生产建设项目人为水土流失的生态环境损害评估
史东梅
1
,
蒋光毅
2,
郭宏忠
3,
彭旭东
4,
夏蕊
1,
张健乐
1
1. 西南大学资源环境学院, 400715, 重庆;
2. 重庆市水土保持监测总站, 401147, 重庆;
3. 重庆市水利局, 401147, 重庆;
4. 贵州大学林学院, 550025, 贵阳
收稿日期:2020-06-24; 修回日期:2020-10-13
项目名称:重庆市水利局科技项目"生产建设项目弃土弃渣水土流失规律研究"(2012-01);重庆市水利局科技项目"生产建设项目水土流失危害研究"(2013-01)
第一作者简介:史东梅(1970-), 女, 博士, 教授。主要研究方向: 土壤侵蚀与流域治理, 生产建设项目及土壤侵蚀与水土保持。E-mail:
shidm_1970@126.com
摘要:生产建设项目人为水土流失是典型的现代人为加速侵蚀。以人为水土流失危害为切入点,以生产建设项目各种扰动下垫面为研究对象,采用现场调查和原位观测方法对扰动地表与土壤植被进行研究分析,提出人为水土流失的生态环境损害评估程序及方法。结果表明:1)人为水土流失造成的生态环境损害主要以土壤结构和土地资源破坏,地表植被退化、局部地表汇流及地下水改变、生态系统服务功能下降以及在项目区及周边诱发洪水、滑坡、泥石流危险为主要表现特征。2)损害评估范式建立的关键环节有水土流失危害-生态环境基线及阈值判定、水土流失危害鉴定指标体系建立、生态环境损害因果关系分析、生态环境损害价值量化方法及标准。3)生产建设项目生态环境损害评估应重点关注工程堆积体在暴雨作用下人为崩塌、滑坡和泥石流灾害的危险性、局部地表汇流及地下水改变、硬化路(地)面对降雨径流调节与水源涵养能力的减弱等问题。研究结果可为生产建设项目人为水土流失的生态环境损害评估和生态环境恢复提供思路。
关键词:人为水土流失 生态环境损害 鉴定评估 水土流失危害 生产建设项目
Evaluation on eco-environmental damage of human-caused soil erosion for production and construction projects
SHI Dongmei
1,
JIANG Guangyi
2,
GUO Hongzhong
3,
PENG Xudong
4,
XIA Rui
1,
ZHANG Jianle
1
1. College of Resources and Environment, Southwest University, 400715, Chongqing, China;
2. Chongqing Soil and Water Conservation Monitoring Station, 401147, Chongqing, China;
3. Chongqing Municipal Water Resources Bureau, 401147, Chongqing, China;
4. College of Forestry, Guizhou University, 550025, Guiyang, China
Abstract: [Background] Human-caused soil erosion in production and construction projects is a typical modern accelerated erosion type by human-being. For different production and construction projects, there exists an internal and necessary relationship between human-caused soil erosion and eco-environmental damage where express great differences among disturbed geomorphic units, soil erosion characteristics and hazards. [Methods] Taking various disturbed underlying surfaces of production and construction projects as examples, we studied the characteristics of disturbed surface, soil and vegetation by field investigation and in-situ observation methods, and put forward an evaluation paradigm of eco-environmental damage human-caused soil erosion from the view of hazards of human-caused soil erosion. Economic methods of soil and water conservation were used to calculate the value of eco-environmental damage, and two cases were also used to verify this procedure. [Results] 1) Eco-environmental damage from human-caused soil erosion manifest the destruction of soil structure and land resources, degradation of land vegetation, changes of water resources circulation system, decline of ecosystem service functions and the increasing risk of rain-induced floods, landslides, and debris flows. 2) The key links for the evaluation system of eco-environmental damage include 4 aspects such as the judgment on soil and water damage and eco-environmental thresholds, establishment of an index system for identification of soil erosion hazards, causal link analysis of eco-environmental damage, and quantification methods and standards for the value of eco-environmental damage. The damage degree to ecological function of disturbed landform in real estate construction project sorted by loose engineering accumulation > slope green belt > construction access road. 3) The eco-environmental damage for mining projects are the destruction of surface groundwater circulation system, artificial landslide occurred in accumulation body rain-induced conditions. Damage for real estate construction projects is the collapse of high and steep slopes, destruction of topsoil structure and nutrients, decrease of water conservation function caused by increased hardened pavement, etc. The value of soil environmental loss for mining projects and real estate construction projects accounted for 77.27% and 60.35% separately. [Conclusions] The paper may provide some appraisal ideas and methods for evaluation of eco-environmental damage human-caused soil erosion. Furthermore, eco-environmental damage induced from production and construction projects mainly focus on man-made collapses, rain-induced landslides, regulation of runoff on hardened road, water retention function and destruction of the groundwater circulation system especially, which can provide some practical support for damage evaluation and ecological restoration.
