The gully region of Loess Plateau is one of the earliest human settlement areas and the most ecologically sensitive areas in China. It has been facing challenges for future development. Gully village is the smallest social units on Loess Plateau that owns large amount of agricultural population. However, due to inappropriate development planning and lack of developing directions, they are gradually disappearing. Based on the practical investigations of the Gully Regions of Loess Plateau, this paper aims to explore a new way for the future development of gully villages. Firstly, it classifies the gully villages by the distribution of location. Secondly, selecting ecological construction evaluation factors of gully village and completing the quantitative evaluation are applied on the suitability and sensitivity of ecological sustainable development classification. Thirdly, according to the comprehensive evaluation, the developing condition of each gully village is divided into “Good”, “General” and “Poor”. Finally, this paper figures out the future developing direction for gully villages in different developing conditions.
The Loess Plateau is located in the west of China, which is covered with 30 m - 300 m calcareous yellow soil, about 530 thousand square kilometers, accounting for 1/l8 of total Chinese territory [
Within the area, landscape can be divided into tableland, slope, and gully. Villages’ distribution in this region is dispersed and owns obvious local characteristics, mainly distributed in tableland, ditch, slope and gully [
Since the 21st century, with the progress of “population transfer to tableland”, large number of population who used to live in slope villages and gully villages gradually moved to the tableland. On the one hand, it caused the disappearance of the slope village and gully village. On the other hand, it increased ecological pressure of tableland where was densely populated originally. Therefore, for the ecological and sustainable development of gully villages and even the whole loess plateau, it is very important to explore a scientific way to save resources and use energy effectively, protect ecological environment, improve living environment of local people, and guide the construction of gully villages.
Gully villages are located in the gully region of third level tributary. The third level tributary can be identified by length that is about 50 km, and there are 5 km small scale rivers. The conception here is in compliance with what used in the protection and conservation of soil and water [
1) Villages located in main gullies
This type of villages located in the main gullies of the third level tributary. Gully villages own broad land that is near water sources and main roads. Thus, the village size is larger than those located in gully branches, and high population density area. The following figures show a typical main gully village, the name of that is Zhang Jia He village. There are 135 families, 516 people, 102.33 hectares of cultivated land, and the annual per-capita income is approximately 5000 RMB (816 USD) (
In addition, even in the same third level tributary gully, the distributions of gully villages has different forms. If the villages in the main gullies are close to the gullies junction or plateau surface, the developing conditions of these villages are quite better than other villages [
2) Villages located in branch gullies
Because of limited geography, the villages located in branch gullies of the third level tributary, in form of a closed space, which creates an independent, quiet and harmonious neighborhood living unit in Loess Plateau. The villages have a small size with small number of population. The following figures show a typical branch gully village, the name of village is Wu Jia Shan village. There are 68 families, 258 people, and 30.93 hectares of cultivated land. There is no primary school and clinic, meanwhile, infrastructure is poor. Annual per-capita income is less 2000RMB (327 USD) (
Although the distribution of gully villages in main gullies and branch gullies are different, their component elements, distribution forms and the developing influenced elements are almost the same. As there is not much difference between these two kinds of villages, only for the developing conditions are different, they are different. Thus this study uses a same method to evaluate these two kinds of villages. Based on the established ecological system of tableland, the ecological construction of gully villages aims to achieve sustainable development through practical investigation, documentation research, and by contemporary ecological theory and methods. The process of evaluation is shown in
The determination of index factors used in the process of ecological suitability and sensitivity evaluation makes possible for evaluating the effects of ecological construction by qualitative and quantitative methods. The ecological index evaluation of gully villages’ human living ecology is a typical multi-objective decision; each index reflects the importance on ecology. Due to the different contributions of these index factors to the ecological aim, these factors should be treated differently during the process of comprehensive evaluation [
For this reason, the sequencing of index factors with different degree is the basis for the evaluation, and it is also show the understanding of society, economy, the nature, and the implement of governmental guidelines. At present, there is no systematic data statistics of related data in the gully regions. In this research, the index weights are mainly according to large amount of literature review and field research. Basic data are mainly received from local governments and villagers during the field research. According to the importance of factors on people’s production and living, these factors are estimated and classified.
