mirror of
https://gitlab.science.ru.nl/mthesis-edeboone/m.internship-documentation.git
synced 2024-11-26 08:43:32 +01:00
188 lines
11 KiB
TeX
188 lines
11 KiB
TeX
% vim: fdm=marker fmr=<<<,>>>
|
|
\documentclass[../thesis.tex]{subfiles}
|
|
|
|
\graphicspath{
|
|
{.}
|
|
{../../figures/}
|
|
{../../../figures/}
|
|
}
|
|
|
|
\begin{document}
|
|
\chapter{An Introduction to Cosmic Rays and Extensive Air Showers}
|
|
\label{sec:introduction}
|
|
%\section{Cosmic Particles}%<<<<<<
|
|
%<<<
|
|
% Energy and flux
|
|
The Earth is bombarded with a variety of energetic, extra-terrestrial particles.
|
|
The energies of these particles extend over many orders of magnitude (see Figure~\ref{fig:cr_flux}).
|
|
The flux of these particles decreases exponentially with increasing energy.
|
|
For very high energies, above $10^{6}\GeV$, the flux approaches one particle per~square~meter per~year, further decreasing to a single particle per~square~kilometer per~year for Ultra High Energies (UHE) at $10^{10}\GeV$.
|
|
\\
|
|
|
|
\begin{figure}%<<< fig:cr_flux
|
|
\centering
|
|
\includegraphics[width=0.9\textwidth]{astroparticle/The_CR_spectrum_2023.pdf}
|
|
\caption{
|
|
From \protect \cite{The_CR_spectrum}.
|
|
The diffuse cosmic ray spectrum (upper line) as measured by various experiments.
|
|
The intensity and fluxes can generally be described by rapidly decreasing power laws.
|
|
The grey shading indicates the order of magnitude of the particle flux, such that from the ankle onwards ($E>10^9\GeV$) the flux reaches $1$~particle per~square~kilometer per~year.
|
|
}
|
|
\label{fig:cr_flux}
|
|
\end{figure}%>>>
|
|
|
|
% CR: magnetic field
|
|
At these high energies, the incoming particles are primarily cosmic rays\footnote{These are therefore known as \glspl{UHECR}.}, atomic nuclei typically ranging from protons ($Z=1$) up to iron ($Z=26$).
|
|
Because these are charged, the various magnetic fields they pass through will deflect and randomise their trajectories.
|
|
Of course, this effect is dependent on the strength and size of the magnetic field and the speed of the particle.
|
|
It is therefore only at the very highest energies that the direction of an initial particle might be used to (conservatively) infer the direction of its origin.
|
|
\\
|
|
|
|
% CR: galaxy / extra-galactic
|
|
The same argument (but in reverse) can be used to explain the steeper slope from the ``knee'' ($10^{6}\GeV$) onwards in Figure~\ref{fig:cr_flux}.
|
|
The acceleration of cosmic rays equally requires strong and sizable magnetic fields.
|
|
Size constraints on the Milky~Way lead to a maximum energy for which a cosmic ray can still be contained in our galaxy.
|
|
It is thus at these energies that we can distinguish between galactic and extra-galactic origins.
|
|
\\
|
|
|
|
% Photons and Neutrinos
|
|
Other particles at these energies include photons and neutrinos, which are not charged.
|
|
Therefore, these particle types do not suffer from magnetic deflections and have the potential to reveal their source regions.
|
|
Unfortunately, aside from both being much less frequent, photons can be absorbed and created by multiple mechanisms, while neutrinos are notoriously hard to detect due to their weak interaction.
|
|
%\Todo{
|
|
% $\gamma + \nu$ production by CR,
|
|
% source / targets
|
|
%}
|
|
\\
|
|
|
|
%>>>
|
|
%\subsection{Air Showers}%<<<
|
|
When a cosmic ray with an energy above $10^{3}\GeV$ comes into contact with the atmosphere, secondary particles are generated, forming an \gls{EAS}.
|
|
This air shower consists of a cascade of interactions producing more particles that subsequently undergo further interactions.
|
|
Thus, the number of particles rapidly increases further down the air shower.
|
|
This happens until the mean energy per particle is sufficiently lowered from whereon these particles are absorbed in the atmosphere.