Keywords:
human-caused soil erosion eco-environmental damage evaluation hazards of soil erosion production and construction project
经调查“十五”期间全国生产建设项目数量达7万6 810个,其中数量最多的为城镇建设项目;近17年间水利行政主管部门每年审批的生产建设项目数量逐年递增[1]。生产建设项目水土流失主要造成水土资源和土地生产力的破坏和损失,包括生产建设项目具有侵蚀空间有限、时期较短、侵蚀类型复杂、危害严重等特征[2-3]。从水土保持领域的视角出发[4-5],人为水土流失造成的生态环境损害表现为土地资源及地表植被、水资源、水土保持设施与水土保持功能、生态系统服务功能以及项目区周边环境的破坏。李发鹏等[6]借鉴当前生态环境损害概念,界定了领域水土资源损害内涵,为水土保持领域生态环境损害评估提供支撑。姜德文[7]认为水土流失影响度是生产建设项目水土保持损益分析的核心内容,基于综合评价模型可定量计算出项目水土流失对生态环境损害的影响。甘枝茂等[8]分析城镇建设生态环境损害以土体破坏、地表土壤入渗性能减弱和生态系统服务功能损害为主。而我国对于不同生产建设项目人为水土流失的生态环境损害评估鲜有报道。笔者以生产建设项目人为水土流失危害为切入点,分析项目建设期、运行期生态环境损害特征,提出人为水土流失的生态环境损害评估范式并通过评估案例验证评估范式的科学性,为人为水土流失的生态环境损害评估提供鉴定思路,对生态环境恢复具有实践意义。
1 人为水土流失生态环境损害表现特征
生产建设项目水土流失以人类生产活动为外营力产生的水土流失类型,是典型的现代人为加速侵蚀,它与原地貌水土流失既有联系,也有自身特性。生态环境损害表现特征,总体以生态破坏为主,水土流失对象包含自然土和人工土,煤矿开采工程项目中排放的废水废气还会引起环境污染。各生产建设项目类型不同,扰动地貌单元、水土流失特征和危害也有较大差异。人为水土流失与生态环境损害的逻辑关系分析见表 1。
表 1(Tab. 1)
表 1 人为水土流失与生态环境损害逻辑关系分析
Tab. 1 Analysis of logical relationship between human-caused soil erosion and eco-environmental damage
项目类型
Type of project |
扰动地貌单元
Disturbed geomorphic unit |
水土流失危害
Hazards of soil erosion |
生态环境损害评估变量
Assessment variables of eco-environmental damage |
城镇建设[8-11]
Construction of city and town[8-11] |
弃土弃渣场、人工边坡、边坡绿化带、场地硬化、施工便道
Waste soil and residue site, artificial slope, slope green belt, site hardening, and construction access road |
人为开挖地面、倾倒废弃固体直接产生侵蚀与流失,废渣弃石堆积降低土壤蓄水与渗透能力,土壤调节地表径流量减弱,城市化建设期间土壤侵蚀速率是农田的10~350倍、森林地区的1 500倍;房地产项目建设增加不透水面积,巨大雨水径流直接排入市政雨水管网径流系数和产流量相应增大,如北京市不透水建筑物屋顶雨水径流占总雨水径流38.2%
Excavating the ground artificially and dumping the waste solids will cause soil erosion, and accumulation of waste slag and abandoned rocks will reduce the ability of water conservation and penetration and of soil regulating surface runoff. The soil erosion rate is 10-350 times that of farmland, 1 500 times that of forest area during urbanization. The real estate construction projects increase the impervious area, causing stormwater runoff directly discharged into the municipal rainwater pipe network. For example, the rainwater runoff on the roof of impervious buildings in Beijing accounts for 38.2% of the total |
土石方挖填总量、弃土弃渣量、工程占地面积、弃土弃渣边坡失稳危害、土壤入渗率等
