Werner Nachtigall is a German zoologist and biologist. After graduating from high school in Augsburg, he studied at the Ludwig Maximilian University of Munich in the fields of natural sciences biology, physics, chemistry and geography with a diploma in Technical Biology and Bionics. From 1959 to 1961, he was research assistant at the Radiobiology Institute in Neuherberg, later in the Zoological Institute of the University of Munich. His research interests during this time gave rise to questions that later led to the foundation of the field of bionics in Germany. In 1967, he was a visiting professor at the University of California, Berkeley. In 1969, he was appointed professor and director of the Zoological Institute of Saarland University. In 1990, he initiated the field of study called "Technical Biology and Biomimetics" and also the "Society for Technical Biology and Bionics" of which he was the first chairman until 2003. After his retirement in 2002, he became head of the BMBF-funded Competence Network Biomimetics BIOKON at the University of Saarland.
Research
By making use of biostatistics, and also bringing together several scientific and engineering disciplines, his research which focused on mechanisms for movement in the animal kingdom led him to pioneer the field of bionics in Germany. Much of his published work centres on technology in the fields of biology, flight biomechanics and general bionics. In addition to technical scientific papers, he has published more than 30 popular books as well as articles which has stimulated interest in this emerging field. Professor Marianne Stokholm head of the Department of Architecture & Design at Aalborg university Denmark, writes: "The German biologist Werner Nachtigall has since the 1960's been occupied with bionics. His writing on the subject is among the best." Nachtigall formulated ten principles which he felt should undergird bionics:
1. The concept of biological design can be understood in analogous relation to the concept of technological design;
2. The structural relation of technical biology and bionics is of image and reflection;
3. The organism forms a functional whole;
4. Biological design follows the principle of "optimum integration"
5. The organism compensates for harmful overloading
6. The overall size of an organism defines its stability
7. An organism has environmental contact with the inorganic.
8. A form always meets multiple requirements
9. The organism is in contact with other organisms
10. The organism faces a permanent energy crisis
The biomechanist Steven Vogel in his book Life's devices: the physical world of animals and plants, writes, "Wherever nature has a structure, biologists have been painstakingly describing it, but most often paying little attention to mechanical functions. Nachtigall went the next step, gathering a vast collection of structural schemes for attachment, classifying them by function, and comparing each with its technological analogs. Among interlocking joints he recognizes miters, rabbets, dovetails, and mortises; under releasable attachments he describes plugs and sockets, hooks and eyes, snaps, vises, forceps, anchors, suction cups, and others. The diversity defies summarization. Even velcro has its biological analog – what Nachtigall calls 'probabilistic' attachments, coatings of burrs invented repeatedly as a dispersal device for the seeds and fruits of plants. All that these latter require is gentle contact with a sufficiently irregular surface and enough burrs attach to provide a surprisingly strong connection. Velcro...represents highly successful bioemulation: its inventor Georges DeMestral, deliberately worked from the seed barbs of cocklebur and burdock."
2004 - Treviranus Medal of the Association of German Biologists
Publications
Nachtigall, W. 1965. "Die aerodynamische Funktion der Schmetterlingsschuppen". Naturwissenschapter, 52: 216–217.
Nachtigall, W. 1966. "Die Kinematik der Schlagflugelbewegungen von Dipteren: Methodische und analytische Grundlagen zur Biophysik des Insektenflugs". Z. vergl. Physiol.53, 155—211.
Nachtigall, W. & Wilson, D.M. 1967. . Journal of Experimental Biology Vol 47: 77-97. Retrieved November 5, 2011.
Nachtigall, W. 1968. Transparent wings, Moos Verlag
Nachtigall, W. 1968. "Elektrophysiologische and kinematische Untersuchungen Start and Stop des Flugrnotors von Fliegen". Z. vergl. Physiol.61, 1-20
Nachtigall, W. 1968. Insects in Flight.
Nachtigall, W. 1974. Biological Mechanisms of Attachment: the comparative morphology and bionengineering of organs for linkage New York : Springer-Verlag
Nachtigall, W. 1974. Insects in Flight. English Translation edition, London : Allen & Unwin Ltd.
Nachtigall, W. 1984. "Vogelzugforschung in deutschland". Journal of Ornithology. Vol 125:15-187
Nachtigall, W., Nagel, Rolf. 1988. In the Realm of a thousandth of a second - Fascination of the insect flight, Gerstenberg
Kesel, A.B., Philippi, U. & Nachtigall, W. 1998. "Biomechanical aspects of the insect wing: an analysis using the finite element method". Computers in Biology and Medicine, Vol 28: 423-437.
Nachtigall, W. 2000. "Insect wing bending and folding during flight without and with an additional prey load". Entomol. Gener., 25: 1–16.
Nachtigall, W. 2001. Natural mother of invention, Ravensburger Verlag,
