The breakthrough may prove pivotal for technologies trying to capture the energy of the Sun, and saving it for a rainy day, researchers said.
The group is working with molecules known as the Dihydroazulene-Vinylheptafulvene system.
This stores energy by changing shape, but every time the group managed to design improved molecules, the molecules lost some of their ability to hold their "energy storage".
"Regardless of what we did to prevent it, the molecules would change their shape back and release the stored energy after just an hour or two," said Mogens Brondsted Nielsen from the University of Copenhagen.
"Our only problem now is how we get it to release the energy again. The molecule does not seem to want to change its shape back again," Brondsted said.
"Regardless of method, when you store energy, there is a theoretical limit to the energy density," he said.
In theory, a kilogramme of the right molecules could store a megajoule of energy if they were perfectly designed.
With that amount of energy you can heat three litres of water from room temperature to boiling, researchers said.
"What Anders has achieved is an important breakthrough. Admittedly we do not have a good method to release the energy on demand, and we should increase the energy density further still. But now we know which path to take in order to succeed," said Brondsted.
Skov too is excited: Mostly because his molecules are sustainable on more levels than just the obvious one. Not only do they harvest sustainable solar energy. They are also completely non-toxic, he said.