Magnetic exchange coupled MTJ free layer with double tunnel barriers having low switching current and high data retention

What is claimed is: 1. A method of forming a magnetic tunnel junction (MTJ) storage element, the method comprising: forming a first reference layer having a first fixed magnetization direction; forming a first tunnel barrier layer; forming a composite free layer on an opposite side of the first tunnel barrier layer from the first reference layer; forming a second tunnel barrier on an opposite side of the free layer from the first tunnel barrier; and forming a second reference layer having a second fixed magnetization direction, where the second reference layer is on an opposite side of the second tunnel barrier from the free layer; where forming the composite free layer comprises: forming a first region comprising a first material configured to include a first predetermined magnetic moment and a first switchable magnetization direction; forming a second region comprising a second material configured to include a second predetermined magnetic moment and a second switchable magnetization direction; forming a first spacer material between the first region and the second region; and configuring the first spacer material to provide magnetic exchange coupling between the first region and the second region; where the first predetermined magnetic moment is configured to be lower than the second predetermined magnetic moment; where the first region, the second region and the first spacer material are configured such that a direction of the first switchable magnetization direction changing also initiates the change in the direction of the second switchable magnetization direction. 2. A method of forming a magnetic tunnel junction (MTJ) storage element, the method comprising: forming a first reference layer having a first fixed magnetization direction; forming a first tunnel barrier layer; forming a composite free layer on an opposite side of the first tunnel barrier layer from the first reference layer; forming a second tunnel barrier on an opposite side of the free layer from the first tunnel barrier; and forming a second reference layer having a second fixed magnetization direction, where the second reference layer is on an opposite side of the second tunnel barrier from the free layer; where forming the composite free layer comprises: forming a first region comprising a first material configured to include a first predetermined magnetic moment and a first switchable magnetization direction; forming a second region comprising a second material configured to include a second predetermined magnetic moment and a second switchable magnetization direction; forming a third region comprising a third material configured to include a third predetermined magnetic moment and a third switchable magnetization direction; forming a first spacer material between the first region and the second region, where the first spacer material is configured to provide magnetic exchange coupling between the first region and the second region; and forming a second spacer material between the second region and the third region, where the second spacer material is configured to provide magnetic exchange coupling between the second region and the third region; where the first predetermined magnetic moment is configured to be lower than the second predetermined magnetic moment; where the third predetermined magnetic moment is configured to be lower than the second predetermined magnetic moment; where the first region, the second region, and the first spacer material are configured such that a direction of the first switchable magnetization direction changing causes a direction of the second switchable magnetization direction to change; where the third region, the second region, and the second spacer material are configured such that a direction of the third switchable magnetization direction changing causes the direction of the second switchable magnetization direction to change. 3. A method of operating a magnetic tunnel junction (MTJ) storage element, the method comprising: applying a write pulse having a predetermined magnitude to the MTJ storage element; where the MTJ storage element comprises: a first reference layer having a first fixed magnetization direction; a first tunnel barrier layer; a free layer on an opposite side of the first tunnel barrier layer from the first reference layer; a second tunnel barrier on an opposite side of the free layer from the first tunnel barrier; and a second reference layer having a second fixed magnetization direction, where the second reference layer is on an opposite side of the second tunnel barrier from the free layer; where the free layer comprises: a first region comprising a first material configured to include a first predetermined magnetic moment and a first switchable magnetization direction; a second region comprising a second material configured to include a second predetermined magnetic moment and a second switchable magnetization direction; and a third region comprising a third material configured to include a third predetermined magnetic moment and a third switchable magnetization direction; a first spacer material between the first region and the second region, where the first spacer material is configured to provide magnetic exchange coupling between the first region and the second region; a second spacer material between the third region and the second region, where the second spacer material is configured to provide magnetic exchange coupling between the second region and the third region; where the first predetermined magnetic moment is configured to be lower than the second predetermined magnetic moment; where the third predetermined magnetic moment is configured to be lower than the second predetermined magnetic moment; and where the first region, the second region and the first spacer material are configured such that a direction of the first switchable magnetization direction changing also initiates the change in the direction of the second switchable magnetization direction to change; and where the third region, the second region, and the second spacer material are configured such that a direction of the third switchable magnetization direction changing causes the direction of the second switchable magnetization direction to change. 4. The method of claim 3 further comprising: based at least in part on receiving the write pulse, generating spin torque electrons in the first reference layer material, where the spin torque electrons generated in the first reference layer material are insufficient to initiate a process of switching the second switchable magnetization direction of the second region; and based at least in part on spin torque electrons being generated in the first reference layer material, initiating a process of switching the first switchable magnetization direction of the first region; where the first switchable magnetization direction of the first region switching assists the process of switching the second switchable magnetization direction of the second region based at least in part on the magnetic exchange coupling between the first region and the second region provided by the first spacer material; and based at least in part on receiving the write pulse, generating spin torque electrons in the second reference layer material, where the spin torque electrons generated in the second reference layer material are insufficient to initiate a process of switching the second switchable magnetization direction of the second region; and based at least in part on spin torque electrons being generated in the second reference layer material, initiating a process of switching the third switchable magnetization direction of the third region; where the third switchable magnetization direction of the third region switching assists the process