Bio-optical properties of the Brazilian Abrolhos Bank’s shallow coral-reef waters

Thais A. G. Medeiros, M. Zoffoli, R. Frouin, F. D. Cortivo, G. M. Cesar, M. Kampel
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Abstract

The Abrolhos Bank harbors the richest coral reef ecosystem in the South Atlantic Ocean. It exhibits unique geomorphologic structures, is localized in shallow depths, and is divided into two reef regions with an inner arc close to the coast (3–20 m depth) and an outer deeper arc (5–30 m depth). This study aims to describe some bio-optical properties of the Abrolhos Bank waters and to evaluate the performance of the inversion Hyperspectral Optimization Processing Exemplar (HOPE) model, developed to retrieve optical properties in shallow waters, in the region. To this end, measurements at 75 stations during two field campaigns conducted during the 2013 and 2016 wet seasons were analyzed, and the HOPE model was applied to both in situ remote sensing reflectance (R rs ) spectra and PRecursore IperSpettrale della Missione Applicativa (PRISMA) imagery. Significant differences in optical and biological properties were found between the two arcs. The empirical relationships between chlorophyll-a concentration (Chl-a) and absorption coefficient of phytoplankton at 440 nm (a phy(440)) diverged from Bricaud’s models, suggesting differences in phytoplankton diversity and cell size. In both arcs, total non-water absorption coefficient at 440 nm (a T-w(440)) was dominated by colored dissolved organic matter (CDOM) by ∼60%. Absorption coefficient by CDOM (a cdom) presented a higher variability within the outer arc, with the lowest contribution from non-algal particles (NAPs), and the spectral slopes of a CDOM resembled those of the inner arc. The spectral slopes of the NAP absorption coefficient suggested a dominance by organic rather than mineral particles that probably originated from biological production. The HOPE model applied to in situ R rs performed satisfactorily for depth in the Abrolhos Bank waters, although retrievals of a phy(440), CDOM plus NAP (a dg(440)) and a T-w(440) were underestimated with a relative bias of −27.9%, −32.1% and −45.8%, respectively. The HOPE model retrievals from the PRISMA image exhibited low a phy(440) values over the whole scene and the highest a dg(440) values in the Caravelas river plume. Very shallow depths (≤3 m), bottom substrate reflectance used as input in the HOPE model, model parametrization associated with the water complexity in the study site, and uncertainties associated to R rs measurements used as input might be responsible for differences found when comparing HOPE retrievals with in situ measurements.
巴西Abrolhos浅海珊瑚礁水域的生物光学特性
Abrolhos浅滩拥有南大西洋最丰富的珊瑚礁生态系统。它具有独特的地貌结构,位于浅水深处,分为两个礁区,内弧靠近海岸(3-20米深),外弧较深(5-30米深)。本研究旨在描述Abrolhos Bank水域的一些生物光学特性,并评估该地区用于检索浅水光学特性的反演高光谱优化处理范例(HOPE)模型的性能。为此,对2013年和2016年雨季进行的两次野外活动中75个站点的测量结果进行了分析,并将HOPE模型应用于原位遥感反射率(R rs)光谱和precursoiperspettrale della Missione Applicativa (PRISMA)图像。在这两种弧线之间发现了光学和生物学特性的显著差异。叶绿素-a浓度(Chl-a)与浮游植物440 nm吸收系数(a phy(440))之间的经验关系与Bricaud的模型不同,表明浮游植物多样性和细胞大小存在差异。在这两个弧线中,440 nm处的总非水吸收系数(a T-w(440))由彩色溶解有机物(CDOM)主导,约占60%。CDOM的吸收系数在外弧内表现出较高的变异性,非藻粒子(NAPs)的贡献最小,CDOM的光谱斜率与内弧相似。NAP吸收系数的光谱斜率表明有机颗粒占主导地位,而不是可能来自生物生产的矿物颗粒。应用于原位R rs的HOPE模型对Abrolhos Bank水域的深度表现令人满意,尽管检索的phy(440), CDOM加NAP (a dg(440))和T-w(440)被低估了,相对偏差分别为- 27.9%,- 32.1%和- 45.8%。从PRISMA图像中检索的HOPE模型显示,整个场景的a - phy值较低(440),而卡拉维拉斯河羽流的a - dg值最高(440)。非常浅的深度(≤3米)、作为HOPE模型输入的底部基质反射率、与研究地点的水复杂性相关的模型参数化,以及作为输入的rrs测量值相关的不确定性,可能是在比较HOPE反演结果与原位测量结果时发现差异的原因。
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