Total excavation and filling of cubic meter of earth and stone, amount of waste soil and residue, disturbed ground surface area, instability hazards of waste soil and residue slope, soil infiltration rate, etc. |
矿山开采[12]
Mining[12] |
弃土弃渣场、弃渣场边坡、开挖边坡、煤炭转运场、塌陷区、土地复垦区
Waste soil and residue site, slope of slag site, excavated slope, coal transfer site, subsidence area, and land reclamation area |
破坏植被和土壤结构,产生大量弃土石方,严重影响产流产沙量;建设废弃物污染当地水质(含汞、铅等有害物质注入当地水系),不能饮用、灌溉;矿区土质道路易造成细沟发育,如准格尔露天煤矿投产以后弃土石方2.8亿m3,产沙率和输沙量比无采矿区增大10倍以上
Destroying vegetation and soil structure, resulting in a large amount of waste soil and residue, both seriously affect runoff and sediment production. Construction waste contaminates the local water quality (hazardous substances such as mercury and lead are injected into the local water system) and the local water cannot be drunk or irrigated. The roads in mining area are prone to develop rill erosion, for example, after the Zhungeer Open-pit Coal Mine was put into operation, the earthwork was 280 million m3, and the sand production rate and the amount of sand transport increased by 10 times of that in non-mining area |
土石方挖填总量、弃土弃渣量、细沟侵蚀量、上游洪水淹没危害、植被覆盖率变化等
Total excavation and filling of cubic meter of earth and stone, amount of waste soil and residue, amount of rill erosion, upstream flood inundation hazards, changes in vegetation coverage, etc. |
道路建设[13-15]
Construction of road[13-15] |
弃土弃渣场、采石取土场、路基工程、施工便道、生产生活区
Waste soil and residue site, quarry site, subgrade engineering, construction access road, and production and living area |
破坏原地形地貌和植被状况,形成大量裸露边坡,混合侵蚀作用下易形成滑坡、泥石流,直接影响道路沿线生产生活安全;开挖、回填、碾压等建设活动,扰乱地表和原有地下水文系统,公路项目建设中弃渣量达1.4万t/km2,总量达42.4亿t;细沟侵蚀发育,阻碍坡面绿化和坡面复垦,如高速公路弃土场边坡雨季产生沟蚀量高达9 779.55 t/km2
Destroying the original landforms and vegetation, forming huge exposed slopes, developing landslides and debris flows under the mixed erosion, all odirectly affect the safety along the road. Excavation, backfilling, rolling, etc. will disturb the surface ground and the original underground hydrological system. The amount of waste slag in highway projects reaches 14 000 t/km2, and the total amount reaches 4.24 b×109 t. The rill erosion hinders the development of slope greening and reclamation, such as the gully erosion amount in highway waste soil and residue site is as high as 9 779.55 t/km2 |
