12 research outputs found
Intelligence Studies, Universities and Security
This article offers a critical assessment of academic intelligence studies in higher education. It argues that universities (and academics) should value this subject far more highly than they currently do. Doing so will enhance better public understanding of an increasingly important and unique device in modern governance. It will also improve the quality of intelligence activity by raising awareness of both good and bad practice, encourage lawfulness by means of public understanding and so defending a vital public service from ill-informed attacks in today’s conflicted world. This, rather than training potential officers, should be the primary purpose of intelligence studies
Quintessential Kination and Cold Dark Matter Abundance
The generation of a kination-dominated phase by a quintessential exponential
model is investigated and the parameters of the model are restricted so that a
number of observational constraints (originating from nucleosynthesis, the
present acceleration of the universe and the dark-energy-density parameter) are
satisfied. The decoupling of a thermal cold dark matter particle during the
period of kination is analyzed, the relic density is calculated both
numerically and semi-analytically and the results are compared with each other.
It is argued that the enhancement, with respect to the standard paradigm, of
the cold dark matter abundance can be expressed as a function of the
quintessential density parameter at the onset of nucleosynthesis. We find that
values of the latter quantity close to its upper bound require the
thermal-averaged cross section times the velocity of the cold relic to be
almost three orders of magnitude larger than this needed in the standard
scenario so as compatibility with the cold dark matter constraint is achieved.Comment: Published versio
Transient Observers and Variable Constants, or Repelling the Invasion of the Boltzmann's Brains
If the universe expands exponentially without end, ``ordinary observers''
like ourselves may be vastly outnumbered by ``Boltzmann's brains,'' transient
observers who briefly flicker into existence as a result of quantum or thermal
fluctuations. One might then wonder why we are so atypical. I show that tiny
changes in physics--for instance, extremely slow variations of fundamental
constants--can drastically change this result, and argue that one should be
wary of conclusions that rely on exact knowledge of the laws of physics in the
very distant future.Comment: 4 pages, LaTeX; v2: added references; v3: more discussion of setting,
alternative approaches, now 5 pages; v4: added discussion of the effect of
quantum fluctuations on varying constants, appendix added, now 7 pages; v5:
new reference, minor correctio
Cosmology with exponential potentials
We examine in the context of general relativity the dynamics of a spatially
flat Robertson-Walker universe filled with a classical minimally coupled scalar
field \phi of exponential potential ~ e^{-\mu\phi} plus pressureless baryonic
matter. This system is reduced to a first-order ordinary differential equation,
providing direct evidence on the acceleration/deceleration properties of the
system. As a consequence, for positive potentials, passage into acceleration
not at late times is generically a feature of the system, even when the
late-times attractors are decelerating. Furthermore, the structure formation
bound, together with the constraints on the present values of \Omega_{m},
w_{\phi} provide, independently of initial conditions and other parameters,
necessary conditions on \mu. Special solutions are found to possess intervals
of acceleration. For the almost cosmological constant case w_{\phi} ~ -1, as
well as, for the generic late-times evolution, the general relation
\Omega_{\phi}(w_{\phi}) is obtained.Comment: RevTex4, 9 pages, 2 figures, References adde