Carbon Peak and Carbon Neutralization Goals and Realization Paths of the Aquaculture and Fishing Industry in China

doi:10.13304/j.nykjdb.2022.0087

Abstract

Abstract:

Under the background of carbon peak and carbon neutralization，setting and implementing reasonable industry-specific goals has practical significance for the green and high-quality development of China’s fishery and the “dual carbon” strategy. Fishery mainly contains the aquaculture and fishing industry and has double attributes of carbon source and carbon sink. Based on the existing carbon emission and carbon sink accounting methods， this paper explored the “double carbon” goals of China’s aquaculture and fishing industry and the paths to achieve it. The analysis results showed that： ①from 2011 to 2020， due to the double influences of the expansion of fishery and the policy of “reducing ships and changing production”， the carbon emissions increased firstly and then decreased， but it remained to be seen whether the carbon emissions reached a peak； carbon emissions from aquatic feed was the largest carbon source； ② due to the affection of the rapid development of aquaculture， the carbon sinks experienced a rise in volatility， and aquaculture became the primary source of carbon sinks； ③aquaculture and fishing industry were both dual in carbon cycle， and they were more carbon source in China with over 3×10⁷ t of carbon not being neutralized. This paper set reasonable goals of carbon peak and neutralization for aquaculture and fishing industry， based on the big demand of aquatic products and the high-quality green development of aquaculture and fishing industry in China. In order to achieve the carbon goals， this paper proposed technical paths of reducing emissions in key links and expanding fishery sinks， social management methods for exploring fishery carbon trading mechanism and strengthening policy guidance. This paper provided useful reference for supporting China’s aquaculture and fishing industry to achieve carbon peak and carbon neutralization goals， and promote the transformation and upgrade of China’s aquaculture and fishing industry.

Key words: aquaculture and fishing industry, carbon emission, carbon sink, “double carbon” goals, fishery industry

摘要：

在碳达峰、碳中和大背景下，设定和践行具有行业特色的“双碳”目标，对推动我国渔业绿色高质量发展和助力国家“双碳”战略具有现实意义。渔业以水产养殖与捕捞业为主要产业形式，具有碳源碳汇双重属性。基于已有碳排放和碳汇核算方法，探索中国水产养殖与捕捞业“双碳”目标及实现路径，分析发现：①2011—2020年，受产业规模扩大和“减船转产”政策双重影响，水产养殖与捕捞业的碳排放量先增后降，当前饲料投喂碳排放为水产养殖与捕捞业的首要碳源；②受养殖业快速发展的影响，水产养殖与捕捞业总碳汇波动上升，养殖碳汇超过捕捞碳汇；③水产养殖与捕捞业更偏碳源属性，超3 000万t碳未实现中和。综合中长期水产品需求压力和产业绿色高质量发展形势，设定了符合水产养殖与捕捞行业特色的 “双碳”目标，并提出重点环节减排、扩大渔业增汇的技术路径以及探索渔业碳汇交易机制、强化政策支持引导的社会管理路径。期望助力我国水产养殖与捕捞业实现碳达峰、碳中和目标，推动水产养殖与捕捞业由粗放、低效、高耗能向集约、高效、绿色产业转型，从而为促进产业发展和民众富裕提供有益参考。

关键词: 水产养殖与捕捞业, 碳排放, 碳汇, “双碳”目标, 渔业

CLC Number:

Xue LI, Zifei LIU, Mingjun ZHAO, Lejun XU, Huiwu SUN. Carbon Peak and Carbon Neutralization Goals and Realization Paths of the Aquaculture and Fishing Industry in China[J]. Journal of Agricultural Science and Technology, 2022, 24(11): 13-26.

李雪, 刘子飞, 赵明军, 徐乐俊, 孙慧武. 我国水产养殖与捕捞业“双碳”目标及实现路径[J]. 中国农业科技导报, 2022, 24(11): 13-26.