Evaluation on the suitability of ecological construction is based on weighted grading method [
The main ideas can be listed as the following:
1) The selection and classification of suitability evaluation factors. The factors’ suitability can classify into 5, 3, 1, which can also be used to show the suitability levels of ecological construction of gully villages [
According to different influence factors on production, living and adapting methods, and documents utility, author selected ten evaluation factors: 1) slope gradient of both slopes in gullies, 2) gully width, 3) surface water, 4) cultivated land per capita, 5) population size, 6) transportation, and 7) village land use degrees, 8) soil productivity, 9) plants diversity, and 10) public infrastructure. Ten evaluation factors are described as follows:
1) Slope gradient of both slopes in gullies
The influence caused by slope gradient is one of the most important factors for land suitability. According to the research of runoff plots of soil and water conservation, if the slope gradient is within 30˚ and under the same utilization conditions, the bigger the slope gradient, the soil and water erosion will be worse, and soil productivity will be lower thus slope gradient and soil and water erosion is positive correlated [
Slope gradient < 5˚: basically is flat land, soil erosion which is suitable land for village development. The evaluation value is 5.
Slope gradient 5˚ - 25˚: have a certain slope gradient, which can be use for terrace field. There are limitations for villages’ development. The evaluation value is 3.
Slope gradient > 25˚: slope gradient is large, the farmland there should be returned into forest or grass land. The limitation for villages’ development is large. The evaluation value is 1.
2) Gully width
Gully width directly limits the scale of village land use, land area, thus affecting the development of the whole village. The weight is 0.125.
Gully width > 300 m: there is enough developing space that can satisfy the demand for village development. The evaluation value is 5.
Gully width 100 m - 300 m: land scale is general and there is not too much space for further development. The evaluation value is 3.
Gully width < 100 m: land scale is too small and unsuitable for villages’ development. The evaluation value is.
3) Surface water
Surface water is one of the very important elements for wild animals and natural ecological system. Thus water area is a judge standard. The weight is 0.075.
Gully villages are located in the area of reservoir and the coverage area. The evaluation value is 5.
Gully villages are located in the coverage area of rivers or springs. The evaluation value is 3.
Gully villages are located in the no water area. The evaluation value is 1.
4) Cultivated land per capita
Cultivated land per capita is the most important production condition and essential guarantee for certain productivity. The weight is 0.100.
>3.0 mu/per: villagers have large area of production land and in good condition, thus good living conditions can be guaranteed. The evaluation value is 5.
1.5 - 3.0 mu/per: Production land is enough and villagers’ living conditions can be guaranteed. The evaluation value is 3.
<1.5 mu/per: Production land is not enough and in bad conditions, villagers’ life is very hard. The evaluation value is 1.
5) Population size
Population size is the basic element to ensure the villager development. The weight is 0.100.
>300: population is large size and developing conditions are related mature, which is suitable for further development. The evaluation value is 5.
100 - 300: Population is moderate size and developing conditions are relatively common, which can be reserved and developed. The evaluation value is 3.
<100: Population is relatively small size and developing conditions are relatively poor, which is better to relocate to other places. The evaluation value is 1.
6) Transportation
Numerous gullies, fragment landform and lower accessibility are the main characteristics of gully villagers’ transportation. Thus, transportation is the main index to measure the accessibility and convenience among cities and towns, which own the positive relation with villagers’ development degree [
Transportation joint: the joint of logistics, energy flow, information flow and species flow. The evaluation value is 5.
Beside transportation thoroughfares: the place that logistics, energy flow, information flow and species flow pass. The evaluation value is 3.
Faraway from transportation thoroughfares: the place is far away from logistics, energy flow, information flow and species flow. The evaluation value is 1.
7) Village land use degrees
Village land use degree is an important influence factor for developing invest and construction, which is also one of the basis for deciding villagers developing directions in a period of planning process. The higher degree of land use means the larger population and the bigger developing potential. It is how that the proportion of existing residential area. The weight is 0.100.
Village land use degree > 30%: The proportion of residential land use is high. The evaluation value is 5.
Village land use degree 5% - 30%: The proportion of residential land use is relatively high. The evaluation value is 3.
Village land use degree < 5%: The proportion of residential land use is low. The evaluation value is 1.
8) Soil productivity
Soil productivity refers to the food production capacity and quantity in farmland per unit, and also the comprehensive reflection of effective thickness of soil layer, soil organic elements, and water condition and soil texture. The weight is 0.125.
