The following may provide possible cold fusion. Take Bose-Einstein condensate with the temperature lowered to close to absolute zero. (Absolute zero can not be reached. In order for absolute zero to be reached energy would have to have no motion. Energy always has motion.) Lowering the temperature to close to absolute zero lowers the energy of the atoms. With the low energy the particles displace space less. With less energy to displace space, the particles move together to have enough energy to shoulder the displaced space. The particles displace a certain amount of space and with the low energy the particles can not shoulder the compression and the particles move closer together to shoulder the compression. With the particles so close, placing two strong magnets around the Bose-Einstein condensate to push the particles into each other with the magnetic fields could push the atoms into fusion, creating cold fusion. The magnetic fields of the magnets could push the magnetic fields of the particles and push the particles closer together. The particles can not shoulder the compression, the particles move closer together and can be pushed together with their magnetic fields. Using two strong magnets to push the condensate closer together could create fusion. The Bose-Einstein condensate is lowered to close to absolute zero, so it is cold, and the atoms could be fused together, to create fusion.

Cold Fusion

1. Yellow: Bose-Einstein condensate

2. Black and grey: magnets

3. Blue curves: water