Figures/Tables 13

References 31

1	徐皓,刘晃,张建华,等.我国渔业能源消耗测算[J].中国水产, 2007(11):74-76, 78.
2	唐启升. 碳汇渔业与海水养殖业——战略性新兴产业[N]. 中国渔业报,2010-11-29(007).
3	徐皓,张祝利,张建华,等.我国渔业节能减排研究与发展建议[J].水产学报,2011,35(3):472-480.
	XU H, ZHANG Z L, ZHANG J H, et al.. The research and development proposals on fishery energy saving and emission reduction in China [J]. J. Fisheries China,2011,35(3):472-480.
4	PARKER R, HARTMANN K, GREEN B S, et al.. Environmental and economic dimensions of fuel use in Australian fisheries [J]. J. Cleaner Production, 2015, 87:78-86.
5	岳冬冬,王鲁民,王茜,等.我国海洋捕捞渔业温室气体排放量估算与效率分析[J].山西农业科学,2013,41(8):873-876.
	YUE D D, WANG L M, WANG Q, et al.. GHG emissions estimation and efficiency analysis of marine fisheries [J]. Shanxi J. Agric. Sci., 2013,41(8):873-876.
6	李晨,迟萍,邵桂兰.我国远洋渔业碳排放与行业经济增长的响应关系研究——基于脱钩理论与LMDI分解的实证分析[J].科技管理研究,2016,36(6):233-237, 244.
	LI C, CHI P, SHAO G L. Research on the responsive relationship between China’s deep-sea fishery carbon emissions and industry economic growth: an empirical analysis based on decoupling theory and LMDI Decomposition [J]. Sci. Technol. Manage. Res., 2016,36(6):233-237, 244.
7	金书秦,陈洁.我国水产养殖的直接能耗及碳排放研究[J].中国渔业经济, 2012,30(1):73-82.
	JIN S Q, CHEN J. A study on energy consumption and carbon emission of China’s aquaculture [J]. Chin. Fisheries Econ., 2012,30(1):73-82.
8	刘晃,车轩.中国水产养殖二氧化碳排放量估算的初步研究[J].南方水产, 2010,6(4):77-80.
	LIU H, CHE X. Elementary study on evaluation of CO₂ emissions from aquaculture in China [J]. Southern Fisheries, 2010,6(4):77-80.
9	李晨,李昊玉,孔海峥,等.中国渔业生产系统隐含碳排放结构特征及驱动因素分解[J].资源科学, 2021, 43(6): 1166-1177.
	LI C, LI H Y, KONG H Z, et al.. Structural characteristics and driving factors of embodied carbon emissions from fishery production system in China [J]. Resour. Sci., 2021, 43(6): 1166-1177.
10	IPCC. IPCC fourth assessment report-AR4-climate change 2007: the physical science basis [R]. Intergovernmental Panel on Climate Change, 2007.
11	唐启升,蒋增杰,毛玉泽.渔业碳汇与碳汇渔业定义及其相关问题的辨析[J].渔业科学进展,2022, 43(5): 1-7.
	TANG Q S, JIANG Z J, MAO Y Z. Clarification on the definitions and its relevant issues of fisheries carbon sink and carbon sink risheries [J]. Progress Fishery Sci., 2022, 43(5): 1-7.
12	WILSON R W, MILLERO F J, TAYLOR R J, et al.. Contribution of fish to the marine inorganic carbon cycle [J]. Science, 2009, 323(5912): 359-363.
13	FODRIE F J, RODRIGUEZ A B, GITTMAN R K, et al.. Oyster reefs as carbon sources and sinks [J/OL]. Proc. Biol., 2017, 284(1859):20170891 [2022-07-21]. .
14	MARBÀN, ARIAS-ORTIZ A, MASQUÉP, et al.. Impact of seagrass loss and subsequent revegetation on carbon sequestration and stocks [J]. J. Ecol., 2015,103: 296-302.
15	GE C, WANG H, KAN M, et al.. Carbon sequestration within silica bodies extracted from kelp cultured in the east china sea [J]. Silicon, 2015, 9:1-6.
16	张继红,方建光,唐启升.中国浅海贝藻养殖对海洋碳循环的贡献[J].地球科学进展, 2005(3):359-365.
	ZHANG J H, FANG J G, TANG Q S. The contribution of shellfish and seaweed mariculture in China to the carbon cycle of coastal ecosystem [J]. Adv. Earth Sci., 2005(3):359-365.
