The development of fishery-photovoltaic complementary industry and the studies on its environmental, ecological and economic effects in China: A review

IF 8 Q1 ENERGY & FUELS
Zihao Zhu , Zijie Song , Sihan Xu , Shoubing Wang , Xingyu Chen , Yongshuang Wang , Zhenhua Zhu
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Therefore, based on an analysis of relevant research literature, this study reviews the current development status, environmental and economic effects, as well as challenges faced by the fishery-photovoltaic complementary industry in China. The aim is to provide scientific references for promoting sustainable development within this sector. The findings reveal that existing fishery-photovoltaic complementary industry projects are primarily concentrated in the middle and lower reaches of the Yangtze River and Pearl River Basin. The geographical distribution of these projects is predominantly influenced by local aquaculture areas and available solar energy resources, with a greater impact observed from the former rather than the latter. 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引用次数: 0

Abstract

The fishery-photovoltaic complementary industry is an emerging industrial model in China that integrates aquaculture with the solar industry. This innovative model involves conducting aquaculture activities while installing photovoltaic modules on the water surface to harness solar energy for electricity generation. However, despite its rapid growth in China, this model lacks substantial scientific data support across various domains. Therefore, based on an analysis of relevant research literature, this study reviews the current development status, environmental and economic effects, as well as challenges faced by the fishery-photovoltaic complementary industry in China. The aim is to provide scientific references for promoting sustainable development within this sector. The findings reveal that existing fishery-photovoltaic complementary industry projects are primarily concentrated in the middle and lower reaches of the Yangtze River and Pearl River Basin. The geographical distribution of these projects is predominantly influenced by local aquaculture areas and available solar energy resources, with a greater impact observed from the former rather than the latter. During summer months when water is shaded by photovoltaic panels, a slight decrease in the average water quality parameters across cases was observed, such as a decrease of 0.2 units in pH, a decrease of 1.06 °C in water temperature, a decrease in dissolved oxygen levels of 0.8 mg/L, inorganic nitrogen content and total phosphorus concentration dropped by 0.08 mg/L and 0.02 mg/L respectively. Conversely, there is a moderate increase noted in total nitrogen and ammonia nitrogen levels. The conclusion of the effect on phytoplankton biomass is not uniform, but it will certainly reduce zooplankton biomass. The impact on the species diversity of the zooplankton community was minimal, and its direction, whether positive or negative, varied depending on the specific aquatic ecosystem. A certain degree of shade is advantageous for the cultivation of shade-loving fish. Through the strategic deployment of photovoltaic panels and the implementation of scientific stocking practices, it is possible to achieve sustained levels of fisheries production. This model also can reduce an average of 978.6 tons of CO2 emissions per megawatt per year through energy production, thus achieving the combined goals of energy conservation and emissions reduction, and ensuring the profitability of power generation. Additionally, compared with the land utilization area of 3.66 hm2 per megawatt of traditional ground-mounted photovoltaics, fishery-photovoltaic complementary only requires 1.64 hm2, which can significantly save land resources by utilizing water surfaces, which mitigates the conflict between land use for agriculture and renewable energy installations. At the same time, research also pointed out that the existence of fishery-photovoltaic complementary will inevitably have some negative impacts on bird communities. Economic analyses indicate that while initial infrastructure costs and long payback periods pose challenges, the overall economic feasibility is promising, especially with governmental support and technological advancements. However, several challenges need to be addressed for further development: these include difficulties associated with infrastructure construction and initial costs, long payback periods; insufficient experience and technical support; as well as a lack of research on ecological and environmental impacts - particularly an urgent need for comprehensive life cycle assessments encompassing both environmental and economic aspects. Future research should focus on life cycle assessments, improved PV technology integration, and optimized aquaculture practices.

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中国渔光互补产业的发展及其环境、生态和经济效应研究:综述
渔光互补产业是中国将水产养殖与太阳能产业相结合的新兴产业模式。这种创新模式是在开展水产养殖活动的同时,在水面安装光伏组件,利用太阳能发电。然而,尽管这种模式在中国发展迅速,却缺乏各领域大量科学数据的支持。因此,本研究在分析相关研究文献的基础上,回顾了中国渔业与光伏互补产业的发展现状、环境和经济效应以及面临的挑战。目的是为促进该行业的可持续发展提供科学参考。研究结果表明,现有的渔光互补产业项目主要集中在长江中下游和珠江流域。这些项目的地理分布主要受当地水产养殖区和可用太阳能资源的影响,前者的影响大于后者。在夏季,当水体被光伏板遮挡时,各案例的平均水质参数略有下降,如 pH 值下降 0.2 个单位,水温下降 1.06 °C,溶解氧水平下降 0.8 毫克/升,无机氮含量和总磷浓度分别下降 0.08 毫克/升和 0.02 毫克/升。相反,总氮和氨氮的含量则略有增加。对浮游植物生物量的影响结论并不一致,但肯定会减少浮游动物的生物量。对浮游动物群落物种多样性的影响微乎其微,其方向是积极的还是消极的,因具体的水生生态系统而异。一定程度的遮荫有利于喜阴鱼类的养殖。通过战略性地部署光伏板和实施科学的放养方法,可以实现持续的渔业生产水平。这种模式还可以通过能源生产平均每年每兆瓦减少 978.6 吨二氧化碳排放,从而实现节能减排的综合目标,并确保发电的盈利性。此外,与传统地面光伏每兆瓦 3.66 hm2 的土地利用面积相比,渔光互补仅需 1.64 hm2,利用水面可大幅节约土地资源,缓解了农业用地与可再生能源设施的矛盾。同时,研究也指出,渔光互补的存在不可避免地会对鸟类群落产生一些负面影响。经济分析表明,虽然初期基础设施成本和较长的投资回收期构成了挑战,但总体经济可行性是有希望的,特别是在政府支持和技术进步的情况下。然而,要进一步发展,还需要应对几个挑战:包括与基础设施建设和初期成本相关的困难、投资回收期长;经验和技术支持不足;以及缺乏对生态和环境影响的研究--特别是迫切需要进行包括环境和经济两方面的综合生命周期评估。未来的研究应侧重于生命周期评估、改进光伏技术集成和优化水产养殖实践。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Energy nexus
Energy nexus Energy (General), Ecological Modelling, Renewable Energy, Sustainability and the Environment, Water Science and Technology, Agricultural and Biological Sciences (General)
CiteScore
7.70
自引率
0.00%
发文量
0
审稿时长
109 days
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