不同地下水埋深下胡杨叶片生理参数及光谱特征分析

doi:10.13466/j.cnki.lyzygl.2022.01.004

摘要/Abstract

摘要：

该研究以塔里木河流域进行实地野外研究,选取典型荒漠河岸林植物胡杨为研究对象,设置5个不同地下水埋深梯度(0~2 m,2~4 m,4~6 m,6~8 m,8~10 m)。通过测定不同地下水埋深梯度下的胡杨生理指标(MDA、PAL、叶片含水率、叶绿素)和叶片反射光谱进行分析。结果显示:随地下水埋深的增大,叶片含水率与MDA含量的变化呈先下降后上升趋势,而叶绿素密度与PAL活性的变化则呈先上升后下降趋势;MDA含量与PAL活性大小均对地下水埋深变化较敏感,同时,低埋深下可能产生的盐胁迫对于植物影响大于干旱胁迫影响,对于埋深0~2m处叶绿素密度和MDA含量都产生较大的影响,但叶片含水率在5个埋深下的差异较小;在350~900nm波段,胡杨具有“一峰两谷”的特征,在“蓝谷”处,不同埋深下胡杨反射率大小顺序:4~6m>0~2m>6~8m>8~10m>2~4m;“绿峰”处,不同埋深下胡杨反射率大小顺序:4~6m>6~8m>0~2m>8~10m>2~4m,与“红谷”处的差异一致;通过生理指标与光谱的相关分析,在波长429nm之后,原始光谱与叶片含水率均达到极显著负相关,在波长645nm处达到负相关的最大值(r为-0.605 30),总体变化幅度较小;但叶绿素密度与光谱在红边710nm处有相关系数最大值(r为-0.636 55)。胡杨光谱的“三边”参数黄边位置在不同埋深时的差异较大,叶片含水率与红谷幅值达到极显著水平,相关性最强(r为-0.577)。这些指标的变化特征及光谱曲线的变化特征,旨在为胡杨抗旱性的研究与鉴定及干旱区植被恢复提供一定的依据。

关键词: 胡杨, 地下水, 不同埋深, 变化特征, 生理参数, 反射光谱

Abstract:

The study was conducted in the field in the Tarim River basin,with a typical desert riparian forest plant,Populus euphratica as the study object and set five different groundwater depth gradients (0~2 m,2~4 m,4~6 m,6~8 m and 8~10 m). Physiological indicators (MDA,PAL,leaf water content,chlorophyll) and leaf reflectance spectra were analyzed by measuring Populus euphratica under different groundwater burial depth gradients. The results showed that the changes of leaf water content and MDA content tended to decrease at first and increase afterwards with increasing depth of groundwater burial,while the changes of chlorophyll density and PAL activity tended to increase at first and decrease afterwards. Both MDA content and PAL activity magnitude were more sensitive to changes in groundwater burial depth,while the possible salt stress at low burial depths had a greater effect on plants than drought stress,and had a greater effect on chlorophyll density and MDA content at burial depths of 0~2 m. However,the differences in leaf water content at the five burial depths were small. In the 350~900nm band,poplar had the characteristics of "one peak and two valleys". In the "blue valley",the order of poplar reflectance at different burial depths was: 4~6m>0~2m>6~8m>8~10m>2~4m. At the "Green Peak",the order of poplar reflectance at different depths was: 4~6m>6~8m>0~2m>8~10m>2~4m,which was consistent with the difference at the "Red Valley". By correlation analysis of physiological indexes and spectra,the original spectra and leaf water content all reached a highly significant negative correlation after the wavelength of 429 nm,and reached the maximum value of negative correlation at the wavelength of 645 nm (r of -0.60530),with a small overall change. However,the correlation coefficient between the chlorophyll density and the spectrum had a maximum at 710nm on the red side (r of -0.63655). The "trilateral" parameters of the poplar spectra varied greatly at different depths of burial,and the water content of the leaves reached a highly significant level with the red valley amplitude,with the strongest correlation (r of -0.577).The variation characteristics of these indicators and spectral curves are intended to provide some basis for the research and identification of drought resistance of Populus euphratica,and the construction of ecological environment and vegetation restoration in arid areas.

Key words: Populus euphratica, groundwater, different burial depths, characteristics of change, physiological parameters, reflection spectrum

中图分类号:

Q945

张冬冬, 温云梦, 王家强, 李福庆, 蔡海辉, 柳维扬. 不同地下水埋深下胡杨叶片生理参数及光谱特征分析[J]. 林业资源管理, 2022, 0(1): 24-34.

ZHANG Dongdong, WEN Yunmeng, WANG Jiaqiang, LI Fuqing, CAI Haihui, LIU Weiyang. Analyze of Spectral Characterization and Physiological Parameters in Populus Euphratica Leaves under Different Groundwater Burial Depths[J]. FOREST RESOURCES WANAGEMENT, 2022, 0(1): 24-34.

