农牧交错区生态环境质量遥感动态监测——以宁夏盐池为例

以26 a（1989-2015年）4期Landsat TM/OLI遥感数据为基础,提取不同年份的湿度指数、植被指数、地表温度以及土壤指数,利用主成分分析法,构建盐池县4个时期遥感生态指数（RSEI）和生态环境质量综合指数（ESI）,对其生态环境质量进行了评价,探讨区域生态环境的时空变化特征。结果表明：（1）湿度、绿度对区域生态环境质量起正面作用,而热度和干度则起负面作用,其中代表绿度指标的植被覆盖度（NDVI）对生态指数的贡献最大。（2）1989-2015年间,4个年份RSEI均值分别为0.41、0.54、0.51、0.57,生态环境质量呈上升-下降-上升且整体变好的特征。26 a间研究区生态环境明显转好的面积约占全县面积的20.01%,而生态环境质量中明显变差的面积仅占全县面积的1.64%。改善区域主要分布在研究区北部的盐池县城-高沙窝镇-王乐井乡以及惠安堡镇以南-麻黄山地区,中部的冯记沟乡生态环境质量有所变差。（3）盐池县生态环境质量受气候影响明显,退耕还林还草、草地禁牧以及禁止乱砍乱伐等措施对生态环境质量的提升起到了重要的促进作用。     

青藏高原植被覆盖变化的地域分异特征

植被的空间分布及其变化都具有明显的地域分异特征。本研究以1981-2006年间的GIMMS/NDVI产品为主要数据源,在地理信息系统技术的支持下,分别从植被空间分布、植被波动和植被变化等方面,探讨了青藏高原植被覆盖变化的水平地域分异特征。研究结果显示,1981-2006年间,雅鲁藏布江河谷区、错那县和墨脱县的西北部、柴达木盆地南缘、三江源地区的顶端和青海南山北麓等区域地表植被年际波动较大。反映区域植被盖度时间变化趋势的SLOPE值以及植被盖度,具有从南部、东南部向北、西北部"下降—上升—不变"的规律。植被盖度下降显著的区域主要分布在喜马拉雅山南麓和青海湖南部,其次是三江源中南部地区;植被没有明显变化的区域主要分布在藏北高原和柴达木盆地。植被指数显著上升的区域集中在雅鲁藏布江河谷区,植被指数明显上升区域主要分布在人迹罕至的唐古拉山和念青唐古拉山等山间盆地区,轻微上升的区域分散在明显改善区的周围。依据SLOPE值的空间分异特征将整个高原划分为4个一级区:帕米尔高原植被指数上升区、藏北高原—阿里高原—柴达木盆地植被指数稳定区、高原中部—雅鲁藏布江中上游河谷植被指数上升区和三江源—横断山区植被指数下降区。     

基于改进遥感生态指数的甘肃省古浪县生态质量评价

干旱、半干旱地区约占中国陆地总面积的47%,该地区多以荒漠为背景,其生态结构简单,生态系统脆弱。为了更加客观准确的评价干旱、半干旱地区生态质量,对遥感生态指数（Remote sensing ecological index,RSEI）进行改进,提出一种适用于干旱地区的干旱遥感生态指数（Drought remote sensing ecological index,DRSEI）,该指数由绿度、湿度、干度、荒漠化指数和热度5个生态因子耦合而成。相较于RSEI,DRSEI对植被更加敏感,对不透水面、土地以及沙地的分辨能力更强,适合干旱半干旱地区的生态质量评价。利用DRSEI对古浪县1994—2020年生态质量进行长时序的动态监测与评价。结果表明：古浪县1994—2020年生态质量整体变好,中西部和东南部植被覆盖度明显增加,对生态环境有很强的改善作用;生态质量较差的区域主要集中在北部腾格里沙漠,生态质量为优、良、中的地区主要分布在南部祁连山东端支脉。基于DRSEI定量化评价干旱半干旱区域生态质量,对指导我国干旱半干旱区域的生态环境整治以及可持续发展具有重要的现实意义。     

