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The Mechanism of the vdW-to-Covalent Well Transitions. We found that a small group of trajectories ( ~10% of the sample ) make the dominant contribution to the stabilization ( ~65% of the cross section ). They describe the super-collision events:. t = 40000 a.u.
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The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 40000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 42000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 44000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 46000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 48000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 50000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 51000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 52000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 53000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 54000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 55000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 56000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 57000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 58000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 60000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 62000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 64000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 66000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 68000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 70000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 72000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 73000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 74000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 75000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 76000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 78000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 80000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 82000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 84000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 86000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 88000 a.u.
The Mechanism of the vdW-to-Covalent Well Transitions We found that a small group of trajectories (~10% of the sample) make the dominant contribution to the stabilization (~65% of the cross section). They describe the super-collision events: t = 90000 a.u.