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参考文献 26

[1]	魏庆莒. 胡杨[M]. 北京: 中国林业出版社, 1990.
[2]	王海珍, 韩路, 徐雅丽, 等. 不同温度下灰胡杨叶片气孔导度对光强响应的模型分析[J]. 生态环境学报, 2015,24(5):741-748.
[3]	徐海量, 宋郁东, 王强, 等. 塔里木河中下游地区不同地下水位对植被的影响[J]. 植物生态学报, 2004(3):400-405. doi: 10.17521/cjpe.2004.0057
[4]	陈亚宁, 李卫红, 徐海量, 等. 塔里木河下游地下水位对植被的影响[J]. 地理学报, 2003(4):542-549.
[5]	宋玉. 荒漠春季(成年)胡杨叶片含水率地面光谱特征分析[D]. 乌鲁木齐:新疆大学, 2015.
[6]	赵新风, 李伯岭, 王炜, 等. 极端干旱区8个绿洲防护林地土壤水盐分布特征及其与地下水关系[J]. 水土保持学报, 2010,24(3):75-79.
[7]	朱成刚, 李卫红, 马晓东, 等. 塔里木河下游干旱胁迫下的胡杨叶绿素荧光特性研究[J]. 中国沙漠, 2011,31(4):927-936.
[8]	Sims D A, Gamon J A. Estimation of vegetation water content and photosynthetic tissue area from spectral reflectance:a comparison of indices based on liquid water and chlorophyll absorption features[J]. Remote Sensing of Environment, 2003,84(4):526-537. doi: 10.1016/S0034-4257(02)00151-7
[9]	张丽, 董增川, 黄晓玲. 干旱区典型植物生长与地下水位关系的模型研究[J]. 中国沙漠, 2004,24(1):110-113.
[10]	陈亚鹏, 陈亚宁, 李卫红, 等. 塔里木河下游干旱胁迫下的胡杨生理特点分析[J]. 西北植物学报, 2004(10):1943-1948.
[11]	牛婷, 艾里西尔·库尔班, 玉米提·哈力克, 等. 干旱区胡杨叶片含水量和叶绿素含量特征[J]. 生态学杂志, 2012,31(6):1353-1360.
[12]	贺立红, 张进标, 宾金华. 苯丙氨酸解氨酶的研究进展[J]. 食品科技, 2006(7):31-34.
[13]	宋修鹏, 黄杏, 莫凤连, 等. 甘蔗苯丙氨酸解氨酶基因(PAL)的克隆和表达分析[J]. 中国农业科学, 2013,46(14):2856-2868.
[14]	Guo Jia, Wang Myeong-Hyeon. Character-ization of the phenylalanine ammonia-lyase gene(SlPAL5)from tomato(Solanum lycopersicum L.)[J]. Molecular Biology Reports, 2009,36(6):1579-1585. doi: 10.1007/s11033-008-9354-9 pmid: 18791854
[15]	Pan Qiuhong, Zhan Jicheng, Liu Hongtao, et al. Salicylic acid synthesized by benzoic acid 2-hydroxylase participates in the development of thermotolerance in pea plants[J]. Plant Science, 2006,171(2):226-233. doi: 10.1016/j.plantsci.2006.03.012
[16]	刘国华, 周兴元, 杨士虎. 盐胁迫对3种四照花属植物生理特性的影响[J]. 西部林业科学, 2018,47(2):59-64.
[17]	郭枫, 郭相平, 袁静, 等. 地下水埋深对作物的影响研究现状[J]. 中国农村水利水电, 2008(1):63-66.
[18]	庄丽, 陈亚宁, 李卫红, 等. 干旱区荒漠植被丙二醛及保护酶活性对地下水位的响应[J]. 冰川冻土, 2005(5):723-733.
[19]	陈亚宁, 李卫红, 陈亚鹏, 等. 新疆塔里木河下游河道生态输水对植被生理的影响研究[J]. 自然科学进展, 2004(6):66-72.
[20]	赵文智, 刘鹄. 荒漠区植被对地下水埋深响应研究进展[J]. 生态学报, 2006(8):2702-2708.
[21]	倪萍, 牛博. 干旱区荒漠植被的特点及恢复问题的研究——以塔里木河流域胡杨林生态系统为例[J]. 新疆环境保护, 2004(S1):103-106.
[22]	吴婧舒, 周广柱, 周金峰. 运用生理生化指标对平榛抗旱性的综合评价[J]. 湖北农业科学, 2010,49(1):56-59.
[23]	周虹, 范巧佳, 郑顺林, 等. 春季水分胁迫对川芎叶片相对含水量及保护酶活性的影响[J]. 中国中药杂志, 2009,34(2):132-137.
[24]	杨丽, 张秋良, 常金宝. 胡杨树根系空间分布特性[J]. 内蒙古农业大学学报:自然科学版, 2006(1):15-17.
[25]	司建华, 冯起, 李建林, 等. 荒漠河岸林胡杨吸水根系空间分布特征[J]. 生态学杂志, 2007(1):1-4.
[26]	李继业, 杨芳, 姚国慧, 等. 艾比湖流域典型荒漠植被光谱特征分析[J]. 林业资源管理, 2015(1):112-117.