中国土地利用变化生态环境效应的空间分异性与形成机理

中国复杂的自然要素、社会经济要素、区域发展战略和政策调控形成了当前中国不均衡的经济发展空间格局、土地利用空间格局和生态环境质量空间格局。厘清中国生态环境质量的空间格局及形成机理对中国土地资源的可持续利用和生态环境的有效保护具有重要的实践意义和价值。以往研究缺乏对中国县域尺度土地利用/土地覆被变化生态环境效应的空间分异性及形成机理的相关研究,本研究基于1995—2015年间中国土地利用现状遥感监测数据,尝试采用生态环境质量指数方法测度中国土地利用变化的生态环境效应,并且综合运用重心分析、热点分析工具（Getis-Ord G_i*）和地理探测器等研究方法,分析1995—2015年中国生态环境质量时空演变特征及形成机理。研究结果如下：① 东部季风区生态环境质量指数高于青藏高寒区和西北干旱区,东部季风区生态环境质量低值区主要分布在人口和经济集聚的城市群以及省会城市周边地区。研究期间中国生态环境质量重心持续向西北方向迁移;② 1995—2015年间中国生态环境质量变化的热点区域主要分布在西藏地区、新疆、重庆、贵州以及位于黄土高原的省份（青海、甘肃、宁夏、内蒙古、山西、陕西以及河南）境内,冷点区域主要分布在长江经济带沿线地区省份以及东南部沿海地区省份;③ 土地利用程度对于生态环境质量影响力显著强于其他因子,东部季风区的社会经济和交通区位因子对生态环境质量影响力强于青藏高寒区、西北干旱区和生态大区过渡带;④ 影响因子之间相互作用主要包括非线性增强作用和双因子增强作用两种类型,以非线性增强作用为主。     

西藏自治区植被与气候变化的关系

气候变化下植被的时空响应是近年来的研究热点。高海拔西藏地区气候独特多变,研究该区域植被与气候变化的关系具有重要意义。西藏地区的气象站少,利用站点观测资料插值分析误差相对较大,难以准确获得空间连续的数据。本文采用2001~2013年MODIS卫星16天时间序列数据和同期的降雨卫星TRMM数据,利用线性回归和相关性分析法研究西藏地区植被、地表温度和降雨量的时空特征及相关性。研究表明:在2001~2013年间,西藏地区植被与地表温度、降雨量在时间波动和空间分布上具有一致性。植被NDVI逐年增大,植被状况逐渐改善,地表温度总体呈上升趋势,降雨量整体无明显变化,三者年际变化率主要集中在-0.005~0.005/a,-0.05℃~0.15℃/a,-30~40 mm/a。近13年来植被NDVI、地表温度和降雨量的变化区域差异性较大,在西藏中部和东部变化明显。植被NDVI的变化与气候变化(尤其是地表温度上升)密切相关,受降雨明显影响的区域分布在西藏中部,受地表温度明显影响的区域分布在西藏东部和西部。     

基于遥感和GIS的流域自然生态环境质量监测与评价——以无定河流域为例

遥感与GIS技术的发展,为大区域自然生态环境质量的监测与评价提供了低成本、高效率的先进技术手段。基于2000、2004、2008、2012年和2016年共5期MODIS数据,结合地形数据,提取植被覆盖度、土壤指数、坡度等关键生态因子,并基于归一化的生态因子,建立生态环境评价模型,对无定河流域的自然生态环境质量的时空动态变化进行分析和评价。研究结果表明：无定河流域近16 a来自然生态环境质量总体上呈改善趋势,其西北区域受荒漠化影响较为严重,生态质量相对较差。研究结果为正确地认识和评价流域内的生态环境质量,把握不同时期生态环境质量的差异,为生态环境质量的治理、改善提供重要参考。     

基于PSR模型的白龙江流域景观生态安全时空变化

以地貌灾害频发的甘肃白龙江流域为研究区,基于"压力-状态-响应"框架模型构建流域景观生态安全评价指标体系,探讨其时空变化过程及其特征。结果表明:1990~2010年间白龙江流域景观生态安全综合指数逐渐上升,中高安全等级以上的面积约占研究区总面积的52%。流域内低生态安全区域主要集中在舟曲-武都段白龙江两岸区域、宕昌县西北区域和迭部县北部山区,高安全区域主要集中在自然保护区、林业发展区等植被覆盖较好的区域,其分布格局与滑坡、泥石流和水土流失等地貌灾害的风险分布格局相反。     

