Human-Environment Systems, Boise State University, 1910 University Dr. Boise, ID 83725, USA; Trout Unlimited, 910 W Main St #342, Boise, ID, 83702, USA.
Human-Environment Systems, Boise State University, 1910 University Dr. Boise, ID 83725, USA.
J Environ Manage. 2024 Nov;370:122610. doi: 10.1016/j.jenvman.2024.122610. Epub 2024 Sep 27.
Invasive aquatic plants pose a significant threat to coastal wetlands. Predicting suitable habitat for invasive aquatic plants in uninvaded yet vulnerable wetlands remains a critical task to prevent further harm to these ecosystems. The integration of remote sensing and geospatial data into species distribution models (SDMs) can help predict where new invasions are likely to occur by generating spatial outputs of habitat suitability. The objective of this study was to assess the efficacy of utilizing active remote sensing datasets (synthetic aperture radar (SAR) and light detection and ranging (LiDAR) with multispectral imagery and other geospatial data in predicting the potential distribution of an invasive aquatic plant based on its biophysical habitat requirements and dispersal dynamics. We also considered a climatic extreme (lake water levels) during the study period to investigate how these predictions may change between years. We compiled a time series of 1628 field records on the occurrence of Hydrocharis morsus-ranae (European frogbit; EFB) with nine remote sensing and geospatial layers as predictors to train and assess the predictive capacity of random forest models to generate habitat suitability in Great Lakes coastal wetlands in northern Michigan, USA. We found that SAR and LiDAR data were useful as proxies for key biophysical characteristics of EFB habitat (emergent vegetation and water depth), and that a vegetation index calculated from spectral imagery was one of the most important predictors of EFB occurrence. Our SDM using all predictors yielded the highest mean overall accuracy of 88.3% and a true skill statistic of 75.7%. Two of the most important predictors of EFB occurrence were dispersal-related: 1) distance to the nearest known EFB population (m), and 2) distance to nearest public boat launch (m). The area of highly suitable habitat (pixels assigned ≥0.8 probability) was 74% larger during a climatically extreme high water-level year compared to an average year. Our findings demonstrate that active remote sensing can be integrated into SDM workflows as proxies for important drivers of invasive species expansion that are difficult to measure in other ways. Moreover, the importance of a proxy variable for endogenous dispersal (distance to nearest known population) in these SDMs indicates that EFB is currently spreading, and thereby less influenced by within-site dynamics such as interspecific competition. Lastly, we found that extreme climatic conditions can dramatically change this species' niche, and therefore we recommend that future studies include dynamic climate conditions in SDMs to more accurately forecast the spread during early invasion stages.
入侵水生植物对沿海湿地构成重大威胁。预测未受入侵但脆弱的湿地中入侵水生植物的适宜栖息地仍然是防止这些生态系统进一步受到破坏的关键任务。将遥感和地理空间数据集成到物种分布模型 (SDM) 中,可以通过生成栖息地适宜性的空间输出,帮助预测新入侵可能发生的地点。本研究的目的是评估利用主动遥感数据集(合成孔径雷达 (SAR) 和光探测和测距 (LiDAR) 与多光谱图像和其他地理空间数据)根据其生物物理栖息地要求和扩散动态预测入侵水生植物潜在分布的功效。我们还考虑了研究期间的气候极值(湖泊水位),以调查这些预测在不同年份之间可能如何变化。我们编制了 Hydrocharis morsus-ranae(欧洲蛙草;EFB)发生的 1628 个时间序列记录,其中包括 9 个遥感和地理空间层作为预测因子,以训练和评估随机森林模型的预测能力,以生成美国密歇根州北部大湖沿海湿地的栖息地适宜性。我们发现,SAR 和 LiDAR 数据可用作 EFB 栖息地关键生物物理特征(挺水植被和水深)的代理,并且从光谱图像计算的植被指数是 EFB 发生的最重要预测因子之一。我们使用所有预测因子的 SDM 产生了最高的总体平均准确度 88.3%和真实技能统计量 75.7%。EFB 发生的两个最重要的预测因子与扩散有关:1)到最近已知 EFB 种群的距离(m),2)到最近公共船只下水处的距离(m)。在气候极端高水位年,高度适宜栖息地(分配概率≥0.8 的像素)的面积比平均年份大 74%。我们的研究结果表明,主动遥感可以集成到 SDM 工作流程中,作为入侵物种扩张的重要驱动因素的代理,这些因素很难以其他方式进行测量。此外,这些 SDM 中内源性扩散(到最近已知种群的距离)代理变量的重要性表明,EFB 目前正在扩散,因此受种内竞争等站点内动态的影响较小。最后,我们发现极端气候条件会极大地改变该物种的生态位,因此我们建议未来的研究在 SDM 中包含动态气候条件,以更准确地预测早期入侵阶段的传播。
