# Tag Info

## New answers tagged higgs

1

Setting $$\theta := \theta_1 + \theta_2$$, the momentum of the Higgs boson (candidate) with respect to the lab  \| \textbf p_{lab}[~H~] \| = \| \textbf p_{lab}[~\gamma_1~] \| ~\text{Cos}[~\theta_1~] + \| \textbf p_{lab}[~\gamma_2~] \| ~\text{Cos}[~\theta_2~] = (E_{lab}[~\gamma_1~] ~ \text{Cos}[~\theta_1~] + E_{lab}[~\gamma_2~] ~ ...

1

1. Void vs Vacuum The first thing that needs to be done is to distinguish between void and space (ie vacuum). Space is not nothing, because you can move things in it; think of it as the medium in which particles can move. For if space was exactly nothing; then where could you put a particle? There is no place you can put it. 2. Crumpling space The ...

0

Physically what does warping (of space-time) mean? Inhomogeneous space. See the Einstein digital papers where Einstein describes a gravitational field as a place where space is "neither homogeneous nor isotropic". And note that curved spacetime isn't curved time and curved space. See this Baez article for a bit about that: "Similarly, in general ...

1

Describing ´space´ as ´empty´ does very little when you are juxtaposing that with a field.. Spacetime is not ´nothing,´ (though its emptiness can be used to describe it as empty at a localized point given[quantum fluctuations notwithstanding]no actual matter is within whatever frame of reference you are using)it is a field like the Higgs field you ...

4

I expect you are familiar with the Big Bang model, seen here . It is a mathematical model using mathematical solutions from General Relativity and the Standard Model of particle physics . The BB developed to describe astronomical observations and the SM developed to describe particle physics observations. The SM describes how particles/nature behaves as ...

3

The best solutions of the challenge are available in these papers: http://jmlr.org/proceedings/papers/v42/

Top 50 recent answers are included