2000～2011年毛乌素沙地植被生长状况时空变化特征

采用2000~2011年MOD13Q1数据构建EVI时间序列谱,对毛乌素沙地植被生长状况的时空特征进行了研究。主要得出以下结论:①2000~2011年毛乌素沙地EVI年最大值以轻微波动为主,植被生长状况在2001年最差,2010年最好。②全区EVI年最大值按0.002 5/a的速度递增,植被生长状况趋于改善的面积占总面积的81.916%,主要分布在中部、东部和南部等地区;生长状况呈变差趋势的面积占总面积的18.084%,主要分布在北部、西部和中南部。③植被生长状况以轻度和中度波动改善为主,主要分布在西南、中部和东部;重度波动改善区主要分布在西南部和东南部,轻度和中度波动退化区主要分布在西南部、西部和中南部。     

21世纪以来青藏高寒草地的变化特征及其对气候的响应

利用遥感数据和气象观测资料探索气候因子对区域植被变化的驱动作用具有重要意义。以1980-2012年气象数据和2000-2012年MODIS-NDVI数据为数据源,借助线性回归和相关分析分别分析了青海和西藏两个地区21世纪以来气候变化对青藏高寒草地的影响机制。结果表明：（1）1980-2012年,青海和西藏地区均呈暖湿化的发展趋势。但21世纪以来,西藏地区降水呈不显著的减少趋势;整个青藏高原中部和西部地区增温趋势明显（>0.05 ℃·a-1）。（2）在年际尺度（2000- 2012年）上,青海地区NDVI呈显著增加的趋势,增长率为0.003·a-1（P<0.05）;西藏地区NDVI无变化趋势,区域尺度统计中植被退化与改善相互抵消。在空间上,青藏高原东北部地区NDVI呈良性趋势,部分区域增长斜率超过0.01·a-1。青藏高原南部地区NDVI呈变差趋势,变化斜率为0.008·a-1。（3）区域上的相关分析显示,在青海地区,降水量的增加和温度的升高共同促进了该区域植被的良性发展趋势;在西藏地区,降水量的减少和温度的升高可能是南部地区植被变差的重要原因。     

1992—2020年横断山区植被分布与植被活动变化

横断山区位于青藏高原东缘和多条重要江河的上游,是全球生物多样性最丰富的地区和生态保护的优先区域之一,区域植被对维系区域生态安全和可持续发展起着十分重要的作用。20世纪90年代以来,中国在横断山区实施了多项重大生态恢复和建设工程,但囿于资料和调查不足,对于横断山区全域性、长时段的植被变化及其与海拔关系研究相对较少。鉴此,本文结合使用1992—2020年间多种基于卫星遥感资料生产的土地覆被数据和2000—2020年间MODIS的归一化植被指数（NDVI）数据,采用转移矩阵、Theil-Sen Median趋势分析与偏相关分析等方法研究不同植被类型转换、植被覆被面积与平均海拔变化关系以及植被活动的时空变化趋势,并分析时空变化的主要影响因素。结果表明：① 横断山区分布最广泛的植被类型是常绿针叶林与灌丛—草地镶嵌类型。植被发生变化的区域集中分布在河谷和南部低海拔区域,草地多向森林特别是常绿针叶林转换,植被覆被逐渐向好。这表明封山育林、植树造林、退耕还林等生态保护政策起到重要积极作用。时间序列数据显示,植被覆被面积变化剧烈的时期往往处在政策实施的起始阶段。② 植被活动整体呈现增强趋势。在植被类型未变化的区域中,75%以上区域植被活动增强,其中超20%的区域显著增强（P < 0.05）,且森林植被活动增强趋势大于草地。③ 对植被活动影响较大的环境因子主要是气候变化和地形条件。尽管大部分区域植被活动受气候变暖影响而增强,但在干热河谷的植被活动明显受到降水减少的限制。有近1/4面积的植被活动在减弱,主要分布在山地东坡或南坡,或与降水较多、山高坡陡而造成滑坡、泥石流等自然灾害有关。这些发现可为横断山区生态保护政策效益评估、自然灾害综合风险评估和未来气候变化影响下的植被变化预测提供参考。     

