AWESOME FLUORESCENCE THERMOCHROMISM
In this video we're going to demonstrate fluorescence thermochromism.
Simply dissolve a small amount of copper iodide into pyridine to form a clear yellow solution of trispyridine copper iodide.
Normally this does not fluoresce but if cooled to liquid nitrogen temperatures it will fluoresce a strong yellow color.
To understand why this happens one must first understand a little about fluorescence. The ultraviolet light is absorbed by the molecule and excites electrons in it to higher energy levels. Normally the molecule bumps into other molecules and looses this energy, dropping the electrons back into their ground levels. In fluorescent materials though, the electrons release their energy first as fluorescent light before they loose their energy through collisions. In trispyridine copper iodide, the molecules vibrate and collide too much at room temperature and thus destroy any chance of fluorescence, so the substance looks non-fluorescent. But if cooled low enough, the molecules vibrate less and thus the electrons have more opportunity to emit light before a collision.
Now moving on, if a few drops of the trispyrdine copper iodide solution is put on a sheet of filter paper and allowed to dry. it looses a pyridine molecule to become bispyridine copper iodide. This substance is more stable and will fluoresce at room temperature. But cooling will not improve the fluorescence noticeably since the substance is already stable enough to resist collisional deactivation.
Warming the substance a bit liberates another pyridine molecule to yield pyridine copper iodide. This substance has a brilliant yellow fluorescence and amazingly exhibits a color change when cooled with liquid nitrogen. What's happening is that at room temperature it *partially* looses energy upon collision and emits yellow light. But when cooled, the reduction in collisions lets the electrons retain more energy and thus when they emit its a bluer, higher energy light. this chance in color with temperature is thermochromism.
Now extra heating drives off the last pyridine molecule and leaves behind copper iodide which has a dull red fluorescence when cooled and no fluorescence at room temperature.
But the most interesting fluorescence is with pyridine copper iodide.
Видео AWESOME FLUORESCENCE THERMOCHROMISM канала NurdRage
Simply dissolve a small amount of copper iodide into pyridine to form a clear yellow solution of trispyridine copper iodide.
Normally this does not fluoresce but if cooled to liquid nitrogen temperatures it will fluoresce a strong yellow color.
To understand why this happens one must first understand a little about fluorescence. The ultraviolet light is absorbed by the molecule and excites electrons in it to higher energy levels. Normally the molecule bumps into other molecules and looses this energy, dropping the electrons back into their ground levels. In fluorescent materials though, the electrons release their energy first as fluorescent light before they loose their energy through collisions. In trispyridine copper iodide, the molecules vibrate and collide too much at room temperature and thus destroy any chance of fluorescence, so the substance looks non-fluorescent. But if cooled low enough, the molecules vibrate less and thus the electrons have more opportunity to emit light before a collision.
Now moving on, if a few drops of the trispyrdine copper iodide solution is put on a sheet of filter paper and allowed to dry. it looses a pyridine molecule to become bispyridine copper iodide. This substance is more stable and will fluoresce at room temperature. But cooling will not improve the fluorescence noticeably since the substance is already stable enough to resist collisional deactivation.
Warming the substance a bit liberates another pyridine molecule to yield pyridine copper iodide. This substance has a brilliant yellow fluorescence and amazingly exhibits a color change when cooled with liquid nitrogen. What's happening is that at room temperature it *partially* looses energy upon collision and emits yellow light. But when cooled, the reduction in collisions lets the electrons retain more energy and thus when they emit its a bluer, higher energy light. this chance in color with temperature is thermochromism.
Now extra heating drives off the last pyridine molecule and leaves behind copper iodide which has a dull red fluorescence when cooled and no fluorescence at room temperature.
But the most interesting fluorescence is with pyridine copper iodide.
Видео AWESOME FLUORESCENCE THERMOCHROMISM канала NurdRage
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