技术

Conservation agriculture for maize-legume systems with velvet bean as a dense cover crop [肯尼亚]

创建： 05/31/2020 1:49 a.m.
更新： 08/10/2020 9:51 a.m.
编制者： Kennedy Were
编辑者： –
审查者： Rima Mekdaschi Studer, Tatenda Lemann

Kilimo hifadhi

technologies_5775 - 肯尼亚

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完整性： 90%

1. 一般信息

1.2 参与该技术评估和文件编制的资源人员和机构的联系方式

关键资源人

有助于对技术进行记录/评估的项目名称（如相关）

GEF-UNEP-AGRA-KALRO SLM Project

有助于对技术进行记录/评估的项目名称（如相关）

Carbon Benefits Project (CBP)

有助于对技术进行记录/评估的机构名称（如相关）

Kenya Agricultural and Livestock Research Organization (KALRO) - 肯尼亚

1.3 关于使用通过WOCAT记录的数据的条件

编制者和关键资源人员接受有关使用通过WOCAT记录数据的条件。:

是

1.4 所述技术的可持续性声明

这里所描述的技术在土地退化方面是否存在问题，导致无法被认为是一种可持续的土地管理技术？:

否

2. SLM技术的说明

2.1 技术简介

技术定义:

Conservation agriculture for maize-legume systems with velvet bean (Mucuna pruriens) as a dense cover crop is being promoted in western Kenya to address the challenges of land degradation, low crop yields, low incomes, high production costs and climate change.

2.2 技术的详细说明

说明:

Agriculture in western Kenya suffers from low productivity due to the degraded landscape. The soils are predominantly acidic and low in fertility, with the yields of food staples, such as maize and common bean averaging 1 ton/ ha and 5 tons/ ha, respectively. Consequently, the smallholder farmers have encroached into the adjacent Kakamega and Nandi forests in their quest for supplementary agro-ecosystem services and farm incomes. Degradation of the agro-resource base is underpinned by unsustainable practices carried out under conventional farming; for example, continuous cultivation with low nutrient inputs, mono-cropping, removal of crop residues and full tillage. Some of these practices enhance climate change by intensifying the emissions of greenhouse gases, such as carbon dioxide (CO2) into the atmosphere. Therefore, widespread adoption of conservation agriculture (CA) technology is being promoted to reduce the adverse impacts of conventional farming and enhance sustainable land management, environmental protection, and climate change mitigation and adaptation in 10 micro-catchments located within a 5-km radius from the edge of Kakamega and Nandi forests. The CA technology is characterized by the principles of minimum mechanical soil disturbance, maintenance of at least 30 percent permanent organic soil cover, diversified cropping through intercropping and crop rotations, and weed control. These principles have been adapted to the local conditions and needs.

The establishment of CA technology begins with land preparation. That is, the existing weeds and previous crop residues in the field are either slashed, or controlled through the application of appropriate herbicides. All the residues are retained on soil surface as opposed to burning, or removal in the conventional system. Land preparation is followed by planting, where the jab planter is used for precise placement of seeds and fertilizers in un-ploughed field, or within the established planting hills and rip lines to minimize soil tillage. This contrasts with conventional farming practice where a plough, or a hand hoe is used to till the entire field and establish the planting holes for placing seeds and fertilizers. A combination of cereal (maize – Zea mays L.) and legumes (common bean – Phaseolus vulgaris L., soybean - Glycine max, velvet bean – Mucuna pruriens and cowpea – Vigna unguiculata) are either intercropped, or rotated in the field each season to optimize the use of the available soil resources, including water, nutrients, and micro-organisms. The main cereal-legume association involves the establishment of Mucuna pruriens under maize as a dense cover crop. In this cropping system, Mucuna pruriens seeds are sown within a spacing of 1 m × 0.5 m where they grow and spread to completely cover the soil surface. As the cover crop grows, the leaves fall and decompose on the ground, enriching the soil’s nutrients, organic matter and fertility. The maize - Mucuna pruriens mix is rotated with either sole common bean, soybean and cowpea crop, or an intercrop of maize with any of the legumes. Weeding is carried out using either selective herbicides, or weed scrapers. When designing the intercropping and rotation plans, crop families (N-fixing vs. non-fixing), root depths (shallow vs. deep roots), and susceptibility to diseases, pests and weeds are all considered.

