Assessment of Changes in Environmental Factors Affecting Aquaculture Production and Fisherfolk Incomes in China between 2010 and 2020
Abstract
:1. Introduction
2. Materials and Methods
2.1. Principal Component Analysis (PCA)
2.2. Data Set and Variables
2.3. Analysis of Data
3. Results
4. Discussion
- (1)
- Improving the aquaculture production environment in China should be approached from two directions. Firstly, the management systems for the aquaculture production environment in the Central region require strengthening to reduce the negative impacts of environmental pollution on aquaculture production. This involves reducing the pollution in the local environment caused by pesticides and fertilizers, controlling industrial sources of pollution, and adequately treating rural sewage. The objective involves striving to minimize the extent of the negative impacts of environmental pollution on aquaculture production. The second facet is to strengthen the training of Chinese fisherfolk and deepen their knowledge of aquaculture and the environment, thus raising their awareness and understanding of the rational use of pesticides and fertilizers, to allow professionals to assess the intensity of pesticide and fertilizer run-off and the timing of application around rainfall as well as providing farmers and fisherfolk with advance warning. This seeks to avoid the application of pesticides and fertilizers before heavy rains to reduce the loss of pesticides and fertilizers, thus reducing the flows into rivers and other agricultural watercourses caused by rainwater carrying away pesticides and fertilizers. Simultaneously, it is essential to select the fertilizers and pesticides appropriate to the specific environment of the region, to thoroughly evaluate the impact on the regional ecosystem and to strive to selectively apply fertilizers and pesticides through both balanced and effective practices.
- (2)
- An improvement in fisherfolk incomes should be supported by government subsidies (transfer income) in those regions (Northeastern and Western regions) severely affected by the natural environment and where fisherfolk incomes remain low. Additionally, developing green fisheries and aquaculture production should be supported to boost fisherfolk incomes through different channels. Furthermore, it is vital to encourage and provide fisherfolk with free training courses on aquaculture farming and environmental pollution, thereby increasing the awareness of the ecological protection of the aquaculture industry.
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Conflicts of Interest
Appendix A
Units: Ton | Seawater Aquaculture | Freshwater Aquaculture | |||||
---|---|---|---|---|---|---|---|
2010 | 2020 | Changes (%) | 2010 | 2020 | Changes (%) | ||
Eastern | Beijing | - | - | - | 50,202 | 21,079 | −138.16 |
Tianjin | 14,212 | 5155 | −175.69 | 296,272 | 216,994 | −36.53 | |
Hebei | 329,308 | 448,802 | 26.63 | 388,453 | 258,953 | −50.01 | |
Shanghai | - | - | - | 162,479 | 83,555 | −94.46 | |
Jiangsu | 785,173 | 915,258 | 14.21 | 2,907,598 | 3,178,892 | 8.53 | |
Zhejiang | 825,730 | 1,270,357 | 35 | 875,020 | 1,171,254 | 25.29 | |
Fujian | 3,038,990 | 5,107,162 | 40.5 | 659,668 | 839,379 | 21.41 | |
Shandong | 3,962,643 | 4,970,985 | 20.28 | 1,244,018 | 1,081,348 | −15.04 | |
Guangdong | 2,490,688 | 3,291,325 | 24.33 | 3,146,669 | 4,000,107 | 21.34 | |
Hainan | 184,162 | 270,955 | 32.03 | 296,413 | 354,387 | 16.36 | |
Total Aquaculture in the Eastern region | 11,630,906 | 16,279,999 | 28.56 | 10,026,792 | 11,205,948 | 10.52 | |
Total aquaculture in the Eastern region as a percentage of national aquaculture (%) | 78.47 | 78.83 | 0.46 | 42.73 | 37.18 | −14.92 | |
Central | Shanxi | - | - | - | 30,869 | 44,040 | 29.91 |
Anhui | - | - | - | 1,617,241 | 2,109,524 | 23.34 | |
Jiangxi | - | - | - | 1,860,892 | 2,420,568 | 23.12 | |