植被覆盖率变化、土石方挖填总量、弃土弃渣量、弃土弃渣边坡失稳危害、工程占地面积等
Changes in vegetation coverage, total excavation and filling of cubic meter of earth and stone, amount of waste soil and residue, instability hazards of accumulation body slope, disturbed ground surface area, etc. |
水利工程[16]
Hydraulic engineering[16] |
主坝工程区、建筑物工程区、引河工程建设区、土料场区、排泥场区
Main dam project area, building project area, river diversion construction area, soil site, and sludge site |
工程扰动地表强度大,毁坏地表植被,降低土壤抗蚀抗冲性;土石方挖填数量大,堆积体数量多,产生废水废渣影响下游水资源;库区土壤盐碱化、沼泽化等引起植物生理干旱;破坏原生地表、山坡稳定性,占用农耕用地,如恩施小河水电站新增侵蚀量1.459万t,年平均侵蚀量0.775万t
The projects disturbe the surface ground greatly, destroye the vegetation, and reduce soil corrosion resistance. There are huge amount of cubic meter of earth and stone and accumulation body. The generated waste water and slag affect the downstream water. Salinization and basification of soil in the reservoir cause plant physiological drought. The stability of original surface is destroyed. For example, the new erosion amount of Enshi Xiaohe Hydropower Station was 14 590 t, and the average annual erosion amount was 7 750 t |
土石方挖填总量、工程占地面积、建设总工期、林草地减少面积等
Total excavation and filling of cubic meter of earth and stone, disturbed ground surface area, construction period, forest and grassland reduction area, etc. |
|
表 1 人为水土流失与生态环境损害逻辑关系分析
Tab. 1 Analysis of logical relationship between human-caused soil erosion and eco-environmental damage
|
综合分析生产建设项目水土流失的危害其造成生态损害主要表现为:1)破坏水土资源及地表植被。生产建设项目开挖、占压土地直接造成土壤位移和地表物质组成改变,土壤养分降低,土地生产力下降;改变原有水系的自然条件和水文特征,地表径流增大,土壤压实使土壤空隙萎缩,造成城市洪水与内涝威胁;生产建设活动清除地表覆盖物,使植被覆盖度降低,为水土流失创造条件。2)破坏生态系统服务功能及项目区周边环境。生产建设项目临时性或永久性占用土地、减少耕地林草地面积,削弱项目区生态系统服务功能及水土保持设施水源涵养功能;工程堆积体细颗粒松散堆积物,在风蚀区极易浮尘、扬沙等沙尘现象,在水蚀区由于强降雨诱发作用极易引发滑坡、泥石流等重力侵蚀现象,造成社会经济损失和人居环境质量下降。3)由于生产建设项目水土流失危害及扰动地貌单元差异较大,可选择生产建设项目对生态环境损害中的共性影响因素作为生态环境损害评估的主要参数,有土石方挖填总量、工程堆积体量、工程占地面积、水土保持设施数量。
2 人为水土流失生态环境损害评估程序及方法
2.1 损害评估程序解析