High productivity: effective thickness of soil layer > 200 cm, soil organic elements >1.2% soil texture is medium loam, no soil erosion. The evaluation value is 5.
Medium productivity: effective thickness of soil layer 100 - 200 cm,soil organic elements 1% - l.2%, soil texture is light loam, soil erosion is middle degree. The evaluation value is 3.
Low productivity: effective thickness of soil layer < 100 cm,soil organic elements
9) Plants diversity
Plants play very important ecological functions in protecting natural sources, and stabilizing gully and slope, soil and water conservation, improvement of fragile ecological environment and anti-interference ability, reduction of ecological sensitivity variation. Plants can be classified in the following three kinds according to their species, areas and values. The weight is 0.075.
Dense forest zone: mainly with natural vegetation and rich in wild animals. The evaluation value is 5.
Half forest and half village zone: mainly with artificial vegetation and farmland plants. The evaluation value is 3.
No vegetation zone: mainly with farmland plants and without natural vegetation and wild animals. The evaluation value is 1.
10) Public infrastructure degrees
Public infrastructure is the important guarantee for life, the developing level of which is one of the important elements to measure the degree of life convenience. The weight is 0.100.
According to the conditions and distribution, and take the reference of the public infrastructure standards, public infrastructure can be divided into good, general and poor.
According to the grading standards of single factors, a hierarchical graph can be made and the evaluation results of single factors should also be stacked. Using weighting factor method to evaluate, the computational formula is:
In Equation (1):
i―refers to the name of gully village, whose ecological construction conditions will be evaluated.
k―refers to the serial number of evaluation factors for ecological suitability evaluation.
n―refers to the total number of factors for ecological suitability evaluation.
Wk―weight value of factor k for ecological suitability evaluation, W1 + W2 + … + Wk = 1.
Bki―suitability evaluation value of factor k in gully village i.
Si―comprehensive evaluation value of ecological suitability in gully village i.
In
Ecological sensitivity refers to the ecological factors’ adaptability under the outside pressure or interference without damage or lower environmental quality [
Factors’ weighted grading method is adopted for evaluating the ecological sensitivity of gully villages. Firstly, identifying the evaluation factors that have influence on the villages’ ecological sensitivity, and then investigating the distribution and characteristics of each factor and classifying them. Secondly, according to their effects on the villages’ ecological construction, factors’ importance will be identified. More weights will be put to those factors that own more effects on ecological construction. Finally, on the basis of classification, all factors will be weighted sum, thus get the comprehensive evaluation value for sensitivity. The basic method is as the following:
1) The selection and classification of ecological sensitivity factors. The factors’ sensitivity can classify into 5, 3, 1, which can also be used to show the sensitivity levels of ecological construction of gully villages [
Ecological factors | Evaluation standards | Classification | Evaluation value | Weights |
---|---|---|---|---|
Slope gradient of both slopes in gullies | The smaller the slope gradient is, the higher suitability of ecological construction | <5˚ | 5 | 0.100 |
5˚ - 25˚ | 3 | |||
>25˚ | 1 | |||
Gully width | The wider the gully is , the higher suitability of ecological construction | >300 m | 5 | 0.125 |
100 m - 300 m | 3 | |||
<100 m | 1 | |||
Surface water | The better the surface water is, the higher suitability of ecological construction | Reservoir and the coverage area | 5 | 0.075 |
Rivers and springs | 3 | |||
No water areas | 1 | |||
Cultivated land per capita | The larger the cultivated land per capita is, the higher suitability of ecological construction | >3.0 mu/per | 5 | 0.100 |
1.5 - 3.0 mu/per | 3 | |||
<1.5 mu/per | 1 | |||
Population size | The larger the population size is, the higher suitability of ecological construction | >300 people | 5 | 0.100 |
100 - 300 people | 3 | |||
<100 people | 1 | |||
Transportation | The better the transportation is, the higher suitability of ecological construction | Transportation joint | 5 | 0.100 |
Transportation thoroughfares | 3 | |||
Faraway from transportation thoroughfares | 1 | |||
Village land use degrees | The higher the village land use degrees are, the higher suitability of ecological construction | >30% | 5 | 0.100 |
5% - 30% | 3 | |||
<5% | 1 | |||
Soil productivity | The better the soil productivity is, the higher suitability of ecological construction | High productivity | 5 | 0.125 |
Medium productivity | 3 | |||
Low productivity | 1 | |||
Plants diversity | The more diversity the plants are, the higher suitability of ecological construction | Dense forest zone | 5 | 0.075 |
Half forest and half tillage zone | 3 | |||
No vegetation zone | 1 | |||
Public infrastructure degrees | The higher lever the public infrastructure degrees are, the higher suitability of ecological construction | Good | 5 | 0.100 |
General | 3 | |||
Poor | 1 |
Taking the gully nature and social economy into consideration, there are six limitation factors: 1) slope gradient of gully slopes, 2) soil erodibility, 3) surface runoff sediments, 4) soil and water loss, 5) plant coverage, 6) pollution.
