Abstract
The Standard Model of particle physics is governed by Poincaré symmetry, while all other symmetries, exact or approximate, are essentially dictated by theoretical consistency with the particle spectrum. On the other hand, many models of dark matter exist that rely upon the addition of new added global symmetries in order to stabilize the dark matter particle and/or achieve the correct abundance. In this work we begin a systematic exploration into truly natural models of dark matter, organized by only relativity and quantum mechanics, without the appeal to any additional global symmetries, no fine-tuning, and no small parameters. We begin by reviewing how singlet dark sectors based on spin 0 or spin frac{1}{2} should readily decay, while pure strongly coupled spin 1 models have an overabun-dance problem. This inevitably leads us to construct chiral models with spin frac{1}{2} particles charged under confining spin 1 particles. This leads to stable dark matter candidates that are analogs of baryons, with a confinement scale that can be naturally \U0001d4aa(100)TeV. This leads to the right freeze-out abundance by annihilating into massless unconfined dark fermions. The minimal model involves a dark copy of SU(3) × SU(2) with 1 generation of chiral dark quarks and leptons. The presence of massless dark leptons can potentially give rise to a somewhat large value of ∆Neff during BBN. In order to not upset BBN one may either appeal to a large number of heavy degrees of freedom beyond the Standard Model, or to assume the dark sector has a lower reheat temperature than the visible sector, which is also natural in this framework. This reasoning provides a robust set of dark matter models that are entirely natural. Some are concrete realizations of the nightmare scenario in which dark matter may be very difficult to detect, which may impact future search techniques.
Highlights
1 2 particles charged under confining spin 1 particles
Could it be that the parameters of the dark sector conspire to be fine-tuned for life to exist; namely that the gravitational interaction between the dark and visible sectors are not too large or small as to make it difficult for galaxies, stars, etc to form? We take the point of view that this might be possible, the argument is somewhat less potent compared to varying parameters in the Standard Model which obviously have a dramatic effect on life
In this work we began an exploration into models of the dark sector that are truly natural: no small parameters, no fine-tuning, and beyond that, no appeals to any approximate symmetries
Summary
In this work we will restrict our attention to models that can be described in terms of light degrees of freedom. That are described by an effective field theory that has a cutoff well above the mass of the dark matter particle(s). The rules of relativity and quantum mechanics leave only 5 possibilities for the spin of the particles s. 2, since it is thought there is no consistent effective field theory of particles of spin s > 2 with a high cutoff. 3 2 requires the introduction of supergravity, which is an interesting possibility, but we will not pursue this subject here (in any case, one would need to explain why it has a relatively low breaking scale for it to be relevant here). Our focus here will be on the only remaining possibilities for the spins of particles. We begin with a discussion of particles that are gauge singlets, before moving onto the more interesting case of charged particles
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