courses:ast403:epoch-of-reionization
Differences
This shows you the differences between two versions of the page.
| Both sides previous revisionPrevious revisionNext revision | Previous revision | ||
| courses:ast403:epoch-of-reionization [2026/03/29 06:57] – [Context: From Recombination to the Dark Ages] shuvo | courses:ast403:epoch-of-reionization [2026/03/29 09:54] (current) – shuvo | ||
|---|---|---|---|
| Line 5: | Line 5: | ||
| ===== Context: From Recombination to the Dark Ages ===== | ===== Context: From Recombination to the Dark Ages ===== | ||
| - | After the Big Bang, the Universe was a hot plasma of free electrons and nuclei. Approximately 380,000 years after the Big Bang ($z \sim 1100$), the temperature dropped to roughly 3000 K, allowing electrons to combine with protons to form neutral hydrogen atoms. This event, known as **recombination**, made the Universe transparent to photons, which we observe today as the cosmic microwave background (CMB). Following recombination, | + | After the Big Bang, the Universe was a hot plasma of free electrons and nuclei. Approximately 380,000 years after the Big Bang ($z \sim 1100$), the temperature dropped to roughly 3000 K, allowing electrons to combine with protons to form neutral hydrogen atoms. This event, known as recombination, |
| Line 41: | Line 41: | ||
| The physics of reionization is fundamentally a race between two processes: **ionization** (radiation tearing atoms apart) and **recombination** (electrons and protons finding each other to become neutral again). | The physics of reionization is fundamentally a race between two processes: **ionization** (radiation tearing atoms apart) and **recombination** (electrons and protons finding each other to become neutral again). | ||
| - | We quantify the progress of reionization using the **volume filling factor of ionized hydrogen**, denoted as $Q_{HII}$. This represents the fraction of the universe's volume that has been ionized. | + | We quantify the progress of reionization using the **volume filling factor of ionized hydrogen**, denoted as $Q_{HII}$. This represents the fraction of the Universe's volume that has been ionized. |
| The evolution of reionization is governed by a differential equation balancing the production of ionizing photons against the rate at which atoms recombine: | The evolution of reionization is governed by a differential equation balancing the production of ionizing photons against the rate at which atoms recombine: | ||
| Line 53: | Line 53: | ||
| **The Recombination Time and Clumping:** | **The Recombination Time and Clumping:** | ||
| - | Recombination happens faster in dense regions. Because the universe | + | Recombination happens faster in dense regions. Because the Universe |
| $$\bar{t}_{rec} = \frac{1}{C \alpha_B \langle n_e \rangle (1+z)^3}$$ | $$\bar{t}_{rec} = \frac{1}{C \alpha_B \langle n_e \rangle (1+z)^3}$$ | ||
| - | Where $\alpha_B$ is the "Case B" recombination coefficient (which accounts for electrons cascading down energy levels) and $z$ is the redshift. If the gas is highly clumped ($C > 1$), recombination happens much faster, meaning galaxies have to work much harder to keep the universe | + | Where $\alpha_B$ is the "Case B" recombination coefficient (which accounts for electrons cascading down energy levels) and $z$ is the redshift. If the gas is highly clumped ($C > 1$), recombination happens much faster, meaning galaxies have to work much harder to keep the Universe |
| **The Photon Budget:** | **The Photon Budget:** | ||
| Line 69: | Line 69: | ||
| * $f_{esc}$ is the **escape fraction**: the critical percentage of ionizing photons that actually escape the dense gas of their host galaxy and make it into the IGM. | * $f_{esc}$ is the **escape fraction**: the critical percentage of ionizing photons that actually escape the dense gas of their host galaxy and make it into the IGM. | ||
| + | |||
| + | [{{ : | ||
| ===== Observational Evidence ===== | ===== Observational Evidence ===== | ||
| Line 81: | Line 83: | ||
| The disappearance of this trough at $z \lesssim 5.8$ indicates the Universe was fully reionized by that time. | The disappearance of this trough at $z \lesssim 5.8$ indicates the Universe was fully reionized by that time. | ||
| - | 2. **CMB Polarization: | + | 2. **CMB Polarization: |
| We measure the integrated optical depth ($\tau_e$) to the CMB: | We measure the integrated optical depth ($\tau_e$) to the CMB: | ||
| Line 97: | Line 99: | ||
| + | ===== Mapping EoR with 21-cm Hydrogen Line ===== | ||
| + | |||
| + | To map the Epoch of Reionization (EoR), astronomers have to completely flip their perspective. Instead of using optical or infrared telescopes to look for the brilliant light of the first galaxies, they use radio telescopes to look for the vast, cold oceans of neutral hydrogen gas that surround them. | ||
| + | |||
| + | Rather than looking at the light, they are looking at the shadows. The key to this is the 21-cm hydrogen line. | ||
| + | |||