生态环境损害评估通过污染环境或破坏生态行为与生态环境损害之间的因果关系分析,评估污染环境或破坏生态行为所致生态环境损害的范围和程度,确定生态环境恢复至基线并补偿期间损害的恢复措施,量化生态环境损害数额的过程[5]。生产建设项目人为水土流失的生态环境损害评估程序如图 1所示。在以上程序中,关键评估环节是水土危害-生态环境基线及阈值判定、水土流失危害鉴定指标体系建立、生态环境损害因果关系分析和量化损害价值。水土流失危害特征确定及基线判定是在收集分析破坏生态行为资料、开展现场勘查、掌握生态损害基本情况后,研判项目区人为水土流失生态损害特征;生态环境基线判定主要采用历史数据调查、对照区域数据比较和模型推导3种方法[17]。根据各类生产建设项目造成的损害特点及危害范围、程度的差异性,分类筛选具有代表性和可操作性的损害评估指标,利用生态环境恢复方式进行经济补偿时,应保持恢复目标采用指标与损害评估指标的一致性。
2.2 损害价值评估方法
生产建设项目的生态环境损害往往以经济损失来衡量,由受损资源的恢复成本和损失费用或生态功能损失补偿费组成[18]。在评估时,可将生态环境损害评价指标(表 2)进行实物量化,再根据实物量采用水土保持经济学中经济损失计算方法进行价值估算。生态环境损害分为水土资源直接经济损失和生态系统服务功能损失,可利用直接换算法(实物、货币或能值)、置换成本法、影子工程法、陈述偏好法、综合函数贡献法等评估方法进行估算。水土资源直接经济损失包括土壤环境损害价值、土壤养分流失价值、土壤有机质流失价值、涵养水源价值和植被恢复费用等,生态服务功能经济损失包括林草场退化价值、土地占用价值、土地生态价值损失、水土保持补偿费等。生态环境损害价值评估方法及实参数表征意义,各评估方法和参数含义见表 2。
表 2(Tab. 2)
表 2 生态环境损害价值评估方法及参数表征意义
Tab. 2 Evaluation method of the value of eco-environmental damage and significance of parameter representation
损害价值分类[18-19]
Classification of damage value |
评估方法
Method of evaluation |
计算方法
Method of calculation |
参数表征意义
Significance of parameter representation |
土壤环境损害价值
Value of soil environmental damage |
恢复费用法
Restoration cost method |
Ef=Ba+T+Ma+G |
Ef为恢复费用;Ba为恢复方案编制费用;T为工程建设费用;Ma监测检测费;G后期监管费用
Ef is restoration cost; Ba is preparation cost of the restoration plan; T is construction cost; Ma is monitoring and inspection cost; and G is post-supervision cost |
土壤养分流失价值
Value of soil nutrient loss |
市场价值法
Market value method |
En=∑ZiSiCiPi |
En为养分流失所损失价值;Zi为土壤侵蚀总量;Si为土壤中有效氮、磷、钾折算为硫酸铵、过磷酸钙、氯化钾的系数;Ci为土壤中有效氮、磷、钾含量;Pi为硫酸铵、过磷酸钙、氯化钾化肥的价格
En is the value of nutrient loss; Zi is total amount of soil erosion; Si is coefficient of conversion of available nitrogen, phosphorus and potassium into ammonium sulfate, superphosphate and potassium chloride; Ci is the available nitrogen, phosphorus and potassium in soil content; Pi is the price of ammonium sulfate, superphosphate and potassium chloride fertilizer |
土壤有机质流失价值
Value of soil organic matter loss |
市场价值法
Market value method |
Eo=ZjCjPj |
Eo为有机质经济损失;Zj为土壤侵蚀总量;Cj为土壤中有机质平均含量;Pj为有机质价格
Eo is the value of organic matter loss; Zj is the total amount of soil erosion; Cj is the average content of organic matter; Pj is the price of organic matter |
涵养水源价值量
Value of water conservation |
影子工程法
Shadow engineering method |
Eb=(ZkF/Bb)Qm |
Eb为涵养水源价值;Zk为研究区年总侵蚀量;F为涵养水源量;Bb为平均土壤密度;Qm为地方水价