|
|
\\
|
|
|
|
Figure~\ref{fig:airshower:depth} shows the number of particles as a function of atmospheric depth where $0\;\mathrm{g/cm^2}$ corresponds with the top of the atmosphere.
|
|
The atmospheric depth at which this number of particles reaches its maximum is called $\Xmax$.
|
|
\pagebreak
|
|
|
|
In Figure~\ref{fig:airshower:depth}, $\Xmax$ is different for the airshowers generated by a photon, a proton or an iron nucleus.
|
|
Typically, heavy nuclei have their first interaction higher up in the atmosphere than protons, with photons penetrating the atmosphere even further.
|
|
Therefore, accurate measurements of $\Xmax$ allow to statistically discriminate between photons, protons and iron nuclei.
|
|
\\
|
|
|
|
\begin{figure}%<<< airshower:depth
|
|
\centering
|
|
\vspace*{-10mm}
|
|
\includegraphics[width=0.5\textwidth]{airshower/shower_development_depth_iron_proton_photon.pdf}
|
|
\caption{
|
|
From H. Schoorlemmer.
|
|
Shower development as a function of atmospheric depth for an energy of $10^{19}\eV$.
|
|
Typically, iron- and proton-induced air showers have a difference in $\langle \Xmax \rangle$ of $100\;\mathrm{g/cm^2}$~\cite{Deligny:2023yms}.
|
|
For air showers from photons this is even further down the atmosphere.
|
|
They are, however, much more rare than cosmic rays.
|
|
}
|
|
\label{fig:airshower:depth}
|
|
\vspace*{-5mm}
|
|
\end{figure}%>>>
|
|
|
|
The initial particle type also influences the particle content of an air shower.
|
|
Depending on the available interaction channels, we distinguish three components in air showers: the hadronic, electromagnetic and muonic components.
|
|
Each component shows particular development and can be related to different observables of the air shower.
|
|
\\
|
|
For example, detecting a large hadronic component means the initial particle has access to hadronic interactions (creating hadrons such as pions, kaons, etc.) which is a typical sign of a cosmic ray.
|
|
In contrast, for an initial photon, which cannot interact hadronicly, the energy will be dumped into the electromagnetic part of the air shower, mainly producing electrons, positrons and photons.
|
|
\\
|
|
|
|
Finally, any charged pions created in the air shower will decay into muons while still in the atmosphere, thus comprising the muonic component.
|
|
The lifetime, and ease of penetration of relativistic muons allow them to propagate to the Earth's surface, even if other particles have decayed or have been absorbed in the atmosphere.
|
|
These are therefore prime candidates for air shower detectors on the Earth's surface.
|
|
\\
|
|
|
|
% Radio measurements
|
|
Processes in an air showers also generate radiation that can be picked up as coherent radio signals.
|
|
%% Geo Synchro
|
|
Due to the magnetic field of the Earth, the electrons in the air shower generate radiation.
|
|
Termed geomagnetic emission in Figure~\ref{fig:airshower:polarisation}, this has a polarisation that is dependent on the magnetic field vector ($\vec{B}$) and the air shower velocity ($\vec{v}$).
|
|
\\
|
|
%% Askaryan / Charge excess
|
|
An additional mechanism emitting radiation was theorised by Askaryan\cite{Askaryan:1961pfb}.
|
|
Due to the large inertia of the positively charged ions with respect to their light, negatively charged electrons, a negative charge excess is created.
|
|
In turn, this generates radiation that is polarised radially towards the shower axis (see Figure~\ref{fig:airshower:polarisation}).
|
|
\\
|
|
|
|
%% Cherenkov ring
|
|
Due to charged particles moving relativistically through the refractive atmosphere, the produced radiation is concentrated on a cone-like structure.
|
|
On the surface, this creates a ring called the Cherenkov-ring.
|
|
On this ring, a peculiar inversion happens in the time-domain of the air shower signals.
|
|
Outside the ring, radiation from the top of the air shower arrives earlier than radiation from the end of the air shower, whereas this is reversed inside the ring.
|
|
Consequently, the radiation received at the Cherenkov-ring is maximally coherent, being concentrated in a small time-window.
|
|
It is therefore crucial for radio detection to obtain measurements in this region.
