Vacuum Force and Confinement
Abstract: We show that confinement of quarks and gluons can be explained by their interaction with the vacuum Abelian gauge field $A_{\sf{vac}}$, which is implicitly introduced by the canonical commutation relations and generates the vacuum force. The background gauge field $A_{\sf{vac}}$, linear in coordinates of $\mathbb{R}3$, is inherently present in quantum mechanics: it is introduced during the canonical quantization of phase space $(T*\mathbb{R}3, \omega )$ of a nonrelativistic particle, when a potential $\theta$ of the symplectic 2-form $\omega =\mathrm{d}\theta$ on $T*\mathbb{R}3$ is mapped into a connection $A_{\sf{vac}}=-\mathrm{i}\theta$ on a complex line bundle $L_{\sf{v}}$ over $T*\mathbb{R}3$ with gauge group U(1)${\sf{v}}$ and curvature $F{\sf{vac}}=\mathrm{d} A_{\sf{vac}}=-\mathrm{i}\omega$. Generalizing this correspondence to the relativistic phase space $T*\mathbb{R}{3,1}$, we extend the Dirac equation from $\mathbb{R}{3,1}$ to $T*\mathbb{R}{3,1}$ while maintaining the condition that fermions depend only on $x\in\mathbb{R}{3,1}$. The generalized Dirac equation contains the interaction of fermions with $A_{\sf{vac}}$ and has particle-like solutions localized in space. Thus, the wave-particle duality can be explained by turning on or off the interaction with the vacuum field $A_{\sf{vac}}$. Accordingly, confinement of quarks and gluons can be explained by the fact that their interaction with $A_{\sf{vac}}$ is always on and therefore they can only exist in bound states in the form of hadrons.
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