乱流 Date: 09 June 2025 Credit: ロスティ (2025), J. Fluid Mech., 1012, R5. CC BY-NC 4.0. CC BY-NC 4.0 Download full-resolution image Tags Research Share on: Related Images Turbulence A chaotic, turbulent flow. Professor Pinaki Chakraborty at the time of his arrival at OIST (2012) Professor Pinaki Chakraborty arrived at OIST in 2012. Energy flows differently in turbulent non-Newtonian fluids than in turbulent Newtonian fluids. Dissipation in a Newtonian fluid (left) and an elastoviscoplastic fluid (right). Solid regions are shown in grayscale and liquid regions are shown in color. Figure 1. Relationship between corals and Symbiodinium in the supergroups of eukaryotes The Marine Genomics Unit of OIST has decoded the genome of the algae Symbiodinium minutum. The paper was published in the online version of Current Biology on July 11. This is a major advance in understanding the complex ecology of coral reefs. Figure 2. A symbiotic relationship between corals and Symbiodinium The Marine Genomics Unit of OIST has decoded the genome of the algae Symbiodinium minutum. The paper was published in the online version of Current Biology on July 11. This is a major advance in understanding the complex ecology of coral reefs.
Professor Pinaki Chakraborty at the time of his arrival at OIST (2012) Professor Pinaki Chakraborty arrived at OIST in 2012.
Professor Pinaki Chakraborty at the time of his arrival at OIST (2012) Professor Pinaki Chakraborty arrived at OIST in 2012.
Energy flows differently in turbulent non-Newtonian fluids than in turbulent Newtonian fluids. Dissipation in a Newtonian fluid (left) and an elastoviscoplastic fluid (right). Solid regions are shown in grayscale and liquid regions are shown in color.
Energy flows differently in turbulent non-Newtonian fluids than in turbulent Newtonian fluids. Dissipation in a Newtonian fluid (left) and an elastoviscoplastic fluid (right). Solid regions are shown in grayscale and liquid regions are shown in color.
Figure 1. Relationship between corals and Symbiodinium in the supergroups of eukaryotes The Marine Genomics Unit of OIST has decoded the genome of the algae Symbiodinium minutum. The paper was published in the online version of Current Biology on July 11. This is a major advance in understanding the complex ecology of coral reefs.
Figure 1. Relationship between corals and Symbiodinium in the supergroups of eukaryotes The Marine Genomics Unit of OIST has decoded the genome of the algae Symbiodinium minutum. The paper was published in the online version of Current Biology on July 11. This is a major advance in understanding the complex ecology of coral reefs.
Figure 2. A symbiotic relationship between corals and Symbiodinium The Marine Genomics Unit of OIST has decoded the genome of the algae Symbiodinium minutum. The paper was published in the online version of Current Biology on July 11. This is a major advance in understanding the complex ecology of coral reefs.
Figure 2. A symbiotic relationship between corals and Symbiodinium The Marine Genomics Unit of OIST has decoded the genome of the algae Symbiodinium minutum. The paper was published in the online version of Current Biology on July 11. This is a major advance in understanding the complex ecology of coral reefs.