Generally, CA technologies have multiple benefits for farmers and the environment. In the context of the Kakamega-Nandi forest landscape, the CA plots with Mucuna pruriens as a dense cover crop have shown improved soil organic matter, soil structure and nutrient status. It is expected that this will reduce the use of fertilizers over time. Most farmers have also reported that reduced tillage and direct placement of inputs (seeds and fertilizers) save them time, money, fuel, labour and inputs. Aside from saving resources, reduced tillage will ultimately enhance soil living organisms and mitigate atmospheric CO2 emissions through the decrease in fuel consumption and soil disturbance. Moreover, farmers have observed that the maize established with Mucuna pruriens as a cover crop remains green and healthy for long during mid-season dry spells compared to those under mono-culture, or light mulch. This implies that the CA technology also increases water infiltration and soil water content; thus, acting as insurance against drought. The increase in water infiltration and soil moisture occurs because the dense Mucuna pruriens cover crop not only regulates the soil surface temperatures and evaporation, but also reduces surface runoff and exposure to wind erosion. In addition, farmers have witnessed the suppression of weeds, such as Striga hermonthica (witchweed) in plots under dense cover crop and diversified cropping. Besides, diversified cropping through rotations has reduced the incidences of insect pests and diseases, as well as the risk of crop failure during extreme weather conditions and pest infestations. Specifically, farmers have noticed that the CA plots under maize - Mucuna pruriens intercrop are less affected by the fall armyworm (Spodoptera frugiperda) compared to those under mono-culture. They have also noted that, in seasons of excessive rainfall, the maize intercropped with the common bean is usually harvested even when the common bean fails. Most importantly, these CA benefits have boosted maize yields by over 50 percent, meaning more food and income, and fewer forest encroachments.

Proper adoption of the CA technology by land users within the Kakamega-Nandi forest landscape is being hampered by several factors. Firstly, crop residues are inadequate due to competing uses, such as animal feed and fuel. At times, livestock is even allowed to graze on the stubble field, contravening the CA principles. Besides, some farmers have not fully embraced crop diversification and still grow maize throughout the seasons without rotation with other drought-tolerant cereals, such as sorghum and millet. Conventional ploughing is also quite entrenched. Further, some farmers still do not prefer Mucuna pruriens as a cover crop because of insufficient knowledge on the utilization of its inedible yields. Lastly, some farmers are finding it hard to access CA inputs and tools, such as the jab planters, weed scrapers, herbicides and seeds of Mucuna pruriens owing to either high prices, or shortages.

2.3 技术照片

媒体库

2.4 技术视频

2.5 已应用该技术的、本评估所涵盖的国家/地区/地点

国家:

肯尼亚

区域/州/省:

Western region

有关地点的进一步说明:

Kakamega-Nandi forest landscape

具体说明该技术的分布:

适用于特定场所/集中在较小区域

技术现场是否位于永久保护区？:

否

2.6 实施日期

注明实施年份:

2019

2.7 技术介绍

详细说明该技术是如何引入的:

在实验/研究期间
通过项目/外部干预

注释（项目类型等）:

Projects and research focusing mainly on advancing land degradation neutrality and agricultural productivity in the area

3. SLM技术的分类

3.1 该技术的主要目的

改良生产
减少、预防、恢复土地退化
保持/提高生物多样性
减缓气候变化及其影响
创造有益的经济影响

3.2 应用该技术的当前土地利用类型

同一土地单元内混合使用的土地：:

是

具体说明混合土地使用（作物/放牧/树木）:

