Wednesday, July 31, 2013

The Blaschka Glass Menagerie Dynasty

The Natural History Museum (NHM)
German glass artists Leopold (1822-1895) and his son Rudolf (1857-1939) Blaschka produced wonderous glass anotomical models of organisms, including many marine invertebrates and flowers, which went on to populate the natural history museums of the world, universities and aquaria. These were creatures and plants they wished to display but which were difficult to preserve and often rarely observed. Previously, models were limited to drawings, pressed specimens, photos, paper and wax models. The famous Blaschka models not only provided views of anatomy in a full three dimensions, they were beautiful and quite accurate. There were other glass artists making zoological and botanical models, but the Blaschkas were known for their attention to detail - and for the perhaps unexpected way this very specialized career in scientific illustration (in glass) was passed from father to son and how this one family of scientific artisans produced so much of the world's collections of glass specimen models.

Octopus from the Cornell collection
Leopold even kept an aquarium in his home to study these creatures for his models.

Physalia arethusa (glass model of a Portuguese Man-of-War). There are about two hundred tentacles made of thin coloured glass, supported and attached by fine copper wires. (via National Museum Wales)  
 Despite its unexpected resemblance to the 'Golden Snitch' of Harry Potter and the imaginary game of Quidditch fame, the 'sea gooseberry' is a is a common genus of Ctenophora.
A 'sea gooseberry' or 'comb jellyfish' (Pleurobranchia rhododactyla).
Length: 205mm.

Charybdea periphyllum (glass model)
Pelagia cyanella (glass model).
Sea anenomies displaying a territorial dispute.
Here S. troglodytes fires stinging cells at A. mesembryanthemum who has ventured too close. This behaviour was observed first hand in the aquaria at the Blaschka's home.
Base: 180x110mm. Height: 80mm. (via National Museum Wales)
 
collection of 5 marine invertebrates in glass from the Aurelia aurita, Berenice euchroma, Physophora hydrostatica and Pelagia noctiluca species from the Fonazione Scienzia e Tecnia, Florence, Italy

Highly magnified model of single cell amoeba (Amoeba proteus).
Diameter: 120mm.
Life sized model of marine snail (Cerithium vulgatum) with glass body fitted in real shell.
Length: 90mm.
From the Harvard glass flower collection

Thursday, July 18, 2013

Quantum Mechanical Art

  Richard Feynman, & Feynman diagrams,  by Hannah Wilson
Quantum mechanics is the physics of the very small, the subatomic. On that scale classical physics we know intuitively, the physics of our everyday life and human-sized things, breaks down. Strange things can happen; objects (or wave-particles at least) can go through walls or seem to go through two different French doors at the same time. We can't investigate this world without literally interfering with it. We can only know something's position or momentum precisely; it's either where or how fast, but not both. We can only meaningfully make predictions about groups of things: half of these radioactive nuclei will decay in one half-life; the electrons going through these two slits will make this specific interference pattern, but don't ask me to explain what any individual electron will do, and so forth. This sort of anti-intuitive arena inspires either purely mathematical and probabilistic or very metaphorical descriptions. Some things are unknowable, based on the fundamental laws of physics. Working in this Wonderland and believing seven impossible things before breakfast can inspire creativity and often visual thinking in physicists. This weird world within is also a source of inspiration to visual artists.

Edward Tufte, All Possible Photons
One of the most amazing and distinctly visual tools in the quantum mechanic's tool box is the Feynman diagram. These elegant schematics of lines and assorted squiggles not only depict the sorts of things which can occur in any given interaction in the quantum world, they actually allow us to calculate probabilities; they actually represent and take the place of complex equations - and believe you me are far easier to work with.  Everyone would rather draw a series of little drawings than calculate probability amplitudes by integrating over many variables. They are quite easy to read, once you know the vocabulary of particles, antiparticles, force carriers - real and virtual - and they can describe everything which can occur in the quantum world. It's perhaps no surprise that preeminent information designer and champion of elegance, simplicity and meaning in scientific graphics, Edward Tufte would be inspired to creature sculptures of Feynman diagrams with stainless steel tubing.


