Thursday, May 26, 2011

Steady Progress at Focus Fusion





What has to be appreciated is that this device design is the first practical configuration that can be incrementally improved without running into obvious roadblocks.  What I mean is that it should work inside the envelope of our knowledge and that it compares rather nicely to the early efforts that made the internal combustion engine emerge.  I anticipate break even sooner or later.  I also see specific technical improvements been indicated and clearly achievable.

I think we are looking at the emergence of the power plant able to operate a starship and the very important MFEVs (magnetic field exclusion vessel)

Thus we will motor through the breakeven point with this design and a long way past.  It seems to be a case of achieving robustness and precision.  At some point it will all be done in carbon which will serve to bring the size and mass down.

Eight fold symmetry is shown to be better that ten fold symmetry.  That at least throws the five factor out and supports the next stage of sixteen fold symmetry.  I suspect that this is important in terms of going forward.

It is great to be able to follow this technology so closely as it emerges.  Read previous posts on the topic by googling focus fusion on this blog.

Focus fusion project getting greater repeatability and higher current beams

MAY 23, 2011


1. Lawrenceville Plasma Physics is getting major improvement in repeatability of fusion yield and beam production. Repeatable fusion yield is now within a factor of 4 of predictions. Clues found from data and simulation on improving filamentation, ending the early-beam problem and boosting yield up to predictions.


Any small deviation from symmetry greatly reduced yield and repeatability. When we changed the number of capacitors firing from 10 to 8, variability dropped dramatically, with the range of fusion yields dropping first to 3 to 1 and then to ±15% (around a yield of 5x10^10 neutrons). While 10 capacitors are not symmetrically arranged and 8 are, the current spreads out to make asymmetries quite small, so this effect told us that we could still improve the symmetry of the initial conditions of firing. 



The observations are right in line with their prediction of energies of 0.9 MeV and current of 280 kA, proving again they are getting good transference of energy into the plasma and into the beam, but not quite enough compression to get high density. The greater reliability of the beams means LPP’s DPF technology can generate more reliable bursts of high intensity X-rays. 

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