农牧业（包括农牧结合）

农田

一年一作

年作 - 具体指明作物:

谷物类 - 玉米
豆科牧草和豆类 - 豆子
豆科牧草和豆类 - 豌豆
豆科牧草和豆类 - 大豆

年作制度:

玉米/高粱/谷子与豆类间作

每年的生长季节数:

具体说明:

Long rain season (March to May) and short rain season (October to December)

采用间作制度了吗？:

是

如果是，说明哪些作物是间作的:

Maize and legumes (i.e., common bean, soybean and velvet bean – Mucuna pruriens)

采用轮作制度了吗？:

是

如果是，请具体说明:

Maize and legumes (i.e., common bean, soybean and velvet bean – Mucuna pruriens)

牧场

集约放牧/饲料生产:

收割和携带/零放牧
改良牧场

动物类型:

cattle - dairy and beef (e.g. zebu)

是否实行作物与牲畜的综合管理？:

是

如果是，请具体说明:

Manure is used for fertilization and crop residues are used as cattle feed

产品和服务:

manure as fertilizer/ energy production
肉类
奶类
外皮/兽皮
交通工具/役畜

3.3 由于技术的实施，土地使用是否发生了变化？

由于技术的实施，土地使用是否发生了变化？:

是（请在技术实施前填写以下有关土地利用的问题）

同一土地单元内混合使用的土地：:

是

具体说明混合土地使用（作物/放牧/树木）:

农牧业（包括农牧结合）

农田

一年一作

年作 - 具体指明作物:

谷物类 - 玉米

年作制度:

连作玉米/高粱/谷子

采用间作制度了吗？:

否

采用轮作制度了吗？:

否

牧场

集约放牧/饲料生产:

收割和携带/零放牧

动物类型:

cattle - dairy and beef (e.g. zebu)

是否实行作物与牲畜的综合管理？:

是

如果是，请具体说明:

Manure is used for fertilization and crop residues are used as cattle feed

产品和服务:

manure as fertilizer/ energy production
肉类
奶类
外皮/兽皮
交通工具/役畜

3.4 供水

该技术所应用土地的供水:

雨养

3.5 该技术所属的SLM组

改良的地面/植被覆盖
最小的土壤扰动
土壤肥力综合管理

3.6 包含该技术的可持续土地管理措施

农艺措施

A1：植被和土壤覆盖层
A2：有机质/土壤肥力
A3：土壤表面处理
A6：残株管理

A3：区分耕作制度:

A 3.2: Reduced tillage (> 30% soil cover)

A6：对残株管理作出具体说明:

A 6.4：保留

3.7 该技术强调的主要土地退化类型

土壤水蚀

Wt：表土流失/地表侵蚀

土壤风蚀

Et：表土流失

化学性土壤退化

Cn：肥力下降和有机质含量下降（非侵蚀所致）

物理性土壤退化

Pc：压实

生物性退化

Bl：土壤寿命损失

水质恶化

Ha：干旱化

3.8 防止、减少或恢复土地退化

具体数量名该技术与土地退化有关的目标:

减少土地退化

4. 技术规范、实施活动、投入和成本

4.1 该技术的技术图纸

技术规范（与技术图纸相关）:

The first technical drawing shows a typical farm under CA with various principles:
A - Clearance of weeds and previous crop residues through slashing in preparation for planting in season 1 (long rains). The residues are retained on the plot.
B - In a plot under total soil cover with Mucuna pruriens, maize seed and fertilizer are placed at the precise planting hills, denoted by the white circles along the red line, using a jab planter to minimize soil tillage.
C - Maize crop establishes under the dense cover of Mucuna pruriens.
D - Weeding of the maize crop is done using a weed scraper.
E & F - In season 2 (short rains), after harvesting maize in the previous maize – Mucuna cropping system and cutting down the residues, either a row intercropping system with alternate rows of maize and soybean (E), or maize and common bean (F) under maize straw mulch is established.
G & H - Alternatively, in season 2 (short rains), either sole common bean (cowpea, or soybean) production under maize straw mulch (G), or total soil cover with Mucuna pruriens (H) is established in the plot.

