Hyperspectral Reflectance Characteristics of Cyanobacteria

Advances in Remote Sensing Pub Date : 2021-07-28 DOI:10.4236/ars.2021.103004

Terrence Slonecker, Brittany Bufford, J. Graham, K. Carpenter, Dan Opstal, N. Simon, Natalie C. Hall

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引用次数: 2

Abstract

Potentially harmful cyanobacterial blooms are an emerging environmental concern in freshwater bodies worldwide. Cyanobacterial blooms are generally caused by high nutrient inputs and warm, still waters and have been appearing with increasing frequency in water bodies used for drinking water supply and recreation, a problem which will likely worsen with a warming climate. Cyanobacterial blooms are composed of genera with known biological pigments and can be distinguished and analyzed via hyperspectral image collection technology such as remote sensing by satellites, airplanes, and drones. Here, we utilize hyperspectral microscopy and imaging spectroscopy to characterize and differentiate several important bloom-forming cyanobacteria genera obtained in the field during active research programs conducted by US Geological Survey and from commercial sources. Many of the cyanobacteria genera showed differences in their spectra that may be used to identify and predict their occurrence, including peaks and valleys in spectral reflectance. Because certain cyanobacteria, such as Cylindrospermum or Dolichospermum, are more prone to produce cyanotoxins than others, the ability to differentiate these species may help target high priority waterbodies for sampling. These spectra may also be used to prioritize restoration and research efforts to control cyanobacterial harmful algal blooms (CyanoHABs) and improve water quality for aquatic life and humans alike.

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蓝藻的高光谱反射特性

潜在有害的蓝藻华是一个新兴的环境问题，在世界各地的淡水机构。蓝藻繁殖通常是由高营养投入和温暖、静止的水域引起的，并且在用于饮用水供应和娱乐的水体中出现的频率越来越高，这一问题可能会随着气候变暖而恶化。蓝藻华由具有已知生物色素的属组成，可以通过卫星、飞机和无人机遥感等高光谱图像收集技术进行区分和分析。在这里，我们利用高光谱显微镜和成像光谱学来表征和区分几个重要的蓝藻属，这些蓝藻属是在美国地质调查局开展的积极研究项目中获得的，也来自商业来源。许多蓝藻属在光谱上表现出差异，这可以用来识别和预测它们的发生，包括光谱反射率的峰和谷。因为某些蓝藻，如圆筒藻或Dolichospermum，比其他蓝藻更容易产生蓝藻毒素，区分这些物种的能力可能有助于确定优先采样的水体。这些光谱也可用于优先恢复和研究工作，以控制蓝藻有害藻华(CyanoHABs)和改善水生生物和人类的水质。

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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Advances in Remote Sensing

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