It depends upon your calculation of the strength of quantum gravity and the number of additional dimensions of spacetime it acts upon. The blue-shifted collective radiation surrounding the surface of the collapsed matter will be more than enough to take down a nearby coulomb barrier. A 22 microgram black hole is predicted to have a local temperature as high as 5.6×1032 K . It only takes 40 million degrees to trigger fusion, not a problem for one of these guys.
You definitely would not want to lock horns with one of these buggers if they do not evaporate completely. On Fri, Aug 24, 2012 at 9:36 PM, <mix...@bigpond.com> wrote: > In reply to ChemE Stewart's message of Thu, 23 Aug 2012 09:22:57 -0400: > Hi, > [snip] > >Gremlins come in different colors: > > > >Brown dwarf ~ Brown Gremlin > >White dwarf ~ White Gremiln > >Black hole ~. Black Gremlin > >Micro black hole ~ Invisible Gremlin > > > >The smaller they are the more elusive and more trouble they cause in their > >surroundings. > > > For the gravitational field of an Invisible Gremlin with a single positive > charge to be strong enough to attract another proton against the repulsive > Coulomb force, it would need to have a mass in excess of 2 billion kg. > Such a > gremlin would have a Schwarzschild radius >= 3E-3 fm (hundreds of times > smaller > than a proton), exerting a pressure of > > 2 billion kgf / Pi*SR^2 = 1E41 psi on the containment. > > Perhaps needless to say, it's going to be impossible to hang on to one. > > Regards, > > Robin van Spaandonk > > http://rvanspaa.freehostia.com/project.html > >
