Plant Cuttings

Tag: phytoplankton

  • Detecting cyanobacterial blooms with NASA’s EMIT

    Detecting cyanobacterial blooms with NASA’s EMIT

    NASA’s EMIT technology utilizes spectroscopy to analyze minerals in Earth’s deserts and has expanded its utility by detecting phycocyanin in wastewater from the Tijuana River. This insight reveals potential health risks linked to harmful algal blooms, significantly aiding coastal water quality monitoring while addressing environmental concerns from nutrient enrichment.

  • Predictable red tides? [From algae to rice plants… II]

    Predictable red tides? [From algae to rice plants… II]

    This post discusses dinoflagellates and red tides. In particular it considers Karenia brevis and work by Shen Jean Lim et al., who have identified viruses in K. brevis harmful algal bloom (HABs). This discovery suggests potential viral control methods for mitigating such red tides and improving early warning of them.

  • The phytoplanktonic paradox [From algae to rice plants… I]

    The phytoplanktonic paradox [From algae to rice plants… I]

    Research by Muratore et al. reveals that different phytoplankton species exploit phosphorus at varied times, suggesting ‘temporal niche partitioning’ as a potential solution to the phytoplankton paradox and underlining the intricate dynamics of marine ecosystems.

  • Shedding light on marine algae…

    Shedding light on marine algae…

    Dakota McCoy et al. (2024) demonstrate how heart cockles (Corculum cardissa) utilize specialized windows in their shells to focus sunlight onto symbiotic dinoflagellates for photosynthesis. The windows transmit 11–62% of photosynthetically-active radiation while filtering harmful UV rays, suggesting an adaptive advantage for both the molluscs and their symbionts.