Moss Green Halite

https://player.vimeo.com/video/128896761?title=0&byline=0&portrait=0

cgg stanzel 2015 studio kura

June 8th is World Oceans Day - a day to celebrate the oceans that connect and sustain all of us. Our colleagues at the Biodiversity Heritage Library have been leading up to today with a series of blog posts  exploring historic publications that mark important milestones in the progress of marine bioscience research and ocean exploration.

Top image: Whale shark from  Illustrations of the zoology of South Africa… v.4 (1845) Middle top : radiolarians and jellyfish from Ernst Haeckle’s Kunstformen der Natur (1904) Middle bottom: giant squid from Cassell’s Natural History v.5-6 and cuttlefish from  Voyage de la corvette l'Astrolabe Mollusques and Zoophytes Atlas (1833) Bottom: deep sea fish from  Valdivia Expedition…1898-1899. Bd. 15, T. 1

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Physicists resolve long-standing mystery of structure-less transition

We normally associate conduction of electricity with metals. However, some of the high measured conductivities are found in certain organic molecular crystals. Metallic, semiconducting and even superconducting properties can be achieved in these materials, which have interested scientists for decades. Changing temperature or pressure causes phase transitions in the crystal structure of molecular conductors and their related conduction properties. Scientists can usually determine the crystal structure using X-ray diffraction. However, structural change accompanying phase transition in a particular organic crystal (TMTTF)2PF6 has defied examination for almost 40 years.

Now, a research team at Nagoya University has finally explained the mysterious structural changes of this phase transition and its related electronic behavior.

“Researchers have questioned that the TMTTF (tetramethyltetrathiafulvalene) salt shows a charge disproportionation transition at 67 Kelvin but no relevant changes in its crystal structure. This transition is a long-standing mystery known as a ‘structure-less transition’,” explains lead author Shunsuke Kitou.

Read more.

https://player.vimeo.com/video/58293122?title=0&byline=0&portrait=0

Hannah Reber, “Untitled (spin the bottle)”, 2013, installation version #3

Sand and water make a remarkable team when it comes to building. But the substrate – the surface you build on – makes a big difference as well. Take a syringe of wet sand and drip it onto a waterproof surface (bottom right), and you’ll get a wet heap that flows like a viscous liquid. Drop the same wet sand onto a surface covered in dry sand (bottom left), and the drops pile up into a tower. Watch the sand drop tower closely, and you’ll see how new drops first glisten with moisture and then lose their shine. The excess water in each drop is being drawn downward and into the surrounding sand through capillary action. This lets the sand grains settle against one another instead of sliding past, giving the sand pile the strength to hold its weight upright. (Video and image credit: amàco et al.)

Samuel W. Hall. Corona of an Eclipse, Moon Hiding Lower and Upper Limb of Sun, Eclipse of the Sun, Moon Hiding Upper and Lower Limb of Sun, Comparative Size of the Planets, Size of the Sun, Elliptical Orbit. Sunshine and Moonlight; with; also, a Flash of Comets, Meteors and Shooting Stars, and a Twinkle of Starlight. 1889.  Contd from here

NGC 4725, One-Armed Spiral Galaxy