Richard Feynman, Equations and Sketches, 1985
Feynman himself of course had an artistic side. It is well-known that he played the bongos, or painted some of his own diagrams on his van. You may have heard his 'Ode to a flower' - a beautiful refutation of the bias that beauty is to only be found in art, and it is lost on science. The short monologue is animated by Fraser Davison below.  He himself started to draw, at age 44, shortly after developing his visual language for quantum mechanics (via Brain Pickings). He traded art for science lessons with his friend the doubter that scientists could see the beauty of a flower. His daughter Michelle even gathered his drawings into a short book The Art of Richard P. Feynman: Images by a Curious Character. 


Richard Feynman - Ode To A Flower from Fraser Davidson on Vimeo.

Oliver Jeffers, 'Still life with light and lightbulb'
Painter and illustrator Oliver Jeffers got inspired by quantum mechanics, and wave-particle duality. As he himself explains below, we find that if you set up and experiment to look for a wave, light (and in fact electrons, or other quantum wave/particles) will behave like a wave; whereas, if you set up an experiment to look for a particle light (and other wavicles) will behave like a particle.  His painting 'Still life with light and lightbulb' includes the de Broglie equation, relating wavelength to momentum of anything! (So particles, with mass and momentum have wavelengths, and photons which can seem like waves have momentum like particles).





Julian Voss-Andreae, The Well (Quantum Corral), 2009
Gilded wood, 3” x 13” x 12” x (6 x 34 x 31 cm)
Julian Voss-Andreae is a sculptor who also pursued graduate research in quantum mechanics. His background comes out in his sculptures of 'Quantum Objects' and molecular structures. A quantum coral is  a a ring of atoms arranged in an arbitrary shape on a substrate. Lutz, Eigler and Crommie (1993), for instance used a ring of iron (which is ferromagnetic) atoms on copper to reflect the surface electrons into a predicted wave pattern - 'coralling' them into the 'fence' of iron. Voss-Andreae used their specific data to create his sculpture The Well (as in a quantum mechanical well or potential energy well in which electrons are trapped). Like any wavicle, the nature of his 'Quantum Man' sculpture depends on how you look at it, appearing quite solid or nearly disappearing altogether. He also makes beautiful sculptures of structures right at the classic/quantum interface... where the weird world of the very small gets to sufficiently large molecular structures to obey the physics of our everyday world, like 'Quantum Buckeyball' and the many complex protein molecules. His graduate work incidentally, showed that single object as large as Carbon-60, a Buckyball, would behave like a wave, going through two slits at once (just like electrons in the famous double slit experiment).

Julian Voss-Andreae, Quantum Man


Julian Voss-Andreae, Quantum Buckeyball

Niels Bohr portrait 4
Ele Willoughby, Niels Bohr, 2010
My own artwork on the subject of quantum mechanics is a little less literal perhaps... though my linocut portrait of Niels Bohr includes the Bohr model explanation of the Balmer series - the spectral lines given off by excited hydrogen which are in the visible range, showing Bohr's electron orbits (which we now know are a bit too simplistic a model) at the right ratio of diameters, and photons (shown as wavy lines, following Feynman's convention) given off as an electron falls from one given orbit to another lower energy state in the appropriate colours. The line spectrum you would see, if you spread the light given off with a prism, is shown below. I've also depicted Schrödinger's cat, one of the most famous thought experiments (or, really metaphors for the weirdness of quantum mechanics). Erwin Schrödinger proposed this hypothetical experiment to link the strangeness of the quantum world to our everyday world of big things like cats. He imagined a cat in a box with a vial of lethal poison which would rupture if and only if a radioactive particle had decayed - an individually unpredictable quantum event. Until you open the box, is the cat dead or alive? According to quantum mechanics, the wavefunction (or equation describing its state) is the superposition of that of dead and live cat... that is, equal parts live and dead... which of course, seems absurd. Whether the cat is alive or dead depends on when you look at it. Hence, I made a cat and poison vial in thermochromic temperature-dependant ink; sometimes they are apparent, sometimes they are not (or at least, it's too warm and they turn colourless).

Schroedinger1
Ele Willoughby, Schrödinger's Cat (coloured state), 2011

Schroedinger's cat isn't there
Ele Willoughby, Schrödinger's Cat (colourless state)




Thursday, July 4, 2013

The Paleobet

Rosemary Mosco of bird and moon describes herself as a nature lover with with a passion for science communication. She has a truely marvellous collection of illustrations and comics. You should check them out. As a fan of alphabets and prehistoric creatures, I can't resist sharing the Paleobet.



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