2012,25(1):137-139.
[17] 季虹.基于热比率法(HRM)的茎流测量及环境因子修正方法研究[D].东北林业大学,2012.
[18] 赵自国,夏江宝,王荣荣等.不同土壤水分条件下叶底珠(Securinega suffruticosa)茎流特征[J].中国沙漠,2013,33(5):1385-1389.
[19] 李兴财,赵宁.风沙静电场对植物茎秆液流传输过程影响的理论分析[J].中国沙漠,2013,33(6):1731-1734.
[20] 顾幸生,潘晔,卢胜利.基于改进支持向量机的作物叶水势软测量建模[J].同济大学学报:(自然科学版),2010,38(11):1669-1674.
[21] 黄久常,王邦锡.小液流法测定植物水势的改进试验[J].植物生理学通讯,1988,(5):-.
[22] 王振英.小液流法测定植物水势毛细玻璃滴管的改进[J].实验技术与管理,1998,15(6): 60-61.
[23] TYREE,M . T.;HAMMEL, H. T.The Measurement of the Turgor Pressure and the Water Relations of Plants by the pressure-bomb Technique[J].Journal of Experimental Botany,1972,23(1): 267-282.
[24] 李德全,邹琦,程炳嵩.测定植物组织水势的压力室法[J].山东农业科学,1990,(3):46-48.
[25] 张富仓,李志军,康绍忠.用热电偶湿度计测定土壤水势的方法研究α[J].西北农林科技大学学报(自然科学版),2001,29(1).
[26] 荆家海,肖庆德.利用热电偶湿度计测定水势[J].植物生理学通讯,1986,(1):51-53.
[27] Namken L N,Bartholic J F,Runkles J R.Monitoring cotton plant stem radius as an indication of water stress[J].Agronomy Journal,1969,61(6): 891-893.
[28] Levia D F,Michalzik B,Bischoff S,et al.Measurement and modeling of diameter distributions of particulate matter in terrestrial solutions[J].Geophysical Research Letters,2013,40(7):1317-1321.
[29] 孟兆江,段爱旺,刘祖贵,等.根据植株茎直径变化诊断作物水分状况研究进展[J].农业工程学报,2005,21(2):30-33.
[30] 何斌,李卫红,陈永金,等.干旱胁迫条件下胡杨茎流与茎直径变化分析——以塔里木河下游英苏断面为例[J].干旱区地理,2007,30(2):223-230.
[31] 曹逼力,徐坤,石健,等.硅对番茄生长及光合作用与蒸腾作用的影响[J].植物营养与肥料学报,2013,19(2):354-360.
[32] Heinemann A B,Stone L F, Fageria N K.Transpiration rate response to water deficit during vegetative and reproductive phases of upland rice cultivars[J].Scientia Agricola,2011, 68(1):24-30.
[33] E.-D. Schulze,Hall A .E. Hall, O .Lange and H.Walz. A portable steady-state porometer for measuring the carbon dioxide and water vapour exchanges of leaves under natural conditions[J]. Oecologia,1982,53(2):141-145.
[34] M . G . Holmes, J. C . Sager and W . H . Klein. Sensitivity to far-red radiation in stomata of Phaseolus vulgaris L.: Rhythmic effects on conductance and photosynthesis[J].Planta,1986,168(4): 516-522.
[35] 刘奉觉.使用稳态气孔计的几个技术问题[J].林业实用技术,1988,(2):-.
[36] 刘奉觉.用快速称重法测定杨树蒸腾速率的技术研究[J].林业科学研究,1990,3(2):162-165.
[37] 李薛飞.齐齐哈尔地区五种树木蒸腾速率研究[D].东北林业大学,2011.
[38] 隋旭红.晋西黄土区主要树种蒸腾特性研究[D].北京林业大学, 2011.
[39] 蔡焕杰,康绍忠.用冠层温度计算作物缺水指标的一种简化模式[J].水利学报,1996,(5):44-49.