17	岳冬冬,王鲁民.我国海水养殖贝类产量与其碳汇的关系[J].江苏农业科学, 2012, 40(11):246-248.
	YUE D D, WANG L M. The relationship between marine aquaculture shellfish production and its carbon sink in China [J]. Jiangsu J. Agric. Sci.,2012, 40(11):246-248.
18	岳冬冬,吕永辉,于航盛,等.基于营养级法的福建省淡水捕捞渔业碳汇量评估探析[J].中国渔业经济,2018,36(5):74-81.
	YUE D D, LYU Y H, YU H S, et al.. Research on the evaluation of the freshwater capture fisheries carbon sinks in Fujian province based on trophic level method [J]. Chin. Fishery Econ., 2018,36(5):74-81.
19	PERSHING A J, CHRISTENSEN L B, RECORD N R, et al.. The impact of whaling on the ocean carbon cycle: why bigger was better [J/OL]. PLoS One, 2010, 5(8):e12444 [2022-07-21]. .
20	张波,孙珊,唐启升.海洋捕捞业的碳汇功能[J].渔业科学进展,2013,34(1):70-74.
	ZHANG Bo SUN S, TANG Q S. Carbon sink by marine fishing industry [J]. Progress. Fishery Sci., 2013,34(1):70-74.
21	岳冬冬,王鲁民,方海,等.淡水捕捞渔业碳汇量评估探析——以浙江省的生产调查样本数据为例[J].中国农业科技导报,2017,19(11):117-124.
	YUE D D, WANG L M, FANG H, et al.. Evaluation of carbon sinks in freshwater fisheries—acase research on the sample production survey data of Zhejiang Province [J]. J. Agric. Sci. Technol., 2017,19(11):117-124.
22	岳冬冬,王鲁民,方海,等.基于碳平衡的中国海洋渔业产业发展对策探析[J].中国农业科技导报,2016,18(4):1-8.
	YUE D D, WANG L M, FANG H, et al.. Development strategy of marine fisheries in China based on the carbon balance [J]. J. Agric. Sci. Technol., 2016,18(4):1-8.
23	陈少莲.鱼类及其在水体的物质循环中的作用[M]// 刘建康.东湖生态学研究(一).北京:科学出版社,1993:292-378.
24	解绶启,刘家寿,李钟杰.淡水水体渔业碳移出之估算[J].渔业科学进展, 2013,34(1):82-89.
	XIE S Q, LIU J S, LI Z J. Evaluation of the carbon removal by fisheries and aquaculture in fresh water bodies [J]. Progress Fishery Sci., 2013,34(1):82-89.
25	吴斌,王海华,习宏斌.中国淡水渔业碳汇强度估算[J].生物安全学报,2016,25(04):308-312.
	WU B, WANG H H, XI H B. The carbon sink capacity of the Chinese freshwater aquaculture [J]. J. Biosafety, 2016,25 (4): 308-312.
26	邵桂兰,褚蕊,李晨.基于碳排放和碳汇核算的海洋渔业碳平衡研究——以山东省为例[J].中国渔业经济,2018,36(4):4-13.
	SHAO G L, CHU R, LI C. Research on carbon balance of marine fishery in Shandong province using the calculation results of carbon emission and carbon sink [J]. Chin. Fishery Econ., 2018,36(4):4-13.
27	USSR. The Great Soviet Encyclopedia [M]. Soviet Encyclopedia Press,1979.
28	BENEDICT F G, OSTERBERG E. The elementary composition and heat of combustion of human fat [J]. Am. J. Physiol., 1900, 4(2): 69-76.
29	赵明军,孙慧武,王宇光,等.基于居民营养需求的中长期水产品供给与消费研究[J].中国渔业经济,2019,37(6):1-14.
	ZHAO M J, SUN H W, WANG Y G, et al.. Study of the supplu and consumption of aquatic products in the medium and long term based on the national nutrition demand [J]. Chin. Fisheries Econ., 2019, 37(6):1-14.
30	王宇光,赵明军,赵蕾.居民膳食平衡目标下我国水产品消费研究[J].中国水产,2021(10):48-50.
	WANG Y G, ZHAO M J, ZHAO L. Research on aquatic product consumption in China under the goal of dietary balance of residents. [J]. Chin. Fisheries, 2021(10):48-50.
31	刘子飞,李飞,夏佳佳.大水面生态渔业发展的现状、困境与对策[J].生态经济,2022,38(3):142-148.
	LIU Z F, LI F, XIA J J. Research on development status, issues and countermeasures for ecological fishery of large-scale water [J]. Ecol. Econ., 2022, 38(3):142-148.

