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  • Chemical waves in a Belousov-Zhabotinsky (BZ) reagent. This is a well-mixed solution of citric acid, potassium bromate and a cerium sulphate catalyst. If the local relative concentrations in the reagent are altered, for example by the impact of a dust particle on the surface, the equilibrium of the reaction is disturbed. The reaction then oscillates between oxidation and reduction. The oscillation propagates through the solution as a concentration front (yellow lines), caused by the dynamic coupling between the propagation rate of the reaction and the rates of diffusion of the reagents. Such chemical waves may be modeled using chaos mathematics.
    K10BZRXN3563.tif
  • Chemical waves in a Belousov-Zhabotinsky (BZ) reagent. This is a well-mixed solution of citric acid, potassium bromate and a cerium sulphate catalyst. If the local relative concentrations in the reagent are altered, for example by the impact of a dust particle on the surface, the equilibrium of the reaction is disturbed. The reaction then oscillates between oxidation and reduction. The oscillation propagates through the solution as a concentration front (yellow lines), caused by the dynamic coupling between the propagation rate of the reaction and the rates of diffusion of the reagents. Such chemical waves may be modeled using chaos mathematics.  This image is part of a series.
    K10BZRXN3575.tif
  • Chemical waves in a Belousov-Zhabotinsky (BZ) reagent. This is a well-mixed solution of citric acid, potassium bromate and a cerium sulphate catalyst. If the local relative concentrations in the reagent are altered, for example by the impact of a dust particle on the surface, the equilibrium of the reaction is disturbed. The reaction then oscillates between oxidation and reduction. The oscillation propagates through the solution as a concentration front (yellow lines), caused by the dynamic coupling between the propagation rate of the reaction and the rates of diffusion of the reagents. Such chemical waves may be modeled using chaos mathematics.  This image is part of a series.
    K10BZRXN3572.tif
  • Chemical waves in a Belousov-Zhabotinsky (BZ) reagent. This is a well-mixed solution of citric acid, potassium bromate and a cerium sulphate catalyst. If the local relative concentrations in the reagent are altered, for example by the impact of a dust particle on the surface, the equilibrium of the reaction is disturbed. The reaction then oscillates between oxidation and reduction. The oscillation propagates through the solution as a concentration front (yellow lines), caused by the dynamic coupling between the propagation rate of the reaction and the rates of diffusion of the reagents. Such chemical waves may be modeled using chaos mathematics.  This image is part of a series.
    K10BZRXN3581.tif
  • Chemical waves in a Belousov-Zhabotinsky (BZ) reagent. This is a well-mixed solution of citric acid, potassium bromate and a cerium sulphate catalyst. If the local relative concentrations in the reagent are altered, for example by the impact of a dust particle on the surface, the equilibrium of the reaction is disturbed. The reaction then oscillates between oxidation and reduction. The oscillation propagates through the solution as a concentration front (yellow lines), caused by the dynamic coupling between the propagation rate of the reaction and the rates of diffusion of the reagents. Such chemical waves may be modeled using chaos mathematics.  This image is part of a series.
    K10BZRXN3578.tif
  • Chemical waves in a Belousov-Zhabotinsky (BZ) reagent. This is a well-mixed solution of citric acid, potassium bromate and a cerium sulphate catalyst. If the local relative concentrations in the reagent are altered, for example by the impact of a dust particle on the surface, the equilibrium of the reaction is disturbed. The reaction then oscillates between oxidation and reduction. The oscillation propagates through the solution as a concentration front (yellow lines), caused by the dynamic coupling between the propagation rate of the reaction and the rates of diffusion of the reagents. Such chemical waves may be modeled using chaos mathematics.  This image is part of a series.
    K10BZRXN3584.tif
  • Chemical waves in a Belousov-Zhabotinsky (BZ) reagent. This is a well-mixed solution of citric acid, potassium bromate and a cerium sulphate catalyst. If the local relative concentrations in the reagent are altered, for example by the impact of a dust particle on the surface, the equilibrium of the reaction is disturbed. The reaction then oscillates between oxidation and reduction. The oscillation propagates through the solution as a concentration front (yellow lines), caused by the dynamic coupling between the propagation rate of the reaction and the rates of diffusion of the reagents. Such chemical waves may be modeled using chaos mathematics.
    K10BZRXN3569.tif
  • Chemical waves in a Belousov-Zhabotinsky (BZ) reagent. This is a well-mixed solution of citric acid, potassium bromate and a cerium sulphate catalyst. If the local relative concentrations in the reagent are altered, for example by the impact of a dust particle on the surface, the equilibrium of the reaction is disturbed. The reaction then oscillates between oxidation and reduction. The oscillation propagates through the solution as a concentration front (yellow lines), caused by the dynamic coupling between the propagation rate of the reaction and the rates of diffusion of the reagents. Such chemical waves may be modeled using chaos mathematics.
    K10BZRXN3560.tif
  • Chemical waves in a Belousov-Zhabotinsky (BZ) reagent. This is a well-mixed solution of citric acid, potassium bromate and a cerium sulphate catalyst. If the local relative concentrations in the reagent are altered, for example by the impact of a dust particle on the surface, the equilibrium of the reaction is disturbed. The reaction then oscillates between oxidation and reduction. The oscillation propagates through the solution as a concentration front (yellow lines), caused by the dynamic coupling between the propagation rate of the reaction and the rates of diffusion of the reagents. Such chemical waves may be modeled using chaos mathematics.