作者:

Sam Koile, Kennedy Were & George Ayaga

日期:

31/05/2020

技术规范（与技术图纸相关）:

The second technical drawing is an illustration of a four season (2-year) rotation of maize, legumes and cover crop

作者:

Kennedy Were, Sam Koile & George Ayaga

日期:

15/07/2020

4.2 有关投入和成本计算的一般信息

具体说明成本和投入是如何计算的:

每个技术区域

注明尺寸和面积单位:

1 ha

如果使用本地面积单位，注明转换系数为1公顷（例如1公顷=2.47英亩）：1公顷=:

2.47 acres

其它/国家货币（具体说明）:

KES

如相关，注明美元与当地货币的汇率（例如1美元=79.9巴西雷亚尔）：1美元=:

107.08

注明雇用劳工的每日平均工资成本:

300

4.3 技术建立活动

	活动	时间（季度）
1.	Purchase of CA tools - jab planter, knapsack sprayer, protection gear, slasher, weed scraper, and gunny bag)	Initial stage

4.4 技术建立所需要的费用和投入

	对投入进行具体说明	单位	数量	单位成本	每项投入的总成本	土地使用者承担的成本%
设备	Jab planter	Piece	2.0	1500.0	3000.0	100.0
设备	Knapsack sprayer	Piece	2.0	2500.0	5000.0	100.0
设备	Protection gear	Piece	2.0	1000.0	2000.0	100.0
设备	Weed scraper	Piece	2.0	500.0	1000.0	100.0
设备	Slasher	Piece	2.0	500.0	1000.0	100.0
设备	Gunny bag	Piece	50.0	50.0	2500.0	100.0
技术建立所需总成本					14500.0
技术建立总成本，美元					135.41

4.5 维护/经常性活动

	活动	时间/频率
1.	Land preparation - Slashing	Initial stage
2.	Preparing the planting hills and rip lines	Initial stage
3.	Planting - placing seeds and fertilizer using jab planter	Initial stage
4.	Herbicide application	Initial and growing stages
5.	Pesticide application	Growing stage
6.	Fertilizer application (top-dressing)	Growing stage
7.	Harvesting, drying and shelling	Final stage

4.6 维护/经常性活动所需要的费用和投入（每年）

	对投入进行具体说明	单位	数量	单位成本	每项投入的总成本	土地使用者承担的成本%
劳动力	Land preparation - slashing and herbicide application	Man day	4.0	300.0	1200.0	100.0
劳动力	Planting - preparing the planting hills and placing seeds and fertilizer	Man day	38.0	300.0	11400.0	100.0
劳动力	Top-dressing and pesticide application	Man day	8.0	300.0	2400.0	100.0
劳动力	Harvesting, shelling and drying	Man day	30.0	300.0	9000.0	100.0
植物材料	Maize seed	Kg	20.0	250.0	5000.0	100.0
植物材料	Legume seed	Kg	8.0	250.0	2000.0	100.0
肥料和杀菌剂	Planting fertilizer	Kg	125.0	60.0	7500.0	100.0
肥料和杀菌剂	Top-dressing fertilizer	Kg	125.0	50.0	6250.0	100.0
肥料和杀菌剂	Pesticide	Litre	2.0	1250.0	2500.0	100.0
肥料和杀菌剂	Herbicide	Litre	5.0	875.0	4375.0	100.0
其它	Transport	Km	5.0	1500.0	7500.0	100.0
技术维护所需总成本					59125.0
技术维护总成本，美元					552.16

4.7 影响成本的最重要因素

描述影响成本的最决定性因素:

1. Prevailing market prices of the inputs, equipment and labour.

5. 自然和人文环境

5.1 气候

年降雨量

< 250毫米
251-500毫米
501-750毫米
751-1,000毫米
1,001-1,500毫米
1,501-2,000毫米
2,001-3,000毫米
3,001-4,000毫米
> 4,000毫米

有关降雨的规范/注释:

Rainfall is bi-modal with the long rain season starting from March to May, and the short rains from October to December.