范围	定义	“三边” 参数	内涵
蓝边	蓝边幅值	Db	490~530 nm内最大一阶导数值
	蓝边位置	WP-b	Db对应的波长
	蓝边面积	SDb	蓝边内一阶导数的总和
绿峰	绿峰幅值	Rg	530~560 nm内最大的波段反射率
	绿峰位置	WP-g	Rg对应的波长
黄边	黄边幅值	Dy	560~640 nm内最大一阶导数值
	黄边位置	WP-y	Dy对应的波长
	黄边面积	SDy	黄边内一阶导数的总和
红谷	红谷反射率	Ro	640~680 nm内最小的波段反射率
	红谷位置	WP-o	Ro对应的波长
红边	红边幅值	Dr	680~760 nm内最大一阶导数值
	红边位置	WP-r	Dr对应的波长
	红边面积	SDr	红边内一阶导数的总和

统计指标	埋深/m	平均值	最小值	最大值	标准差	变异系数
	0~2	0.03522	0.01761	0.04941	0.01103	31.31%
	2~4	0.05659	0.04358	0.07498	0.00954	16.85%
叶绿素密度/(mg/cm²)	4~6	0.04394	0.03624	0.05549	0.00594	13.52%
	6~8	0.04488	0.03292	0.05602	0.00818	18.21%
	8~10	0.04467	0.02890	0.05759	0.00957	21.41%
	0~2	1.55252	0.76580	2.76663	0.69555	44.80%
	2~4	1.04648	0.76284	1.29064	0.20305	19.40%
MDA含量/(nmol/cm² FW)	4~6	0.84830	0.52499	1.07825	0.16967	20.00%
	6~8	0.92033	0.52349	1.25830	0.23410	25.44%
	8~10	1.41290	1.01031	1.88812	0.28642	20.27%
	0~2	1.16925	0.35577	2.77055	0.76651	65.56%
	2~4	1.74876	0.37407	8.57528	2.43519	139.25%
PAL活性(U/cm² FW)	4~6	3.79812	2.38218	5.49893	0.94541	24.89%
	6~8	4.18301	2.45562	6.31725	1.28068	30.62%
	8~10	1.37021	0.67778	4.74859	1.22161	89.16%
	0~2	65.03%	60.14%	71.09%	3.51%	5.39%
	2~4	62.19%	57.03%	71.45%	4.17%	6.70%
叶片含水率	4~6	51.27%	44.94%	57.10%	3.48%	6.79%
	6~8	52.44%	46.46%	57.28%	3.21%	6.13%
	8~10	60.54%	52.99%	71.63%	6.22%	10.27%

光谱提取变量	0~2m	2~4m	4~6m	6~8m	8~10m
蓝边幅值Db	0.00160	0.00093	0.00209	0.00155	0.00148
黄边幅值Dy	0.00011	0.00022	0.00033	0.00023	0.00023
红边幅值Dr	0.00903	0.00861	0.01068	0.00911	0.00848
蓝边面积SDb	0.02854	0.02044	0.03999	0.03164	0.02676
黄边面积SDy	-0.03649	-0.02130	-0.04554	-0.02928	-0.02807
红边面积SDr	0.34680	0.32183	0.40240	0.35308	0.34290
绿峰幅值Rg	0.16115	0.12953	0.21300	0.16382	0.14680
红谷幅值Ro	0.11027	0.09663	0.14970	0.11920	0.10528
蓝边位置WP-b/nm	520	520	519	527	517
黄边位置WP-y/nm	596	606	631	621	614
红边位置WP-r/nm	704	718	718	718	717
绿峰位置WP-g/nm	555	553	554	554	554
红谷位置WP-o/nm	667	669	672	672	664

光谱提取变量	叶绿素密度	MDA含量	PAL活性	叶片含水率
蓝边幅值Db	-0.540^**	-0.096	0.130	-0.309^*
蓝边面积SDb	-0.547^**	-0.159	0.155	-0.384^**
黄边幅值Dy	0.342^*	-0.449^**	0.259	-0.451^**
黄边面积Sdy	0.512^**	0.071	-0.093	0.227
红边幅值Dr	-0.232	-0.165	0.169	-0.190
红边面积Sdr	-0.325^*	-0.163	0.186	-0.241
红边位置WP-r	0.544^**	-0.038	0.030	-0.110
蓝边位置WP-b	0.019	-0.149	0.190	-0.281
黄边位置WP-y	-0.185	-0.017	-0.002	0.063
绿峰幅值Rg	-0.424^**	-0.213	0.418^**	-0.533^**
红谷幅值Ro	-0.230	-0.237	0.503^**	-0.577^**
红谷位置WP-o	0.060	-0.313^*	0.272	-0.417^**
绿峰位置WP-g	-0.431^**	-0.004	0.123	-0.236