Henan | - | - | - | 546,200 | 878,603 | 37.83 | |
Hubei | - | - | - | 3,267,281 | 4,533,682 | 27.93 | |
Hunan | - | - | - | 1,883,332 | 2,463,211 | 23.54 | |
Total Aquaculture in the Central region | - | - | - | 9,205,815 | 12,449,628 | 26.06 | |
Total aquaculture in the Central region as a percentage of national aquaculture (%) | - | - | - | 39.23 | 41.31 | 5.03 | |
Western | Chongqing | - | - | - | 213,345 | 524,116 | 59.29 |
Gansu | - | - | - | 12,300 | 14,353 | 14.3 | |
Guangxi | 877,408 | 1,425,970 | 38.47 | 1,093,701 | 1,335,494 | 18.11 | |
Guizhou | - | - | - | 75,838 | 233,024 | 67.45 | |
Inner Mongolia | - | - | - | 83,133 | 111,904 | 25.71 | |
Ningxia | - | - | - | 89,845 | 149,533 | 39.92 | |
Qinghai | - | - | - | 1565 | 18,526 | 91.55 | |
Shaanxi | - | - | - | 56,138 | 161,196 | 65.17 | |
Sichuan | - | - | - | 992,605 | 1,538,002 | 35.46 | |
Tibet | - | - | - | 72 | 96 | 25 | |
Xinjiang | - | - | - | 90,913 | 152,032 | 40.2 | |
Yunnan | - | - | - | 274,636 | 606,137 | 54.69 | |
Total Aquaculture in the Western region | 877,408 | 1,425,970 | 38.47 | 2,984,091 | 4,844,317 | 38.4 | |
Total aquaculture in the Western region as a percentage of national aquaculture (%) | 5.92 | 6.9 | 14.27 | 12.72 | 16.07 | 20.89 | |
Northeast | Heilongjiang | - | - | - | 352,815 | 608,300 | 42 |
Jilin | - | - | - | 146,202 | 217,501 | 32.78 | |
Liaoning | 2,314,694 | 2,947,318 | 21.46 | 749,628 | 811,651 | 7.64 | |
Total Aquaculture in the Northeast region | 2,314,694 | 2,947,318 | 21.46 | 1,248,645 | 1,637,452 | 23.74 | |
Total aquaculture in the Northeast region as a percentage of national aquaculture (%) | 15.62 | 14.27 | −9.43 | 5.32 | 5.43 | 2.06 |
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Environmental Variables (Unit: Hectares) | ||
---|---|---|
TFA | Aquaculture farming areas affected by typhoons and flooding | Economic losses due to damage to aquaculture facilities and loss of aquaculture products caused by meteorological disasters such as typhoons and floods. Farming areas affected by typhoons and flooding include aquaculture and freshwater farming areas (Unit: hectares) |
DA | Aquaculture farming areas affected by diseases | Bacterial and parasite illnesses can cause major economic losses deriving from high fish mortality rates. Farming areas affected by diseases include aquaculture and freshwater farming areas (Unit: hectares) |
DRA | Aquaculture farming areas affected by droughts | Drought causes a decrease in the volume of farming water, making water quality control more difficult and causing a serious lack of oxygen in the water, resulting in the death of a large number of farming species; during the hot season, water quality drops, making it easier for epidemics to occur and spread. |
PA | Aquaculture farming areas affected by pollution | Eutrophication of the aquaculture environment is mostly caused by aquaculture pollution, which can result in red tides and fish illnesses. |
OA | Aquaculture farming areas affected by environmental factors other than typhoons, floods, disease, drought, and pollution | Environmental factors other than typhoons, floods, disease, drought, and pollution. |
Income Variables (Unit: CNY) | ||
HOI | Household operating income | Household operating income is derived through the production and administration of goods and services in the family. |
SI | Salary income | Salary income refers to the total remuneration for work and benefits received by fisherfolk in their household through various means, including wages earned from productive work in the aquaculture industry and wages earned from work in other industries. |
PI | Property net income | Property net income is the net income received by fisherfolk households or their member in return for placing financial assets and natural resources at the disposal of other institutions, households or individuals, and after deduction of relevant fees and charges. (Examples: net interest income, dividend income, net income from savings insurance, net rental income from the transfer of contracted land or water rights, etc.). |