黄河三角洲“三生”用地转型的生态环境效应及其空间分异机制

“三生”用地转型的生态环境效应及其空间分异特征是指导区域国土空间开发与生态环境保护的重要依据。基于1998年、2008年和2018年3期土地利用遥感解译数据,构建黄河三角洲“三生”用地分类体系,通过土地利用转型图谱、生态环境质量指数、重心转移和地理探测器等方法定量分析研究区“三生”用地转型特征、生态环境效应及其空间分异性的主要影响因子。结果表明：① 1998—2018年黄河三角洲“三生”用地转型表现为生产用地占比大幅增加（+13.50%）,生态用地占比大幅减少（?17.19%）,生活用地占比小幅增长（+3.69%）。1998—2008年,“三生”用地转型以生态用地向生产用地转型为主。2008—2018年,无绝对优势转型类型,转型过程复杂化。② 1998—2018年,黄河三角洲生态环境质量整体向好,指数由0.390升至0.395,较高质量区与高质量区占主体地位。研究区中部及黄河入海口区域生态环境质量不断提升,东南及东北沿海地区生态环境质量有所降低。③ 植被覆盖度、微地貌类型、土壤类型是研究区生态环境质量空间分异的主导因子。区位因子与社会经济因子对生态环境质量空间分异的贡献率随生态环境质量的提升而降低,生态保护因子对生态环境质量空间分异的贡献率呈上升趋势。     

藏东南三江并流核心区植被时空动态变化及其气候驱动力分析

植被生长状况及其分布对气候等影响因子的响应是当前生态学研究的热点之一。基于2000—2016年MODIS NDVI数据和气象数据,用Sen+Mann-Kendall等方法分析了藏东南三江并流核心区植被的时空变化及其与气候因子的关系。研究结果表明：① 该区植被覆盖整体趋于稳定,呈缓慢增加趋势,不同植被类型覆盖空间异质性明显。② 植被变化趋势结果显示植被覆盖变化以稳定不变和改善趋势为主,区域总体呈稳中向好态势。③ 相关分析表明植被NDVI增加主要与气候暖化有关,与降水量相关性较小。此外,人类活动对植被影响的双重性表现为：大多地区植被改善受生态工程和围栏禁牧政策影响,局部地区植被退化则与城镇化进程加快有关。研究结果揭示气温是影响植被格局的主要气候因子,了解影响植被变化及其驱动因素的空间变异性可为山地植被生态环境保护建设提供一定的科学依据。     

The relationship between NDVI and precipitation on the Tibetan Plateau

The temporal and spatial changes of NDVI on the Tibetan Plateau, as well as the relationship between NDVI and precipitation, were discussed in this paper, by using 8-km resolution multi-temporal NOAA AVHRR-NDVI data from 1982 to 1999. Monthly maximum NDVI and monthly rainfall were used to analyze the seasonal changes, and annual maximum NDVI, annual effective precipitation and growing season precipitation (from April to August) were used to discuss the interannual changes. The dynamic change of NDVI and the corre-lation coefficients between NDVI and rainfall were computed for each pixel. The results are as follows: (1) The NDVI reached the peak in growing season (from July to September) on the Tibetan Plateau. In the northern and western parts of the plateau, the growing season was very short (about two or three months); but in the southern, vegetation grew almost all the year round. The correlation of monthly maximum NDVI and monthly rainfall varied in different areas. It was weak in the western, northern and southern parts, but strong in the central and eastern parts. (2) The spatial distribution of NDVI interannual dynamic change was different too. The increase areas were mainly distributed in southern Tibet montane shrub-steppe zone, western part of western Sichuan-eastern Tibet montane coniferous forest zone, western part of northern slopes of Kunlun montane desert zone and southeastern part of southern slopes of Himalaya montane evergreen broad-leaved forest zone; the decrease areas were mainly distributed in the Qaidam montane desert zone, the western and northern parts of eastern Qinghai-Qilian montane steppe zone, southern Qinghai high cold meadow steppe zone and Ngari montane desert-steppe and desert zone. The spatial distribution of correlation coeffi-cient between annual effective rainfall and annual maximum NDVI was similar to the growing season rainfall and annual maximum NDVI, and there was good relationship between NDVI and rainfall in the meadow and grassland with medium vegetation cover, and the effect of rainfall on vegetation was small in the forest and desert area.     