    K10BZRXN3566.tif
  • A 3d Printed shell made with a unique program by Andy kinsman
    K12-3D-shell006.JPG
  • This is an example of mathematical origami which is a new and exciting field of mathematics.  This surface is made from a single sheet of paper with numerous folds and no cuts..
    K12-origami212.jpg
  • A 3d Printed shell made with a unique program by Andy kinsman
    K12-3D-shell017.JPG
  • A baton is tossed in a strobe light.  The strobe flashes 250 times a second.  The baton rotates around its center of mass and follows parabolic motion.
    K12-strobo-stick7850.jpg
  • A baton is tossed in a strobe light.  The strobe flashes 250 times a second.  The baton rotates around its center of mass and follows parabolic motion.
    K12-strobo-stick7845.jpg
  • A pen is tossed in a strobe light.  The strobe flashes 250 times a second.  The baton rotates around its center of mass and follows parabolic motion.
    K12-strobo-pen7889.jpg
  • An X-ray of glass tubes to show the relation of x-ray souce on objects.
    K15X-glass-tubes02.jpg
  • Falling toast photographed with a 25 hz strobe.  That is the flash is set off 25 times a second..The falling toast is said to always land buttered side down.
    K12-strobotoast7838.jpg
  • Falling toast photographed with a 25 hz strobe.  That is the flash is set off 25 times a second..The falling toast is said to always land buttered side down.
    K12-strobotoast7818.jpg
  • This is an example of mathematical origami which is a new and exciting field of mathematics.  This surface is made from a single sheet of paper with numerous folds and no cuts..
    K12-origami216.jpg
  • This is an example of mathematical origami which is a new and exciting field of mathematics.  This surface is made from a single sheet of paper with numerous folds and no cuts..
    K12-origami215.jpg
  • An X-ray of glass tubes to show the relation of x-ray souce on objects.
    K15X-glass-tubes01.jpg
  • A 3d Printed shell made with a unique program by Andy kinsman
    K12-3D-shell005.JPG
  • A 3d Printed shell made with a unique program by Andy kinsman
    K12-3D-shell004.JPG
  • A 3d Printed shell made with a unique program by Andy kinsman
    K12-3D-shell002.JPG
  • Falling toast photographed with a 25 hz strobe.  That is the flash is set off 25 times a second..The falling toast is said to always land buttered side down.
    K12-strobotoast7840.jpg
  • A baton is tossed in a strobe light.  The strobe flashes 250 times a second.  The baton rotates around its center of mass and follows parabolic motion.
    K12-strobo-stick7844 copy.jpg
  • A baton is tossed in a strobe light.  The strobe flashes 250 times a second.  The baton rotates around its center of mass and follows parabolic motion.
    K12-strobo-stick7843.jpg
  • This is an x-ray of a mathematical origami.  Mathematical origami is a new and exciting field of mathematics.  This surface is made from a single sheet of paper with numerous folds and no cuts..
    K11X-oragami-002-12inchB.jpg
  • This is an x-ray of a mathematical origami.  Mathematical origami is a new and exciting field of mathematics.  This surface is made from a single sheet of paper with numerous folds and no cuts..
    K11X-oragami-002-12inch.jpg
  • An X-ray of glass tubes to show the relation of x-ray souce on objects.
    K15X-glass-tubes03.jpg
  • A 3d Printed shell made with a unique program by Andy kinsman
    K12-3D-shell022.JPG
  • A 3d Printed shell made with a unique program by Andy kinsman
    K12-3D-shell014.JPG
  • A 3d Printed shell made with a unique program by Andy kinsman
    K12-3D-shell003.JPG
  • A 3d Printed shell made with a unique program by Andy kinsman
    K12-3D-shell001.JPG
  • Falling toast photographed with a 25 hz strobe.  That is the flash is set off 25 times a second..The falling toast is said to always land buttered side down.
    K12-strobotoast7837 copy.jpg
  • This is an example of mathematical origami which is a new and exciting field of mathematics.  This surface is made from a single sheet of paper with numerous folds and no cuts..
    K12-peperorigami7919.jpg
  • This is an example of mathematical origami which is a new and exciting field of mathematics.  This surface is made from a single sheet of paper with numerous folds and no cuts..
    K12-origami213.jpg
  • This is an example of mathematical origami which is a new and exciting field of mathematics.  This surface is made from a single sheet of paper with numerous folds and no cuts..
    K12-origami209.jpg
  • This is an example of mathematical origami which is a new and exciting field of mathematics.  This surface is made from a single sheet of paper with numerous folds and no cuts..
    K12-origami203.jpg
  • This is an example of mathematical origami which is a new and exciting field of mathematics.  This surface is made from a single sheet of paper with numerous folds and no cuts..
    K12-origami201.jpg
  • An X-ray of a Chambered Nautilus (Nautilus pompilius).
    nautilus1FC.jpg
  • A hand held calculator is x-rayed to show the placement of keyboard, electronics, and circuits.  This calculator does not have any batteries in it, but the internal battery is clearly visible as a circular spot about the size of a quarter near the bottom.
    calculator.jpg
  • A 3d Printed shell made with a unique program by Andy kinsman
    K12-3D-shell021.JPG
  • A 3d Printed shell made with a unique program by Andy kinsman
    K12-3D-shell010.JPG
  • Falling toast photographed with a 25 hz strobe.  That is the flash is set off 25 times a second..The falling toast is said to always land buttered side down.
    K12-strobotoast7817.jpg
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Ted Kinsman

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