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Revision as of 14:00, 22 June 2009 editජපස (talk | contribs)Extended confirmed users, Pending changes reviewers, Rollbackers60,450 edits explain exactly what's going on... see talk.← Previous edit Revision as of 14:32, 22 June 2009 edit undoජපස (talk | contribs)Extended confirmed users, Pending changes reviewers, Rollbackers60,450 edits Mechanism: fix linkNext edit →
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==Mechanism== ==Mechanism==


Normally, the ] prevents ], which are always positively charged, from approaching close enough to fuse. However, neutrons are not affected by the ] repulsive force that creates the barrier, because they have no charge. In all fusion processes, the ] sets the requisite energy which interacting ] need to fuse. Since nuclei are always positively charged the ] is always repulsive. One way to avoid this problem is to use ] since they have no charge, the Coulomb barrier for such interactions is nil. Since isolated neutrons are unstable, the neutrons themselves must be created through other nuclear reactions. The O-P process allows for similar sorts of nuclear reactions to take place with naturally occurring stable deuterium.


Deuterium is the simplest nucleus other than a bare proton, having a single neutron in addition. The deuteron's positive charge is spatially polarized, as if at one end of a ], the proton end. As the deuteron approaches the target nucleus, it is deaccelerated by the ], converting kinetic energy to potential energy, as with the compression of a spring. Depending on its energy, and assuming that the energy is not sufficient for it to surmount the barrier, it will approach to a minimum distance. As it it slows, the neutron is slowed with it. ] resists their separation. If the orientation of the deuteron at the maximum approach is such that the neutron is oriented toward the target nucleus, it may be close enough to fuse. At these low energies, fusion proceeds if the ] between the neutron and the target nucleus generates greater force than that holding the proton and neutron together. The neutron is "stripped" from the proton. During the O-P process, the deuteron's positive charge is spatially polarized, as if at one end of a ], the proton end. As the deuteron approaches the target nucleus, it is repelled by the ], converting ] to ] until, assuming the energy is not sufficient for it to surmount the barrier, the deuteron approaches to a minimum distance. Fusion proceeds when the unstable deuterated nucleus decays into daughter nuclei, normally a proton being one of the products.


As the neutron is drawn to the target nucleus, the binding force exerted by it pulls the proton closer than it would otherwise have approached on its own. If the neutron is captured, the proton is stripped from it and is ejected by the ], and since it has half the mass of the deuteron, the same repulsive force that originally deaccelerated it can bounce it back with more than doubled velocity, for it carries away not only all of the potential energy stored up in repulsion as it approached, plus half the remaining kinetic energy (zero with a centered collision), but also part of the binding energy of the deuteron. It may in this way carry away more than the incident energy, leaving the transmuted nucleus in an ], or even in the ], as if it had fused with a neutron of negative kinetic energy.<ref name=friend68>Friendlander, 2008, p. </ref><ref>Blatt, 1991, pp. 508-509</ref><ref>Blatt, 1991, pp. 508-509</ref> As the neutron is drawn to the target nucleus, the binding force exerted by it pulls the proton closer than it would otherwise have approached on its own. If the neutron is captured, the proton is stripped from it and is ejected by the ], and since it has half the mass of the deuteron, it can recoil with more than double the incident velocity, and may carry away more than the incident kinetic energy of the deuteron, leaving the transmuted nucleus in a state as if it had fused with a neutron of negative kinetic energy.<ref name=friend68>Friendlander, 2008, p. </ref><ref>Blatt, 1991, pp. 508-509</ref><ref>Blatt, 1991, pp. 508-509</ref>


==References== ==References==

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The Oppenheimer–Phillips process or strip reaction is a type of deuteron-induced nuclear reaction.

In this process the neutron half of an energetic deuteron fuses with a target nucleus, transmuting it to a heavier isotope, while the proton half is ejected. An example would be the nuclear transmutation of carbon-12 to carbon-13.

The process is considered important because the cross section for the interaction is enhanced over that expected from the Bohr model due to a polarization of the deuteron where the proton-end faces away from the incident nucleus and the neutron-end faces towards the incident nucleus during most energetically favorable arrangement for the reaction.

History

Explanation of this effect was published by J. Robert Oppenheimer and Melba Phillips in 1935, considering experiments with the Berkeley cyclotron showing that some elements became radioactive under deuteron bombardment.

Mechanism

In all fusion processes, the Coulomb barrier sets the requisite energy which interacting atomic nuclei need to fuse. Since nuclei are always positively charged the electrostatic force is always repulsive. One way to avoid this problem is to use neutrons since they have no charge, the Coulomb barrier for such interactions is nil. Since isolated neutrons are unstable, the neutrons themselves must be created through other nuclear reactions. The O-P process allows for similar sorts of nuclear reactions to take place with naturally occurring stable deuterium.

During the O-P process, the deuteron's positive charge is spatially polarized, as if at one end of a barbell, the proton end. As the deuteron approaches the target nucleus, it is repelled by the electrostatic field, converting kinetic energy to potential energy until, assuming the energy is not sufficient for it to surmount the barrier, the deuteron approaches to a minimum distance. Fusion proceeds when the unstable deuterated nucleus decays into daughter nuclei, normally a proton being one of the products.

As the neutron is drawn to the target nucleus, the binding force exerted by it pulls the proton closer than it would otherwise have approached on its own. If the neutron is captured, the proton is stripped from it and is ejected by the electrostatic field, and since it has half the mass of the deuteron, it can recoil with more than double the incident velocity, and may carry away more than the incident kinetic energy of the deuteron, leaving the transmuted nucleus in a state as if it had fused with a neutron of negative kinetic energy.

References

  1. ^ Friendlander, 2008, p. 68-69
  2. Oppenheimer, 1995, page 192 cf. Note on the transmutation function for deuterons, J. Robert Oppenheimer and Melba Phillips, Phys. Rev. 48, September 15, 1935, 500-502, received July 1, 1935.
  3. Blatt, 1991, pp. 508-509
  4. Blatt, 1991, pp. 508-509


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