营养成分 Nutrient	比例 Ratio/%	碳质量分数 Mass fraction of C/%
蛋白质 Protein	35.00	52.55
脂肪 Fat	10.00	76.50
碳水化合物Carbohydrate	25.00	40.00
其他 Others	30.00	—

营养成分 Nutrient	比例 Ratio/%	碳质量分数 Mass fraction of C/%
蛋白质 Protein	35.00	52.55
脂肪 Fat	10.00	76.50
碳水化合物Carbohydrate	25.00	40.00
其他 Others	30.00	—

养殖方式Aquaculture mode	类别 Category		海水 Seawater	淡水 Freshwater
工厂化养殖 Industrialized aquaculture	增氧 Oxygenation	水体投饲率Feed ratio/%	3	3
		饲料耗氧量 Oxygen consumption of feed/（kg·kg^-1）	0.5	0.5
		罗茨风机产氧 Oxygen production of Roots blower/（g·kWh^-1）	0.8	0.8
		年运行时间 Running time per year/d	200	200
	换水 Water renewal	次数 Times	4	4
		流量Flow/（m³·kWh^-1）	20	30
		运行时间 Running time per year/d	200	200
池塘养殖 Pond aquaculture	增氧 Oxygenation	需氧面积占比Percent of oxygenation area/%	80	80
		耗电量Power consumption/（kWh·hm^-2）	2.25	2.24
		使用频次Using frequency/ （h·d^-1）	4	4
		年运行时间 Running time per year/d	200	200
	换水 Water renewal	平均水深Average depth/m	1	1.5
		换水率Water renewal ratio/%	2	2
		流量Flow/（m³·kWh^-1）	60	60
		年运行时间 Running time per year/d	200	200

养殖方式Aquaculture mode	类别 Category		海水 Seawater	淡水 Freshwater
工厂化养殖 Industrialized aquaculture	增氧 Oxygenation	水体投饲率Feed ratio/%	3	3
		饲料耗氧量 Oxygen consumption of feed/（kg·kg^-1）	0.5	0.5
		罗茨风机产氧 Oxygen production of Roots blower/（g·kWh^-1）	0.8	0.8
		年运行时间 Running time per year/d	200	200
	换水 Water renewal	次数 Times	4	4
		流量Flow/（m³·kWh^-1）	20	30
		运行时间 Running time per year/d	200	200
池塘养殖 Pond aquaculture	增氧 Oxygenation	需氧面积占比Percent of oxygenation area/%	80	80
		耗电量Power consumption/（kWh·hm^-2）	2.25	2.24
		使用频次Using frequency/ （h·d^-1）	4	4
		年运行时间 Running time per year/d	200	200
	换水 Water renewal	平均水深Average depth/m	1	1.5
		换水率Water renewal ratio/%	2	2
		流量Flow/（m³·kWh^-1）	60	60
		年运行时间 Running time per year/d	200	200

参数 Parameter		扇贝 Pectinidae	蛤 Mactra	牡蛎 Ostrea gigas thunberg	贻贝 Mytilus edulis	其他 Others
湿、干重转换系数 Wet/dry weight conversion factor		63.89	52.55	65.10	75.28	64.21
质量比重 Mass proportion/%	软组织 Soft tissue	14.35	1.98	6.14	8.47	11.41
质量比重 Mass proportion/%	壳 Shell	85.65	98.02	93.86	91.53	88.59
碳含量 Carbon content/%	软组织 Soft tissue	42.84	44.90	45.98	44.40	43.87
碳含量 Carbon content/%	壳 Shell	11.40	11.52	12.68	11.76	11.44
碳汇系数 Carbon sink coefficient/%		10.17	6.40	9.59	10.93	9.72