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1. Zooplankton diel vertical migration during Antarctic summer

   https://doi.org/10.1016/j.dsr.2020.103324  

   Conroy, John A.; Steinberg, Deborah K.; Thibodeau, Patricia S.; Schofield, Oscar (August 2020, Deep Sea Research Part I: Oceanographic Research Papers)

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2. Vertical vs. horizontal transmission of the microbiome in a key disease vector, Ixodes pacificus

   https://doi.org/10.1111/mec.14391  

   Kwan, Jessica Y.; Griggs, Reid; Chicana, Betsabel; Miller, Caitlin; Swei, Andrea (December 2017, Molecular Ecology)
3. Extant mat microbes synchronize vertical migration to a diel tempo

   https://doi.org/10.1016/j.jglr.2022.10.006  

   Biddanda, Bopaiah A.; Weinke, Anthony D.; Stone, Ian P. (November 2022, Journal of Great Lakes Research)
4. Size and transparency influence diel vertical migration patterns in copepods

   https://doi.org/10.1002/lno.12461  

   Barth, Alex; Johnson, Rod; Stone, Joshua (November 2023, Limnology and Oceanography)

   Abstract Diel vertical migration (DVM) is a widespread phenomenon in aquatic environments. The primary hypothesis explaining DVM is the predation‐avoidance hypothesis, which suggests that zooplankton migrate to deeper waters to avoid detection during daylight. Copepods are the predominant mesozooplankton undergoing these migrations; however, they display massive morphological variation. Visual risk also depends on a copepod's morphology. In this study, we investigate hypotheses related to morphology and DVM: (H1) as size increases visual risk, increases in body size will increase DVM magnitude and (H2) if copepod transparency can reduce visual risk, increases in transparency will reduce DVM magnitude. In situ copepod images were collected across several cruises in the Sargasso Sea using an Underwater Vision Profiler 5. Copepod morphology was characterized from these images and a dimension reduction approach. Although in situ imaging offers challenges for quantifying mesozooplankton behavior, we introduce a robust method for quantifying DVM. The results show a clear relationship in which larger copepods have a larger DVM signal. Darker copepods also have a larger DVM signal, however, only among the largest group of copepods and not smaller ones. These findings highlight the complexity of copepod morphology and DVM behavior. 

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5. Swimming behaviors during diel vertical migration in veined squid Loligo forbesii

   https://doi.org/10.3354/meps14056  

   Cones, SF; Zhang, D; Shorter, KA; Katija, K; Mann, DA; Jensen, FH; Fontes, J; Afonso, P; Mooney, TA (June 2022, Marine Ecology Progress Series)

   Diel vertical migration (DVM) is a vital behavior for many pelagic marine fauna. Locomotory tactics that animals use during DVM define the metabolic costs of migrations and influence the risk of detection and capture by predators, yet, for squids, there is little understanding of the fine-scale movements and potential variability during these migrations. Vertical migratory behaviors of 5 veined squid Loligo forbesii were investigated with biologging tags (ITags) off the Azores Islands (central North Atlantic). Diel movements ranged from 400 to 5 m and were aligned with sunset and sunrise. During ascent periods, 2 squid exhibited cyclic climb-and-glide movements using primarily jet propulsion, while 3 squid ascended more continuously and at a lower vertical speed using mostly a finning gait. Descents for all 5 squid were consistently more rapid and direct. While all squid swam in both arms-first and mantle-first directions during DVM, mantle-first swimming was more common during upward movements, particularly at vertical speeds greater than 25 cm s -1 . The in situ variability of animal posture, swim direction, and gait use revealed behavioral flexibility interpreted as energy conservation, prey capture, and predator avoidance. 

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