农业气候带

潮湿的
半湿润

mean annual temperature varies from 18 to 29° C

5.2 地形

平均坡度:

水平（0-2%）
缓降（3-5%）
平缓（6-10%）
滚坡（11-15%）
崎岖（16-30%）
陡峭（31-60%）
非常陡峭（>60%）

地形:

高原/平原
山脊
山坡
山地斜坡
麓坡
谷底

垂直分布带:

0-100 m a.s.l.
101-500 m a.s.l.
501-1,000 m a.s.l.
1,001-1,500 m a.s.l.
1,501-2,000 m a.s.l.
2,001-2,500 m a.s.l.
2,501-3,000 m a.s.l.
3,001-4,000 m a.s.l.
> 4,000 m a.s.l.

说明该技术是否专门应用于:

不相关

5.3 土壤

平均土层深度:

非常浅（0-20厘米）
浅（21-50厘米）
中等深度（51-80厘米）
深（81-120厘米）
非常深（> 120厘米）

土壤质地（表土）:

中粒（壤土、粉土）
细粒/重质（粘土）

土壤质地（地表以下> 20厘米）:

中粒（壤土、粉土）
细粒/重质（粘土）

表土有机质:

中（1-3%）
低（<1%）

5.4 水资源可用性和质量

地下水位表:

5-50米

地表水的可用性:

中等

水质（未处理）:

不良饮用水（需要处理）

水质请参考：:

地下水和地表水

水的盐度有问题吗？:

否

该区域正在发生洪水吗？:

否

5.5 生物多样性

物种多样性:

中等

栖息地多样性:

中等

5.6 应用该技术的土地使用者的特征

定栖或游牧:

定栖的

生产系统的市场定位:

生计（自给）
混合（生计/商业）

非农收入:

低于全部收入的10%
收入的10-50%

相对财富水平:

贫瘠
平均水平

个人或集体:

个人/家庭

机械化水平:

手工作业
畜力牵引

性别:

女人
男人

土地使用者的年龄:

中年人
老年人

5.7 应用该技术的土地使用者使用的平均土地面积

< 0.5 公顷
0.5-1 公顷
1-2 公顷
2-5公顷
5-15公顷
15-50公顷
50-100公顷
100-500公顷
500-1,000公顷
1,000-10,000公顷
> 10,000公顷

这被认为是小规模、中规模还是大规模的（参照当地实际情况）？:

小规模的

5.8 土地所有权、土地使用权和水使用权

土地所有权:

个人，未命名
个人，有命名

土地使用权:

个人

用水权:

社区（有组织）
个人

土地使用权是否基于传统的法律制度？:

是

5.9 进入服务和基础设施的通道

健康:

贫瘠
适度的
好

教育:

贫瘠
适度的
好

技术援助:

贫瘠
适度的
好

就业（例如非农）:

贫瘠
适度的
好

市场:

贫瘠
适度的
好

能源:

贫瘠
适度的
好

道路和交通:

贫瘠
适度的
好

饮用水和卫生设施:

贫瘠
适度的
好

金融服务:

贫瘠
适度的
好

6. 影响和结论性说明

6.1 该技术的现场影响

社会经济效应

生产

作物生产

降低

增加

SLM之前的数量:

Reduced tillage has subsequently decreased the farmers' workload because they no longer have to plough the entire field

On-farm demonstrations of the CA technology and the training of trainers (ToTs) have empowered different stakeholders within the communities with sufficient SLM/ land degradation knowledge

生态影响

水循环/径流

地表径流

增加

降低

注释/具体说明:

The dense Mucuna pruriens cover crop reduces surface runoff

地下水位/含水层

下降

补水

注释/具体说明:

There has been increase in water infiltration and soil water content because the dense Mucuna pruriens cover crop not only regulates the soil surface temperatures and evaporation, but also reduces surface runoff. This recharges the aquifer

蒸发

增加

降低

注释/具体说明:

The dense Mucuna pruriens cover crop regulates both the soil surface temperatures and evaporation

As the dense cover crop grows, the leaves fall and decompose on the ground, with organic matter additions.