[40] 梁银丽,张成娥.冠层温度-气温差与作物水分亏缺关系的研究[J].中国生态农业学报, 2000,8(1):24-26.
[41] Jackson R D,Reginato R J,Idso S B.Wheat canopy temperature: a practical tool for evaluating water requirements[J].Water Resources Research,1977,13(3): 651-656.
[42] N . D S. Huband and J L . Monteith Radiative surface temperature and energy balance of a wheat canopy[J].Boundary-Layer Meteorology,1986,36(1-2):107-116.
[43] 周芳,刘恩世,孙海彦,等.水分胁迫对干旱锻炼后木薯叶片内脱落酸,脯氨酸及可溶性糖含量的影响[J].西南农业学报,2013, 26(4): 1428-1433.
[44] 杨建昌,乔纳圣.水分胁迫对水稻叶片气孔频率,气孔导度及脱落酸含量的影响[J].作物学报,1995,21(5):533-539.
[45] 刘祖祺,张连华,朱培仁.用放射免疫法分析柑桔抗寒锻炼中游离和结合态脱落酸的变化[J].园艺学报, 1990, 17(3): 197-202.
[46] 侯学瑛.用气相色谱测定植物激素脱落酸[J].分析仪器,1986,(3):-.
[47] 魏东,黄智鸿,赵月平,等.浅析ELISA的基本原理与注意事项[J].安徽农业科学,2009,37(6):2357-2358.
[48] E Engvall, P Perlmann. Enzyme-linked immunosorbent assay (ELISA). Quantitative assay of immunoglobulin G[J]. Immunochemistry, 1971, 8(9): 871-874.
[49] 周安佩,刘东玉,江涛,等.滇杨一年生扦插苗侧芽内源激素含量的变化分析[J].北方园艺,2014 (4):63-67.
[50] 王露,吴中军,刘杰.外源IBA对百合切花花瓣内源激素的影响[J].安徽农业科学,2014,42(4):974-975.
[51] 彭文,李庆武,霍冠英,等.基于计算机视觉的植物水分胁迫状况监测方法[J].科学技术与工程,2013(9):2313-2317,2330.
[52] Kacira M, Ling P P,Short T H. Machine vision extracted plant movement for early detection of plant water stress[J].Transactions of the ASAE. American Society of Agricultural Engineers,2001,45(4):1147-1153.
[53] 甘露萍.基于机器视觉技术的鲜烟叶含水量模型研究[D].重庆:西南大学,2009.
[54] 孙瑞东,于海业,于常乐,等.基于图像处理的黄瓜叶片含水量无损检测研究[J].农机化研究,2008(7):87-89.[56] 甘露萍,谢守勇,邹大军.基于计算机视觉的烤烟鲜烟叶含水量无损检测及MATLAB实现[J].西南大学学报:自然科学版,2009 (7):166-170.
[55] 张晓飞.基于计算机视觉的棉花群体生长指标检测[D].北京邮电大学,2007.
[56] 甘露萍,谢守勇,邹大军.基于计算机视觉的烤烟鲜烟叶含水量无损检测及MATLAB实现[J].西南大学学报:自然科学版,2009 (7):166-170.[55] 张晓飞.基于计算机视觉的棉花群体生长指标检测[D].北京邮电大学,2007.[56] 王娟,危常州,王肖娟,等.采用灰板校正的计算机视觉预测棉花叶绿素含量[J].农业工程学报,2013,29(24):173-180.
[57] 张玉华,孟一.肉类品质无损检测技术研究现状与发展趋势[J].食品工业科技,2012,33(12):392-395,400.
[58] 侯瑞,吉海彦,饶震红,等.基于近红外光谱的活体植物叶片水分检测仪器[J].农业工程学报,2009,25(13):92-96.
[59] 李文龙,徐金钟,刘绍勇,等.近红外漫反射光谱法测定5种中药提取物中水分含量的研究[J].药物分析杂志,2009 (10):1602-1606.
[60] 林晓鹰.近红外水分仪的研制[J].中国仪器仪表,2001(2):13-14.