Eb is the value of water conservation; Zk is the total annual erosion; F is the amount of water conservation; Bb is the average soil bulk density; Qm is local water price |
植被恢复费用
Cost of vegetation restoration |
市场价值法
Market value method |
Ck=SlPk |
Ck为植被恢复费用;Sl为植被恢复面积;Pk为单位面积恢复费用
Ck is vegetation restoration cost; Sl is vegetation restoration area; Pk is unit restoration cost |
林草场退化价值
Value of forestland or grassland degradation |
陈述偏好法、市场价值法
Stated preference method and market value method |
${C_1} = \sum\limits_{j = 1}^m {{A_j}} k{B_j}$ |
Cl为草地资源年m种功能损害经济损失;Aj为j功能单位面积实物量;k为再生系数;Bj为j功能的年均资源破坏量
Cl is the economic loss of m kinds of functional damages in grassland resources; Aj is the amount of per unit area of j function; k is the regeneration coefficient; Bj is the annual average amount of resource destruction of j function |
土地占用价值
Value of land occupation |
市场价值法
Market value method |
Em=SmBcY |
Em为每年土地占用价值;Sm为土地占用面积;Bc为每年的土地机会成本;Y为施工建设年限
Em is the value of annual land occupation; Sm is the land occupation area; Bc is the annual land opportunity cost; and Y is the construction period |
作物减产损失
Value of crop yield loss |
市场价值法
Market value method |
${E_{\rm{q}}} = \sum\limits_i {\sum\limits_i {{q_{ij}}} } {p_i}$ |
Eq为作物减产的经济损失;pi为单元i生产物的市场价格;qij为单元i中各类侵蚀强度下作物减产量
Eq is value of crop yield loss; pi is the market price of the product of unit i; qij is the crop yield reduction under various erosion intensity in unit i |
土地生态价值损失量
Value of land ecological loss |
条件价值法
Contingent value method |
Ev=ΔSnPo |
ΔSn为土地向建设用地转化面积;Po为生态系统服务功能单价;Ev为土地生态价值损失量
ΔSn is the area converted from land to construction land; Po is the unit price of ecosystem services functions; Ev is the value of amount of land ecological loss |
水土保持补偿费
Compensation for soil and water conservation |
市场价值法
Market value method |
Ep=Mcv |
Ep为水土保持补偿费;Mc为弃渣量;v为每立方米弃渣收取标准
Ep is the compensation for soil and water conservation; Mc is the amount of abandoned slag; v is the standard price for abandoned slag per m3 |
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表 2 生态环境损害价值评估方法及参数表征意义
Tab. 2 Evaluation method of the value of eco-environmental damage and significance of parameter representation
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3 人为水土流失生态环境损害实证研究