Diversified cropping through rotations has reduced the incidences of insect pests and diseases through disruption of pest and disease cycles. Specifically, farmers have noticed that the CA plots under maize - Mucuna pruriens intercrop are less affected by the fall armyworm (Spodoptera frugiperda)

减少气候和灾害风险

干旱影响

增加

降低

注释/具体说明:

The maize established with Mucuna pruriens as a cover crop has remained green and healthy for long during mid-season dry spells. This implies that the CA technology also increases water infiltration and soil water content; thus, acting as insurance against drought.

碳和温室气体的排放

增加

降低

注释/具体说明:

Reduced tillage mitigates atmospheric carbon dioxide emissions through the decrease in fossil fuel consumption and soil disturbance. Crop residues are also retained in the field and not burnt; hence, reducing emission of carbon.

6.2 该技术的场外影响已经显现

温室气体的影响

增加

减少

6.3 技术对渐变气候以及与气候相关的极端情况/灾害的暴露和敏感性（土地使用者认为的极端情况/灾害）

渐变气候

	季节	增加或减少	该技术是如何应对的？
年温度		增加	好
年降雨量		增加	好

气候有关的极端情况（灾害）

气候灾害

	该技术是如何应对的？
干旱	好

生物灾害

	该技术是如何应对的？
流行病	好
昆虫/蠕虫侵扰	好

6.4 成本效益分析

技术收益与技术建立成本相比如何（从土地使用者的角度看）？

短期回报:

稍微积极

长期回报:

积极

技术收益与技术维护成本/经常性成本相比如何（从土地使用者的角度看）？

短期回报:

稍微积极

长期回报:

积极

注释:

For example, it is expected that the associated improvement in soil organic matter, soil structure and nutrient status will reduce the use of fertilizers in the long term.

6.5 技术采用

1-10%

在所有采用这项技术的人当中，有多少人是自发的，即未获得任何物质奖励/付款？:

51-90%

6.6 适应

最近是否对该技术进行了修改以适应不断变化的条件？:

否

6.7 该技术的优点/长处/机会

土地使用者眼中的长处/优势/机会
Maize established with Mucuna pruriens as a dense cover crop is not adversely affected by the fall army worm (Spodoptera frugiperda)
Reduced tillage saves time, money and energy, while the direct placement of inputs (seeds and fertilizers) minimizes wastage. The saved resources can be used to engage in other income-generating activities
Maize established with Mucuna pruriens as a dense cover crop remains green and healthy for long during mid-season dry spells
Weeds, such as Striga hermonthica (witchweed) are suppressed in plots under dense cover crop and diversified cropping (rotations and inter-crops)
In seasons of excessive rainfall, the maize intercropped with the common bean is usually harvested even when the common bean fails
The CA technology has boosted maize yields, meaning more food and income, and reduced cost of feeding the family

编制者或其他关键资源人员认为的长处/优势/机会
The CA plots with Mucuna pruriens as a dense cover crop have improved soil organic matter, soil structure and nutrient status
Reduced tillage has enhanced soil living organisms, such as earthworms and decreased fuel consumption and soil disturbance; hence, mitigating atmospheric carbon dioxide emissions and storing carbon in soils
The CA technology has increased water infiltration and soil water content (moisture); thus, acting as insurance against drought
Diversified cropping through rotations has reduced the incidences of insect pests and diseases, as well as the risk of crop failure during extreme weather conditions and pest infestations