1) Slope gradient and length of both slopes
Ecological factors | Evaluation standards | Classification | Evaluation value | Weights |
---|---|---|---|---|
Slope gradient and length | The bigger the slope gradient and length is, the higher sensitivity of ecological construction | >25˚, <12 m | 5 | 0.250 |
5˚ - 25˚, 12 m - 60 m | 3 | |||
<5˚, >60 m | 1 | |||
Soil erodibility | The higher the soil erodibility is, the higher sensitivity of ecological construction | Sandy soil, clay | 5 | 0.250 |
Light loam | 3 | |||
Medium loam | 1 | |||
Surface runoff sediments | The more surface runoff sediment is, the higher sensitivity of ecological construction | Runoff and sediments collecting area | 5 | 0.100 |
Runoff and sediments source area | 3 | |||
Runoff and sediments formative area | 1 | |||
Soil and water loss | The more serious the soil and water loss is, the higher sensitivity of ecological construction | Serious | 5 | 0.150 |
General | 3 | |||
Slight | 1 | |||
Plants coverage | The more the plants coverage is, the higher sensitivity of ecological construction | <50% | 5 | 0.150 |
50% - 90% | 3 | |||
>90% | 1 | |||
Pollution | The more serious pollution is, the higher sensitivity of ecological construction | High | 5 | 0.100 |
Medium | 3 | |||
Low | 1 |
Slope gradient and length is an important factor that influences soil erosion sensitivity. Under a certain condition, the same slope gradient but longer slope, the kinetic energy of water flow is larger, soil erosion intensity is higher, geological conditions is less stable, thus it is very sensitive for human activity. The weight is 0.250.
Slope gradient < 5˚, slope length < 12 m: Basically are flat land and the ideal land for village development. The evaluation value is 5.
Slopes gradient 5˚ - 25˚, slope length 12 m - 60 m: Have a certain slope gradient, which can be used for terrace field. There are a certain limitations for villages’ development. The evaluation value is 3.
Slope gradient > 25˚, slope length > 60 m: The slope is large, slope gradient is large, the farmland there should be returned into forest or grass land. The limitation for villages’ development is large. The evaluation value is 1.
2) Soil erodibility
The higher the soil erodibility is, the erosion sensitivity will be higher. The weight is 0.250.
Sandy soil, clay. The evaluation value is 5.
Light loam. The evaluation value is 3.
Medium loam. The evaluation value is 1.
3) Surface runoff sediments
Surface runoff sediments is the most direct motivation for soil and water loss, thus kinetic energy of surface water and sediment movement is the most important factor to evaluate the soil erosion sensitivity. The weight is 0.100.
Runoff and sediments collecting area. The evaluation value is 5.
Runoff and sediments source area. The evaluation value is 3.
Runoff and sediments formative area. The evaluation value is 1.
4) Soil and water loss
The more serious the soil erosion means that ecology is more sensitive to human activity, which can be divided into serious, the evaluation value is 5; general, the evaluation value is 3; and slight, the evaluation value is 1. The weight is 0.150.
5) Plants coverage
The rain erosion and kinetic energy of water flow can be reduced greatly if the soil is covered by plants. At the same time, rainfall infiltration and surface runoff can be increased, thus reduces the soil erosion. Therefore, plants coverage is an important factor that influences soil erosion sensitivity. The weight is 0.150.
Plants coverage > 90%: Means that plant coverage area accounts for more than 90% of unit area. The evaluation value is 5.
Plants coverage 50% - 90%: Plant coverage area accounts for 50% - 90% of unit area. The evaluation value is 3.