|
|
\\
|
|
|
|
\begin{figure}%<<< airshower:polarisation
|
|
\centering
|
|
\begin{subfigure}{0.48\textwidth}
|
|
\includegraphics[width=\textwidth]{airshower/airshower_radio_polarisation_geomagnetic.png}%
|
|
\caption{
|
|
Geomagnetic emission
|
|
}
|
|
\label{fig:airshower:polarisation:geomagnetic}
|
|
\end{subfigure}
|
|
\hfill
|
|
\begin{subfigure}{0.48\textwidth}
|
|
\includegraphics[width=\textwidth]{airshower/airshower_radio_polarisation_askaryan.png}%
|
|
\caption{
|
|
Askaryan or charge-excess emission
|
|
}
|
|
\label{fig:airshower:polarisation:askaryan}
|
|
\end{subfigure}
|
|
\caption{
|
|
From \protect \cite{Schoorlemmer:2012xpa, Huege:2017bqv}
|
|
The Radio Emission mechanisms and the resulting polarisations of the radio signal: \subref{fig:airshower:polarisation:geomagnetic} geomagnetic and \subref{fig:airshower:polarisation:askaryan} charge-excess.
|
|
See text for explanation.
|
|
}
|
|
\label{fig:airshower:polarisation}
|
|
\vspace{-2mm}
|
|
\end{figure}%>>>>>>
|
|
%>>>>>>
|
|
|
|
%\subsection{Experiments}%<<<
|
|
As mentioned, the flux at the very highest energy is in the order of one particle per square kilometer per century (see Figure~\ref{fig:cr_flux}).
|
|
Observatories therefore have to span huge areas to gather decent statistics at these highest energies on a practical timescale.
|
|
In recent and upcoming experiments, such as the~\gls{Auger}\cite{Deligny:2023yms} and the~\gls{GRAND}\cite{GRAND:2018iaj}, the approach is typically to instrument a large area with a (sparse) grid of detectors to detect the generated air shower.
|
|
With distances up to $1.5\;\mathrm{km}$ (\gls{Auger}), the detectors therefore have to operate in a self-sufficient manner with only wireless communication channels and timing provided by \gls{GNSS}.
|
|
\\
|
|
|
|
In the last two decades, with the advent of advanced electronics, the detection using radio antennas has received significant attention.
|
|
Analysing air showers using radio interferometry requires a time synchronisation of the detectors to an accuracy in the order of $1\ns$\cite{Schoorlemmer:2020low} (see Chapter~\ref{sec:interferometry} for further details).
|
|
Unfortunately, this timing accuracy is not continuously achieved by \glspl{GNSS}, if at all.
|
|
For example, in the~\gls{AERA}, this was found to range up to multiple tens of nanoseconds over the course of a single day\cite{PierreAuger:2015aqe}.
|
|
\\
|
|
|
|
\pagebreak[1]
|
|
|
|
% Structure summary
|
|
This thesis investigates a relatively straightforward method (and its limits) to improve the timing accuracy of air shower radio detectors
|
|
by using an additional radio signal called a beacon.
|
|
It is organised as follows.
|
|
\\
|
|
|
|
First, an introduction to radio interferometry is given in Chapter~\ref{sec:interferometry}.
|
|
This will be used later on and gives an insight into the timing accuracy requirements.
|
|
\\
|
|
Chapter~\ref{sec:waveform} reviews some typical techniques to analyse waveforms and to obtain timing information from them.
|
|
\\
|
|
|
|
In Chapter~\ref{sec:disciplining}, the concept of a beacon transmitter is introduced to synchronise an array of radio antennas.
|
|
It demonstrates the achievable timing accuracy for a sine and pulse beacon using the techniques described in the preceding chapter.
|
|
\\
|
|
|
|
|
|
A degeneracy in the synchronisation is encountered when the timing accuracy of the \gls{GNSS} is in the order of the periodicity of a continuous beacon.
|
|
Chapter~\ref{sec:single_sine_sync} establishes a method using a single sine wave beacon while using the radio interferometric approach to observe an air shower and correct for this effect.
|
|
\\
|
|
|
|
Finally, Chapter~\ref{sec:gnss_accuracy} investigates some possible limitations of the current hardware of \gls{GRAND} and its ability to record and reconstruct a beacon signal.
|
|
\end{document}
|