6.8 技术的弱点/缺点/风险及其克服方法

土地使用者认为的弱点/缺点/风险	如何克服它们？
The Mucuna pruriens used as a dense cover crop intertwines on maize crop, which might increase manual labour	Promote other erect cover crops like the lablab bean (Dolichos lablab), Desmodium and Canavalia that will have less effect on the cereal crop established
The yields of Mucuna pruriens used as a dense cover crop are not edible	- Extension agents and Trainer of Trainees (ToTs) to equip farmers with knowledge on the options available for utilizing Mucuna pruriens yields other than being a cover crop - Promote other erect cover crops like the lablab bean (Dolichos lablab), Desmodium and Canavalia
Residue retention reduces the availability of fodder and fuel materials	Adopt an agro-forestry system with tree species that can provide alternative source of fodder and fuel
The critical CA inputs and implements, such as the jab planters, weed scrapers, herbicides and Mucuna seeds are hard to access	- Incentivize and train the local fabricators to fabricate affordable CA tools - Subsidize CA inputs, such as fertilizer and herbicides - Facilitate access to credit - Train more seed producers to multiply the seeds of Mucuna pruriens

编制者或其他关键资源人员认为的弱点/缺点/风险	如何克服它们？
Agro-ecosystem contamination through use of herbicides and inorganic fertilizers	Use the right doses of herbicides and fertilizers

查看章节

1. 一般信息

1.2 参与该技术评估和文件编制的资源人员和机构的联系方式

关键资源人

SLM专业人员:

SLM专业人员:

SLM专业人员:

SLM专业人员:

SLM专业人员:

有助于对技术进行记录/评估的项目名称（如相关）

有助于对技术进行记录/评估的项目名称（如相关）

有助于对技术进行记录/评估的机构名称（如相关）

1.3 关于使用通过WOCAT记录的数据的条件

编制者和关键资源人员接受有关使用通过WOCAT记录数据的条件。:

1.4 所述技术的可持续性声明

这里所描述的技术在土地退化方面是否存在问题，导致无法被认为是一种可持续的土地管理技术？:

2. SLM技术的说明

2.1 技术简介

技术定义:

2.2 技术的详细说明

说明:

2.3 技术照片

媒体库

2.4 技术视频

2.5 已应用该技术的、本评估所涵盖的国家/地区/地点

国家:

区域/州/省:

有关地点的进一步说明:

具体说明该技术的分布:

技术现场是否位于永久保护区？:

2.6 实施日期

注明实施年份:

2.7 技术介绍

详细说明该技术是如何引入的:

注释（项目类型等）:

3. SLM技术的分类

3.1 该技术的主要目的

3.2 应用该技术的当前土地利用类型

同一土地单元内混合使用的土地：:

具体说明混合土地使用（作物/放牧/树木）:

农田

年作 - 具体指明作物:

年作制度:

每年的生长季节数:

具体说明:

采用间作制度了吗？:

如果是，说明哪些作物是间作的:

采用轮作制度了吗？:

如果是，请具体说明:

牧场

集约放牧/饲料生产:

动物类型:

是否实行作物与牲畜的综合管理？:

如果是，请具体说明:

产品和服务:

3.3 由于技术的实施，土地使用是否发生了变化？

由于技术的实施，土地使用是否发生了变化？:

同一土地单元内混合使用的土地：:

具体说明混合土地使用（作物/放牧/树木）:

农田

年作 - 具体指明作物:

年作制度:

采用间作制度了吗？:

采用轮作制度了吗？:

牧场

集约放牧/饲料生产:

动物类型:

是否实行作物与牲畜的综合管理？:

如果是，请具体说明:

产品和服务:

3.4 供水

该技术所应用土地的供水:

3.5 该技术所属的SLM组

3.6 包含该技术的可持续土地管理措施

农艺措施

A3：区分耕作制度:

A6：对残株管理作出具体说明:

3.7 该技术强调的主要土地退化类型

土壤水蚀

土壤风蚀