Plants coverage < 50%: Plant coverage area accounts for less than 50% of unit area. The evaluation value is 1.
6) Pollution
Pollution caused by industry, agriculture, domestic pollution, and can be divided into high, the evaluation value is 1; medium, the evaluation value is 3; and low, the evaluation value is 1. The weight is 0.100.
According to the hierarchical graph of single factors, factors should be stacked. Then using weighting factor method to evaluate, the following is computational formula:
In the equation:
i―refers to the name of gully village, whose ecological construction conditions will be evaluated.
k―refers to the serial number of evaluation factors for ecological sensitivity evaluation.
n―refers to the total number of factors for ecological sensitivity evaluation.
In
According to the ecological suitability and sensitivity evaluation of gully villages, the developing condition can be divided into “Good”, “General” and “Poor”:
“Good” is defined that the comprehensive evaluation for ecological suitability > 3.70, and ecological sensitivity ≤ 2.40.
“General” is defined that the comprehensive evaluation for ecological suitability > 2.40, and ecological sensitivity ≤ 3.70.
“Poor” is defined that the comprehensive evaluation for ecological suitability < 2.40, and ecological sensitivity > 3.70.
If the self-conditions is the basic requirement for the ecological construction and social development of gully villages, then the ecological developing conditions of surrounding villages also play an important role in it. On the basis of quantitative and qualitative analyses of self-conditions of gully villages, this paper also analyze the relationship between gully villages and the surrounding villages. The surrounding villages’ developing level can directly or indirectly contribute the developing directions of gully villages. Combining with the surrounding villages’ developing situation,
Distribution of surrounding villages | Ecological self-conditions of gully villages | Future developing directions |
---|---|---|
Large villages with good developing conditions | Good | Villages can develop by themselves, and also can be merged into the surrounding villages with better developing conditions. |
General | It is better to be merged into the surrounding villages with better developing conditions, and also they can develop by themselves. | |
Poor | These villages should be merged into the surrounding village with better developing conditions. | |
General size villages with general developing conditions | Good | It is better to develop independently, and also they can merge into the surrounding villages. |
General | Villages can develop by themselves, and also can be merged into the surrounding villages with better developing conditions. | |
Poor | These villages should be merged into the surrounding villages with better developing conditions. | |
Small size villages with poor developing conditions | Good | These villages should merge with the small size villages with poor developing conditions. |
General | These villages can develop by themselves, and also can be merged into the surrounding villages with better developing conditions. | |
Poor | These villages can merge with the surrounding villages, and also can be moved to other areas. | |
No villages distribution | Good | These villages should develop independently. |
General | These villages should develop independently, and also can be move to other areas. | |
Poor | These villages should be move to other areas. |
China, as the largest developing country in the world, is experiencing rapid development now. Along with this rapid development and recent new socialist rural construction, gully villages of Loess Plateau are also experiencing a great change. How to make them to achieve a better development in the future is a big challenge for this region. At the same time, as one of the most fragile ecological area in China, it is very significant to improve their soil and water protection, ecological system, during the whole developing process.
This paper studies the gully villages of Loess Plateau in detailed, which are very typically facing “death” in recent years, and finds out factors that influences ecological construction and development. The classification of
suitability and sensitivity factors of ecological construction makes it possible to evaluate the efficiency of ecological construction by qualitative and quantitative evaluation, and at the same time provides as the basis for ecological management. However, human living’s ecological environment of gully village is continuous developing. These independent and limited index factors are impossible to reflect overall functions, structure relationships, developing levels and tendency. The comprehensive index system is not necessary and sufficient. And these standards are not absolute suitable for ecological construction. They must combine with specific time, space and social conditions. Therefore, what could be provided here are only relative references, which are imprecise and periodically. This paper hopes to explore a new way for the future development of gully villages, and provides reference and guidance for better and scientific development in the future.
1) Supported by the National R & D Infrastructure and Facility Development Program of China (2007 DKA 32300-12)
2) Supported by Science and technology research and development project of Shaanxi Province (2010K01-123)
TaoZhang,QinianHu,HiroatsuFukuda,DianZhou, (2016) The Evaluation Method of Gully Village’s Ecological Sustainable Development in the Gully Regions of Loess Plateau. Journal of Building Construction and Planning Research,04,1-12. doi: 10.4236/jbcpr.2016.41001