TI | Transfer income | Transfer income refers to various recurrent transfers from the government, institutions, and social teams to fisherfolk. (Examples: pensions or retirement benefits, social assistance and subsidies, agricultural subsidies, policy subsistence subsidies, etc.) transferred to fisherfolk by the government, non-administrative units, and social teams. |
Region | Ranking | Ranking | Ranking Changes | Ranking | Ranking | Ranking Changes | |||||
---|---|---|---|---|---|---|---|---|---|---|---|
Eastern | Beijing | −4.21 | 25 | −3.01 | 21 | 4 | −3.18 | 26 | −2.97 | 26 | 0 |
Fujian | 8.5 | 4 | 4.03 | 9 | −5 | −1.94 | 15 | −2.77 | 19 | −4 | |
Guangdong | 17.45 | 1 | 2.83 | 10 | −9 | 1.32 | 10 | 4.73 | 6 | 4 | |
Hainan | 4.09 | 8 | −3.77 | 24 | −16 | −2.52 | 18 | −2.88 | 22 | −4 | |
Hebei | −3.02 | 16 | 4.17 | 8 | 8 | −2.59 | 20 | −2.26 | 11 | 9 | |
Jiangsu | 8.01 | 5 | 14.54 | 2 | 3 | 4.65 | 6 | 15.99 | 1 | 5 | |
Shandong | 9.94 | 2 | 6.33 | 6 | −4 | 3.58 | 7 | 2.64 | 8 | −1 | |
Shanghai | 6.68 | 6 | 11.97 | 4 | 2 | −2.91 | 23 | −2.85 | 20 | 3 | |
Tianjin | −2.46 | 14 | 14.11 | 3 | 11 | −2.92 | 24 | −2.33 | 14 | 10 | |
Zhejiang | 9.87 | 3 | 17.52 | 1 | 2 | −1.65 | 14 | −0.36 | 10 | 4 | |
Central | Anhui | −1.27 | 12 | −0.6 | 16 | −4 | 8.27 | 2 | 9.95 | 2 | 0 |
Henan | −3.96 | 19 | −1.96 | 19 | 0 | −2.71 | 21 | −0.26 | 9 | 12 | |
Hubei | −0.37 | 11 | 1.99 | 11 | 0 | 14.48 | 1 | 8.72 | 3 | −2 | |
Hunan | −1.95 | 13 | −1.26 | 18 | −5 | 5.92 | 3 | 6.12 | 5 | −2 | |
Jiangxi | −2.73 | 15 | −0.42 | 15 | 0 | 4.94 | 4 | 7.54 | 4 | 0 | |
Shanxi | −4.3 | 26 | −9.46 | 28 | −2 | −3.22 | 28 | −2.99 | 28 | 0 | |
Western | Chongqing | −4.08 | 22 | 1.49 | 12 | 10 | −2.56 | 19 | −2.85 | 21 | −2 |
Gansu | −3.85 | 18 | −11.71 | 30 | −12 | −3.23 | 29 | −2.99 | 29 | 0 | |
Guangxi | 0.21 | 10 | 4.2 | 7 | 3 | 0.35 | 11 | −2.33 | 13 | −2 | |
Guizhou | −4.38 | 29 | −9.51 | 29 | 0 | −1.29 | 12 | −2.7 | 16 | −4 | |
Inner Mongolia | −4.32 | 27 | −7.17 | 26 | 1 | −1.95 | 16 | −2.28 | 12 | 4 | |
Ningxia | −4.32 | 28 | −2.81 | 20 | 8 | −3.16 | 25 | −2.98 | 27 | −2 | |
Qinghai | −4.42 | 30 | −8.49 | 27 | 3 | −3.23 | 30 | −2.99 | 30 | 0 | |
Shaanxi | 2.59 | 9 | 1.36 | 13 | −4 | −2.81 | 22 | −2.93 | 24 | −2 | |
Sichuan | −3.36 | 17 | 0.02 | 14 | 3 | −1.3 | 13 | −2.75 | 18 | −5 | |
Tibet | −4.42 | 30 | −18.05 | 31 | −1 | −3.23 | 31 | −2.99 | 30 | 1 | |
Xinjiang | −4.1 | 23 | −3.18 | 22 | 1 | −2.15 | 17 | −2.74 | 17 | 0 | |
Yunan | −4.03 | 20 | −3.51 | 23 | −3 | 4.79 | 5 | −2.38 | 15 | −10 | |
Northeast | Heilongjiang | −4.07 | 21 | −1.02 | 17 | 4 | −3.21 | 27 | −2.95 | 25 | 2 |
Jilin | −4.12 | 24 | −7.1 | 25 | −1 | 1.87 | 8 | −2.93 | 23 | −15 | |
Liaoning | 6.43 | 7 | 8.48 | 5 | 2 | 1.58 | 9 | 2.76 | 7 | 2 |
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Wang, P.; Mendes, I. Assessment of Changes in Environmental Factors Affecting Aquaculture Production and Fisherfolk Incomes in China between 2010 and 2020. Fishes 2022, 7, 192. https://doi.org/10.3390/fishes7040192
Wang P, Mendes I. Assessment of Changes in Environmental Factors Affecting Aquaculture Production and Fisherfolk Incomes in China between 2010 and 2020. Fishes. 2022; 7(4):192. https://doi.org/10.3390/fishes7040192
Chicago/Turabian StyleWang, Peiwen, and Isabel Mendes. 2022. "Assessment of Changes in Environmental Factors Affecting Aquaculture Production and Fisherfolk Incomes in China between 2010 and 2020" Fishes 7, no. 4: 192. https://doi.org/10.3390/fishes7040192
APA StyleWang, P., & Mendes, I. (2022). Assessment of Changes in Environmental Factors Affecting Aquaculture Production and Fisherfolk Incomes in China between 2010 and 2020. Fishes, 7(4), 192. https://doi.org/10.3390/fishes7040192