Mapping rice-crayfish co-culture (RCC) fields with Sentinel-1 and -2 time series in China's primary crayfish production region Jianghan Plain

IF 5.7 Q1 ENVIRONMENTAL SCIENCES Science of Remote Sensing Pub Date : 2024-07-16 DOI:10.1016/j.srs.2024.100151
Wenxia Tan , Xingcheng Wang , Lin Yan , Jun Yi , Tian Xia , Zhe Zeng , Gongliang Yu , Min Chai , Naga Manohar Velpuri , Apichaya Thaneerat
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Abstract

Crayfish is a high-risk invasive species with devastating impacts on freshwater ecosystems. Meanwhile, nicknamed “little lobster”, it is a popular food in many countries including China. The crayfish production in China increased from 1.13 to 2.39 million tons in 2017–2020, accounting for 97% global production. This phenomenal increase is attributed to the expansion of the rice-crayfish co-culture (RCC) farming mode whose area increased by 123% from 0.57 to 1.26 million ha in 2017–2020. However, the fast expansion of RCC is undertaken in an uncontrolled and unregulated manner, referred by some researchers as a “blind expansion”. It raises wide concerns on ecological risks (crayfish can escape in high-magnitude floods), endangerment of riverbanks (crayfish burrows), food security (reduced rice production), excessive water consumption, and greenhouse gas (methane) emission. It is thus urgent to accurately map the spatial distributions of RCC fields using satellite remote sensing data, so as to assess the ecological and environmental impacts and risks, and to better regulate the expansion. However, there are currently no practically-scalable approaches to reliably map RCC fields in large areas. In particular, there lack the knowledge on the relationship between satellite observations and on-ground biophysical processes in RCC fields. In this study, we conducted field surveys in RCC fields, and in particular, the daily water levels in RCC fields were measured for the complete year of 2020. The comparison of annual water-level time series and satellite-NDVI time series, combined with the RCC farming information collected in surveys, reveals how satellite observations vary in correspondences to on-ground biophysical processes in RCC fields; and importantly, it provides information on how RCC fields can be efficiently distinguished from other land covers using satellite data. Based on that, we propose an approach to map RCC fields from annual Sentinel-2 optical-wavelength and Sentinel-1 Synthetic Aperture Radar (SAR) time series, utilizing the annual water-occurrence frequency (AWF) and characteristic phenological features derived from the satellite data. This method was demonstrated in Jianghan Plain, the primary crayfish production region in China with an area of approximately 37,000 km2. A total of 273,365 ha (2733.65 km2) RCC field area in year 2020 was mapped, which accounted for 24.6% of the whole plain's cropland area (approximately 11,100 km2), meaning a significant proportion of the rice paddies were converted to RCC fields. The RCC mapping accuracies were validated using the samples collected in field surveys and also from Google Earth images, and was compared with the state-of-practice RCC mapping method using bi-seasonal optical-wavelength satellite images. The proposed method obtained 93.8% overall accuracy and 0.91 kappa coefficient, and outperformed the compared bi-seasonal method. The proposed method is scalable for large-area and multi-annual applications. Future research regarding improvements and applications is recommended.

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利用哨兵-1 和-2 时间序列绘制中国小龙虾主产区江汉平原的稻虾共作(RCC)田地图
小龙虾是一种高风险入侵物种,对淡水生态系统具有破坏性影响。同时,小龙虾绰号 "小龙虾",是包括中国在内的许多国家的大众美食。2017-2020 年,中国小龙虾产量从 113 万吨增至 239 万吨,占全球产量的 97%。这一惊人的增长得益于稻虾共作(RCC)养殖模式的扩大,其面积从 57 万公顷增加到 2017-2020 年的 126 万公顷,增长了 123%。然而,稻虾共作模式的快速扩张是在不受控制和监管的情况下进行的,被一些研究人员称为 "盲目扩张"。这引起了人们对生态风险(小龙虾会在特大洪水中逃逸)、河岸危害(小龙虾洞穴)、粮食安全(水稻减产)、过度耗水和温室气体(甲烷)排放等问题的广泛关注。因此,当务之急是利用卫星遥感数据准确绘制垃圾填埋场的空间分布图,以评估其对生态和环境的影响及风险,更好地调控其扩张。然而,目前还没有切实可行的方法来可靠地绘制大面积的 RCC 田分布图。特别是,人们对卫星观测数据与 RCC 实地生物物理过程之间的关系缺乏了解。在本研究中,我们对 RCC 田进行了实地调查,特别是测量了 2020 年全年 RCC 田的日水位。通过比较年度水位时间序列和卫星-NDVI 时间序列,并结合调查中收集到的 RCC 农田信息,揭示了卫星观测数据如何与 RCC 农田的地面生物物理过程相对应;重要的是,它提供了如何利用卫星数据将 RCC 农田与其他土地覆盖物有效区分开来的信息。在此基础上,我们提出了一种从年度哨兵-2 光波长和哨兵-1 合成孔径雷达(SAR)时间序列中绘制 RCC 田地图的方法,利用了从卫星数据中得出的年度水发生频率(AWF)和物候特征。该方法在江汉平原进行了演示,江汉平原是中国小龙虾的主要产区,面积约为 37,000 平方公里。绘制的 2020 年 RCC 田总面积为 273,365 公顷(2733.65 平方公里),占整个平原耕地面积(约 11,100 平方公里)的 24.6%,这意味着相当一部分稻田被转化为 RCC 田。利用实地调查收集的样本和谷歌地球图像验证了 RCC 测绘精度,并与使用双季光波卫星图像的现行 RCC 测绘方法进行了比较。所提出的方法获得了 93.8% 的总体准确率和 0.91 的卡帕系数,表现优于所比较的双季节方法。所提出的方法具有可扩展性,适用于大面积和多年度应用。建议今后在改进和应用方面开展研究。
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