青藏高原植被覆盖变化与降水关系

The temporal and spatial changes of NDVI on the Tibetan Plateau, as well as the relationship between NDVI and precipitation, were discussed in this paper, by using 8-km resolution multi-temporal NOAA AVHRR-NDVI data from 1982 to 1999. Monthly maximum NDVI and monthly rainfall were used to analyze the seasonal changes, and annual maximum NDVI, annual effective precipitation and growing season precipitation (from April to August) were used to discuss the interannual changes. The dynamic change of NDVI and the corre- lation coefficients between NDVI and rainfall were computed for each pixel. The results are as follows: (1) The NDVI reached the peak in growing season (from July to September) on the Tibetan Plateau. In the northern and western parts of the plateau, the growing season was very short (about two or three months); but in the southern, vegetation grew almost all the year round. The correlation of monthly maximum NDVI and monthly rainfall varied in different areas. It was weak in the western, northern and southern parts, but strong in the central and eastern parts. (2) The spatial distribution of NDVI interannual dynamic change was different too. The increase areas were mainly distributed in southern Tibet montane shrub-steppe zone, western part of western Sichuan-eastern Tibet montane coniferous forest zone, western part of northern slopes of Kunlun montane desert zone and southeastern part of southern slopes of Himalaya montane evergreen broad-leaved forest zone; the decrease areas were mainly distributed in the Qaidam montane desert zone, the western and northern parts of eastern Qinghai-Qilian montane steppe zone, southern Qinghai high cold meadow steppe zone and Ngari montane desert-steppe and desert zone. The spatial distribution of correlation coeffi- cient between annual effective rainfall and annual maximum NDVI was similar to the growing season rainfall and annual maximum NDVI, and there was good relationship between NDVI and rainfall in the meadow and grassland with medium vegetation cover, and the effect of rainfall on vegetation was small in the forest and desert area.     

基于RS与GIS的三峡库区(重庆段)人居环境适宜性评价

To explore geographical differences in quantitative characteristics and spatial pat-tern of human settlements environmental suitability (HSES) in the Three Gorges Reservoir Area (TGRA),terrain,climate,hydrology,vegetation and other natural factors were selected to build the livable environmental evaluation,and the quantitative analysis was conducted through Remote Sensing(RS) and Geographic Informational System (GIS) to reveal geo-graphical characteristics and spatial patterns of HSES.The results are obtained as follows:(1) inhabitants of the TGRA of Chongqing are concentrated in the area with moderate high HSES,which is 78% of the total population distributed in 48% of the study area;(2) the HSES is closely related to the terrain,and it forms an arc-banded spatial succession pattern:relatively low in the northeast and the southeast while comparatively high in the west and the south;(3) large numbers of people are distributed in the area with low suitability (with higher population density than the average of the western China),but economic development level in these areas is quite low.Moreover,these areas are ecological sensitive and fragile,many kinds of eco-environmental problems have been caused by human activities.Therefore,population migration and layout are reasonable options for the development of these areas.     

Ecological changes and the tradeoff and synergy of ecosystem services in western China

Since the implementation of the Development of Western Regions in 2000, a series of major ecological construction projects have been implemented, leading to a series of changes in the ecological conditions and ecological services of western China. This study calculated the amount of ecosystem services in total in the western region from 2000 to 2019, and analyzed ecological changes and the characteristics of spatio-temporal variations in ecological services. A relevant analysis method was applied to explore the tradeoff and synergy of service. It was found that the area of settlements and wetland ecosystems in the western region increased significantly from 2000 to 2015, whereas grassland showed a downward trend year by year. The vegetation fraction showed a decreasing belt-like distribution from south to north. It showed a fluctuating increase during 2000 to 2019, with inter-annual and large spatial differences. The water conservation service (WCS) had a slight downward trend from 2000 to 2019, and the main decreasing areas were distributed in southeastern Tibet, the western part of the Three Rivers Source region, and the karst rocky desertification area. The soil conservation service (SCS) showed an increasing but fluctuating trend, with the greatest increases observed in the Loess Plateau region, western Sichuan and Yunnan, northwest Tibet, and southeast Tibet. The windbreak and sand fixation service (SFS) showed a downward trend, and the sharp decline was mainly in the central and western parts of Inner Mongolia, Tibet and parts of northern Xinjiang. Ecosystem supply and WCS, and SCS were mainly synergistic, which were found in areas north of the Qinling Mountains-Huaihe River (QM-HR) line, especially in Ningxia and Inner Mongolia. Ecosystem supply was mainly tradeoffs with SFS, and it was found in the agriculture-pastoral transition zone. The synergistic degree of ecosystem services in areas subjected to ecological engineering policy was greater than that in non-engineering areas. Quantitative assessment of ecosystem service changes and their tradeoffs is helpful for scientific ecological management and maximizing ecological benefits.     