3.1 矿山开采项目生态环境损害分析
重庆市某采矿项目,采用人工爆破、穿山凿洞等方式进行井下开采,造成的生态环境损害有采矿过程中扰动地表或地下岩土层,山体内部形成大量采空区和临空面,塌陷区面积达矿区范围约120%,导致矿区附近地表塌陷、房屋损坏;工程堆积体在降雨条件下易引发人为崩塌、人为滑坡等灾害,对河流行洪能力造成影响;涵养水源功能及土地生产力受损。由于爆破、机械震动和采空对岩体结构(尤其是保水层)的破坏,造成地下水量逐年减少、水井干枯、旱地缺水致荒废、土地产出能力锐减。项目占地面积为0.53 km2,直接影响区面积为0.75 km2,对当地生态环境影响区域高达1.38 km2,是项目区面积的2倍多;采矿与矿区附近地表塌陷、地下水枯竭、土地生产力下降、房屋损坏等有直接因果关系。采用土地生态价值损失估算模型评估土地生态价值损失量,通过土壤养分流失价值评估土地生产功能价值进行,按市场价值法计算林场退化损失价值,弃渣尾矿规范化处理按GB 50433—2018《生产建设项目水土保持技术标准》临时防护工程标准评估,该生产建设项目的损害价值如图 2所示。
可知矿山开采生态环境损害价值总量为357.2万元,土地生态价值和弃渣尾矿处理分别为276万和45万元,占损害价值总量77.27%和12.60%。说明:一矿山开采项目的生态环境损害以地表地下水循环系统破坏及排土场、矸石场、尾矿库等工程堆积体人为崩塌、人为滑坡危害为主;二采矿对项目区及周边区域危害影响大,要特别关注暴雨期人为水土流失威胁下游人民生命财产安全;三采矿项目造成的土地生态价值损失严重,要利用好第三方机构评估,严格水土保持监测过程,将人为水土流失造成的生态环境损害和社会经济损害降至最低。
3.2 房地产项目生态环境损害分析
重庆市某房地产项目占地面积3万2 805 m2,工期为2.5年。野外调查发现,各扰动地貌单元的土壤物理性质均与原地貌单元有较大差异,土壤密度表现为施工道路(1.83 g/cm3)>松散堆积体(1.68 g/cm3)>边坡绿化带(1.54 g/cm3),与天然林地相比分别增加38.64%、27.27%、16.67%。生态环境损害主要表现为破坏项目区水土资源,硬化路面影响城市地表排洪系统;建造过程中钢筋混凝土的加工、墙体砌筑,土壤结构破坏、不透水面积增大、入渗率降低,易引发城市水土流失;大量土方工程涉及基础开挖、现浇砌筑,高陡边坡、工程堆积体在雨季易诱发人为崩塌、人为滑坡等灾害,对项目区及周边生态环境造成负面影响。项目建设对项目区水土资源、生态系统功能及水土保持设施破坏等有直接因果关系,根据项目区相似条件未破坏参考区域数据确定生态环境损害评估基线,生态环境损害价值评估需从土地生态价值损失量、涵养水源价值量、土壤环境损害价值、水土保持补偿费等方面估算(图 3)。
可知房地产建设项目造成的生态环境损害价值总额为75.56万元,生态损害价值最多的是土壤环境损害价值(45.6万元),占60.35%,其余依次为涵养水源价值(17.27万元)、水土保持补偿费(6.79万元)和土地生态价值(5.9万元),项目区硬化路面增加,部分裸露场地土壤被显著压实,没有良好的表层透水孔隙,暴雨时易发生地表径流,难以发挥土壤蓄水渗水作用。说明:一房地产项目造成生态环境损害以高陡边坡崩塌、表土土壤结构及养分破坏、硬化路面增加导致的水源涵养功能下降为主要表现;二房地产建设项目扰动地貌单元生态功能损害程度依次为松散堆积体>边坡绿化带>施工便道,应关注表土保护利用问题以及工程堆积体在暴雨径流作用下人为崩塌、人为滑坡对交通与居民生活的影响;三房地产建设项目中土壤环境损害价值占比最多,但可通过景观绿化对生态环境恢复,项目完成后基本不产生新增水土流失。
4 结论
1) 生产建设项目人为水土流失生态环境损害主要表现为破坏项目区水土资源、地表植被及生态系统服务功能和周边生态环境、人居环境质量,工程堆积体在暴雨作用下极易诱发崩塌、滑坡、泥石流等重力侵蚀,损害评估重要参数有土石方量、工程堆积体量、工程占地面积、水土保持设施破坏数量等。
2) 生态环境损害评估的关键环节有水土流失危害-生态环境基线及阈值判定、水土流失危害评估指标体系建立、生态环境损害因果关系分析和生态环境损害价值量化方法及标准;生态环境损害价值的评估方法有直接换算法(实物、货币或能值)、置换成本法、陈述偏好法、综合函数贡献法等。水土资源直接经济损失包括土壤环境损害价值、土壤养分流失价值、涵养水源价值、植被恢复费用等,生态服务功能经济损失包括林草场退化价值、土地占用价值、土地生态价值损失、水土保持补偿费等。
3) 采矿项目生态环境损害以局部地表汇流及地下水改变、降雨条件下的排土场、矸石场等工程堆积体的人为滑坡和人为泥石流潜在危险性为主,土地生态价值和弃渣尾矿处理分别占损害价值总量77.27%、12.60%。房地产项目生态环境损害以高陡边坡崩塌、表土土壤结构破坏及养分丧失、硬化路面增加导致的水源涵养功能下降为主,土壤环境损害价值占损害价值总量60.35%。
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2021, Vol. 19 
表1(Table 1)