| + | Here is a detailed look at how this signal is generated, how it maps the ionized bubbles, and how massive radio arrays are attempting to detect it. | ||
| + | |||
| + | **The Physics: The Spin-Flip Transition | ||
| + | ** | ||
| + | The hydrogen atom consists of a single proton and a single electron. According to quantum mechanics, both of these particles have a property called " | ||
| + | |||
| + | Because the early Universe is filled with unimaginably massive clouds of neutral hydrogen, these rare, individual spin-flips add up to a faint but ubiquitous background glow across the cosmos. | ||
| + | |||
| + | |||
| + | [{{ : | ||
| + | |||
| + | **Redshift and the Radio Window: | ||
| + | ** | ||
| + | Just like the Lyman break, the 21-cm signal is redshifted as the Universe expands. To figure out where we should tune our radio dials to hear the EoR (which occurred between redshifts $z = 6$ and $z = 10$), we use the frequency redshift equation: | ||
| + | |||
| + | $$\nu_{\text{obs}} = \frac{1420 \text{ MHz}}{1+z}$$ | ||
| + | |||
| + | If we want to map neutral hydrogen at $z = 8$ (deep in the EoR), the frequency we observe on Earth is shifted down to roughly 157 MHz. | ||
| + | |||
| + | This presents an interesting quirk for observational astronomy: this frequency falls squarely within the VHF band used for FM radio and television broadcasts on Earth. To map the early Universe, astronomers must build telescopes far away from human interference, | ||
| + | |||
| + | **The Mathematics of the Signal: Brightness Temperature | ||
| + | **\\ | ||
| + | |||
| + | Radio astronomers do not just measure the raw brightness of the 21-cm line; they measure its contrast against the omnipresent backlight of the Cosmic Microwave Background (CMB). This contrast is expressed as the **differential brightness temperature** ($\delta T_b$). | ||
| + | |||
| + | The full equation for the 21-cm brightness temperature during the EoR is complex, but its core dependencies are elegantly described as: | ||
| + | |||
| + | $$\delta T_b \approx 27 x_{HI} (1 + \delta_b) \left( \frac{\Omega_b h^2}{0.023} \right) \sqrt{\frac{0.15}{\Omega_m h^2} \frac{1+z}{10}} \left( 1 - \frac{T_{\gamma}}{T_S} \right) \text{ mK}$$ | ||
| + | |||
| + | Let's break down the two most critical variables for mapping the bubbles:\\ | ||
| + | |||
| + | * $x_{HI}$: This is the neutral fraction of the hydrogen gas. If the gas is completely ionized by a nearby galaxy, $x_{HI} = 0$, and the entire equation collapses to zero.\\ | ||
| + | |||
| + | * $T_S$ vs $T_{\gamma}$: | ||
| + | |||
| + | **The Tomographic Map:** Because $\delta T_b$ drops to zero wherever $x_{HI}$ drops to zero, ionized bubbles surrounding early galaxies appear as **" | ||
| + | |||
| + | |||
| + | [{{ : | ||
| + | |||
| + | **The Telescope Arrays: HERA and the SKA:** | ||
| + | |||
| + | A single radio dish cannot resolve these ancient bubbles. To get the necessary resolution, astronomers use interferometry—networking dozens or hundreds of antennas together so they act like a single, massive telescope. | ||
| + | |||
| + | //HERA (Hydrogen Epoch of Reionization Array):// Located in South Africa, HERA consists of hundreds of large, densely packed parabolic dishes pointing straight up. HERA is designed to measure the power spectrum of the 21-cm signal. Rather than taking a high-definition picture of individual bubbles, it measures the statistical variance — telling us the average size of the bubbles and how fast they are growing at specific times. | ||
| + | |||
| + | //SKA (Square Kilometre Array):// Currently under construction across Australia and South Africa, the SKA will be the largest radio telescope ever built. SKA-Low (in Australia) will consist of over 130,000 wire antennas. It will have the raw sensitivity and resolution to go beyond statistics and actually capture true tomographic imaging — giving us direct, 3D video-like maps of the ionized bubbles expanding and merging. | ||
| + | |||
| + | **The Ultimate Challenge: The Foreground Problem: | ||
| + | ** | ||
| + | The reason we don't have perfect maps of the EoR yet is due to a monumental data analysis challenge known as the foreground problem. | ||
| + | |||
| + | The 21-cm signal from the EoR is incredibly weak, typically measuring around **$10$ to $30 \text{ mK}$** (millikelvins). However, our own Milky Way galaxy emits massive amounts of synchrotron radiation (electrons spiraling in magnetic fields) at these exact same low frequencies. The Milky Way foreground is upwards of $10^4$K (tens of thousands of degrees). | ||
| + | |||
| + | This means the foreground noise is about **100,000 times louder** than the signal astronomers are trying to find. Finding the 21-cm EoR signal is often compared to trying to hear a mosquito buzzing while standing next to a roaring jet engine. It requires incredibly precise calibration and complex algorithms to mathematically peel away the smooth foreground of the Milky Way to reveal the crinkly, bubbly 21-cm signal hiding underneath. | ||
courses/ast403/epoch-of-reionization.1774789029.txt.gz · Last modified: by shuvo