Neutrons can readily bind by magnetic dipole force to each other, and to other magnetic dipoles.

MIT Physics @MIT_Physics MIT researchers discover “neutronic molecules” https://physics.mit.edu/?p=17971 @ScienceMIT
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Neutrons can readily bind by magnetic dipole force to each other, and to other magnetic dipoles. Then look for electron clusters and proton clusters in places like neutron stars, collisions, high energy density, black hole regions. Many are observable now with faster sensors. Pairs are very common but intricate networks occur more often than you might imagine. Heteromolecular and heteronuclear clusters.

Neutrons can readily bind by magnetic dipole force to each other, and to other magnetic dipoles. Then look for electron clusters and proton clusters in places like neutron stars, collisions, high energy density, black hole regions. Many are observable now with faster sensors. Pairs are very common but intricate networks occur more often than you might imagine. Heteromolecular and heteronuclear clusters with magnetic bonds. Isotopes are primarily magnetic dipole pairs in cluster and very stable shapes.

Neutrons can readily bind by magnetic dipole force to each other, and to other magnetic dipoles. Then look for electron clusters and proton clusters in places like neutron stars, collisions, high energy density, black hole regions. Many are observable now with faster sensors. Pairs are very common but intricate networks occur more often than you might imagine. Heteromolecular and heteronuclear clusters with magnetic bonds. Isotopes are primarily magnetic dipole pairs in cluster and very stable shapes. Clusters of stable shapes can be extended indefinitely. #AtomicFuels #ExtendedNuclearMaterials

Neutrons can readily bind by magnetic dipole force to each other, and to other magnetic dipoles. Then look for electron clusters and proton clusters in places like neutron stars, collisions, high energy density, black hole regions. All particle-antiparticle magnetic pairs with rotation and vibration. Many are observable now with faster sensors. Pairs are very common but intricate networks occur more often than you might imagine. Heteromolecular and heteronuclear clusters with magnetic bonds. Isotopes are primarily magnetic dipole pairs in cluster and very stable shapes. Clusters of stable shapes can be extended indefinitely. #AtomicFuels #ExtendedNuclearMaterials

Neutrons can readily bind by magnetic dipole force to each other, and to other magnetic dipoles. Then look for electron clusters and proton clusters in places like neutron stars, collisions, high energy density regions, collisions, black hole regions. All particle-antiparticle magnetic pairs with rotation and vibration. Many are observable now with faster sensors. Pairs are very common but intricate networks occur more often than you might imagine. Heteromolecular and heteronuclear clusters with magnetic bonds. Isotopes are primarily magnetic dipole pairs in cluster and very stable shapes. Clusters of stable shapes can be extended indefinitely. #AtomicFuels #ExtendedNuclearMaterials #StrongForce

Neutrons can readily bind by magnetic dipole force to each other, and to other magnetic dipoles. Then look for electron clusters and proton clusters in places like neutron stars, collisions, high energy density regions, collisions, black hole regions. All particle-antiparticle magnetic pairs with rotation and vibration. Many are observable now with faster sensors. Magnetic pairs and clusters are very common, but intricate networks (clusters) occur more often than you might imagine. Heteromolecular and heteronuclear clusters with magnetic bonds. Isotopes are primarily magnetic dipole pairs in cluster and very stable shapes. Clusters of stable shapes can be extended indefinitely. #AtomicFuels #ExtendedNuclearMaterials #StrongForce #MagneticBinding #MagneticBonds

Posted:  Neutrons can readily bind by magnetic dipole force to each other, and to other magnetic dipoles. Then look for electron clusters and proton clusters in places like neutron stars, collisions, high energy density regions, collisions, black hole regions, everyday materials. All particle-antiparticle magnetic pairs with rotation and vibration. Many are observable now with faster sensors. Magnetic pairs and clusters are very common, but intricate networks (clusters) occur more often than you might imagine. Heteromolecular and heteronuclear clusters with magnetic bonds. Isotopes are primarily magnetic dipole pairs in cluster and very stable shapes. Clusters of stable shapes can be extended indefinitely. #AtomicFuels #ExtendedNuclearMaterials #StrongForce #MagneticBinding #MagneticBonds