Vegetation change in the Mt. Qomolangma Nature Reserve from 1981 to 2001

Based on the NOAA AVHRR-NDVI data from 1981 to 2001, the digitalized China Vegetation Map (1:1,000,000), DEM, temperature and precipitation data, and field investiga-tion, the spatial patterns and vertical characteristics of natural vegetation changes and their influencing factors in the Mt. Qomolangma Nature Reserve have been studied. The results show that: (1) There is remarkable spatial difference of natural vegetation changes in the Mt. Qomolangma Nature Reserve and stability is the most common status. There are 5.04% of the whole area being seriously degraded, 13.19% slightly degraded, 26.39% slightly im-proved, 0.97% significantly improved and 54.41% keeping stable. The seriously and slightly degraded areas, which mostly lie in the south of the reserve, are along the national bounda-ries. The areas of improved vegetation lie in the north of the reserve and the south side of the Yarlung Zangbo River. The stable areas lie between the improved and degraded areas. Degradation decreases with elevation. (2) Degeneration in the Mt. Qomolangma Nature Re-serve mostly affects shrubs, needle-leaved forests and mixed forests. (3) The temperature change affects the natural vegetation changes spatially while the integration of temperature changes, slopes and aspects affects the natural vegetation change along the altitude gradi-ents. (4) It is the overuse of resources that leads to the vegetation degeneration in some parts of the Mt. Qomolangma Nature Reserve.     

1981-2001年珠穆朗玛峰自然保护区植被变化

Based on the NOAA AVHRR-NDVI data from 1981 to 2001, the digitalized China Vegetation Map （1：1,000,000）, DEM, temperature and precipitation data, and field investigation, the spatial patterns and vertical characteristics of natural vegetation changes and their influencing factors in the Mt. Qomolangma Nature Reserve have been studied. The results show that： （1） There is remarkable spatial difference of natural vegetation changes in the Mt. Qomolangma Nature Reserve and stability is the most common status. There are 5.04% of the whole area being seriously degraded, 13.19% slightly degraded, 26.39% slightly improved, 0.97% significantly improved and 54.41% keeping stable. The seriously and slightly degraded areas, which mostly lie in the south of the reserve, are along the national boundaries. The areas of improved vegetation lie in the north of the reserve and the south side of the Yarlung Zangbo River. The stable areas lie between the improved and degraded areas. Degradation decreases with elevation. （2） Degeneration in the Mt. Qomolangma Nature Reserve mostly affects shrubs, needle-leaved forests and mixed forests. （3） The temperature change affects the natural vegetation changes spatially while the integration of temperature changes, slopes and aspects affects the natural vegetation change along the altitude gradients. （4） It is the overuse of resources that leads to the vegetation degeneration in some parts of the Mt. Qomolangma Nature Reserve.     

西部地区生态状况变化及生态系统服务权衡与协同

西部大开发战略实施20年以来,一系列重大生态建设工程使得西部地区的生态状况和生态服务发生了重要变化,本文分析西部地区生态状况变化及其生态服务时空变化特征,并运用相关分析法研究其服务功能权衡协同关系。研究发现西部地区2000—2019年间：① 聚落和湿地生态系统面积显著增加,草地有逐年下降趋势。② 植被覆盖度呈波动上升趋势,存在年际差异且空间差异较大。③ 水源涵养服务有轻微下降趋势,下降区域主要分布在藏东南地区、三江源西部地区、喀斯特石漠化地区等;土壤保持服务波动中呈上升趋势,上升区域主要黄土高原地区、川滇西部地区、藏西北地区、藏东南地区等;防风固沙服务呈下降趋势,大幅下降区域主要位于内蒙古中西部地区、西藏和北疆部分地区。④ 生态系统供给与水源涵养、土壤保持主要为协同关系,与防风固沙主要为权衡关系且分布在农牧交错带地区。⑤ 生态工程区内生态系统服务协同程度大于非工程区。定量评估生态系统服务变化及其权衡协同关系有助于进行科学化生态管理,最大化生态效益。