In a chapter of the book I have written, "Anomaly! - Collider physics and the quest for new phenomena at Fermilab" (available from September this year), I made an effort to explain a rather counter-intuitive mechanism at the basis of data collection in hadron colliders: the trigger prescale. I would like to have a dry run of the text here, to know if it is really too hard to understand - I still have time to tweak it if needed. So let me know if you understand the description below!

The text below is maybe hard to read as it is taken off context; however, let me at least spend one

It has been one hundred years since the publication of Einstein's general theory of relativity in May 1916.

People are still trying to find ways to make him wrong, but mostly they just find new ways to show right, as in a recent EPJ Plus article which demonstrated that the rotational motion in the universe is also subject to the theory of relativity.

<!--[if gte mso 9]> 800x600 <![endif]-->

 New Physics Complete Neutrino Mass Specter from Oscillation Data

Today’s emergence of nano-micro hybrid structures with almost biological complexity is of fundamental interest. Our ability to adapt intelligently to the challenges has ramifications all the way from fundamentally changing research itself, over applications critical to future survival, to posing small and medium as well as truly globally existential dangers.

I am told by a TOTEM manager that this is public news and so it can be blogged about - so here I would like to explain a rather cunning plan that the TOTEM and the CMS collaborations have put together to enhance the possibilities of a discovery, and a better characterization, of the particle that everybody hopes is real, the 750 GeV resonance seen in photon pairs data by ATLAS and CMS in their 2015 data.

(Inside Science) – Physicists are on the hunt for elusive dark matter, the hypothesized but as yet unidentified stuff that makes up a large majority of the matter in the universe.

They had long favored "weakly interacting massive particles," known as WIMPs, as the most likely dark matter candidate, but after an exhaustive search, some scientists are moving on to more exotic particles.

With the Large Hadron Collider now finally up and running after the unfortunate weasel incident, physicists at CERN and around the world are eager to put their hands on the new 2016 collisions data. The #MoarCollisions hashtag keeps entertaining the tweeting researchers and their followers, and everybody is anxious to finally ascertain whether the tentative signal of a new 750 GeV particle seen in diphoton decays in last year's data will reappear and confirm an epic discovery, or what.

The twelfth edition of “Quark Confinement and the Hadron Spectrum“, a particle physics conference specialized in QCD and Heavy Ion physics, will be held in Thessaloniki this year, from

<!--[if gte mso 9]> 800x600 <![endif]-->

                                                      Common Sense and Cosmology  

While tediously compiling a list of scientific publications that chance to have my name in the authors list (I have to apply for a career advancement and apparently the committee will scrutinize the hundred-page-long lists of that kind that all candidates submit), I discovered today that I just passed the mark of 1000 published articles. This happened on February 18th 2016 with the appearance in print of a paper on dijet resonance searches by CMS. Yay! And 7 more have been added to the list since then.