HOW TO GET LIGHT FROM THE DARK AGES

Similar documents
Probing the Dark Ages with 21 cm Absorption

Probing Into The Dark Ages with a Low Frequency Interferometer on the Moon

An Introduction to Radio Astronomy

An Introduction to Radio Astronomy

The First Stars John Wise, Georgia Tech

Lunar University Network for Astrophysics Research LUNAR. Jack Burns, Director Eric Hallman, Deputy Director Doug Duncan, E/PO Lead Scientist

Foregrounds for observations of the high redshift global 21 cm signal

Astronomy 210 Final. Astronomy: The Big Picture. Outline

Astrophysics Enabled by the Return to the Moon

Thoughts on LWA/FASR Synergy

University of Groningen. Opening the low frequency window to the high redshift Universe Vedantham, Harish

Astronomical Experiments for the Chang E-2 Project

Center for Astrophysics & Space Astronomy University of Colorado at Boulder

V. Astronomy Section

Square Kilometre Array: World s Largest Radio Telescope Design and Science drivers

Detecting High Energy Cosmic Rays with LOFAR

Astronomy Today. Eighth edition. Eric Chaisson Steve McMillan

Galaxies with Active Nuclei. Active Galactic Nuclei Seyfert Galaxies Radio Galaxies Quasars Supermassive Black Holes

=> most distant, high redshift Universe!? Consortium of international partners

Thoughts on Astrophysics with nano/6u cubesats

Space mission BRАUDE-M. Radio telescope on the farside of the Moon

MURCHISON WIDEFIELD ARRAY

Mapping the Galaxy using hydrogen

Low-frequency radio astronomy and wide-field imaging

Pulsars. Table of Contents. Introduction

Properties of Thermal Radiation

Analysis of differential observations of the cosmological radio background: studying the SZE-21cm

Dr. John Kelley Radboud Universiteit, Nijmegen

Active Galaxies and Galactic Structure Lecture 22 April 18th

Possible Extra Credit Option

Review: Properties of a wave

What are the Big Questions and how can Radio Telescopes help answer them? Roger Blandford KIPAC Stanford

Chapter 10 The Interstellar Medium

Age-redshift relation. The time since the big bang depends on the cosmological parameters.

New Astronomy Reviews

The Dynamic Radio Sky

New physics is learnt from extreme or fundamental things

The Cosmic Microwave Background

Energy Source for Active Galactic Nuclei

A100H Exploring the Universe: Quasars, Dark Matter, Dark Energy. Martin D. Weinberg UMass Astronomy

Perspektiven der. Radioastronomie. im Weltraum. J. Anton Zensus Silke Britzen. Max-Planck-Institut für. Radioastronomie

ASTRONOMY METHODS. A Physical Approach to Astronomical Observations CAMBRIDGE UNIVERSITY PRESS. HALE BRADT Massachusetts Institute of Technology

Exam 3 Astronomy 100, Section 3. Some Equations You Might Need

Gamma-ray Bursts. Chapter 4

Astr 2320 Thurs. May 7, 2015 Today s Topics Chapter 24: New Cosmology Problems with the Standard Model Cosmic Nucleosynthesis Particle Physics Cosmic

International Olympiad on Astronomy and Astrophysics (IOAA)

PART 3 Galaxies. Gas, Stars and stellar motion in the Milky Way

Guiding Questions. Active Galaxies. Quasars look like stars but have huge redshifts

Cover Page. The handle holds various files of this Leiden University dissertation.

Astronomy 102: Stars and Galaxies Review Exam 3

Introduction The Role of Astronomy p. 3 Astronomical Objects of Research p. 4 The Scale of the Universe p. 7 Spherical Astronomy Spherical

Advanced Topic in Astrophysics Lecture 1 Radio Astronomy - Antennas & Imaging

The Cosmic Microwave Background

Cosmic Microwave Background

Astronomy Hour Exam 2 March 10, 2011 QUESTION 1: The half-life of Ra 226 (radium) is 1600 years. If you started with a sample of 100 Ra 226

GCSE Astronomy Course Guide. Each Tuesday after school

X Rays must be viewed from space used for detecting exotic objects such as neutron stars and black holes also observing the Sun.

Astronomy 102: Stars and Galaxies Final Exam Review Problems Revision 2

3/1/18 LETTER. Instructors: Jim Cordes & Shami Chatterjee. Reading: as indicated in Syllabus on web

Astronomy 114. Lecture35:TheBigBang. Martin D. Weinberg. UMass/Astronomy Department

Introduction. How did the universe evolve to what it is today?

Cosmology. Jörn Wilms Department of Physics University of Warwick.

Chapter 21 Galaxy Evolution. Agenda

Multi-wavelength Astronomy

Design Reference Mission for SKA1 P. Dewdney System Delta CoDR

Directed Reading A. Section: The Life Cycle of Stars TYPES OF STARS THE LIFE CYCLE OF SUNLIKE STARS A TOOL FOR STUDYING STARS.

Really, really, what universe do we live in?

Lecture #24: Plan. Cosmology. Expansion of the Universe Olber s Paradox Birth of our Universe

Review of Lecture 15 3/17/10. Lecture 15: Dark Matter and the Cosmic Web (plus Gamma Ray Bursts) Prof. Tom Megeath

Astronomy 103: First Exam

Galaxy Formation/Evolution and Cosmic Reionization Probed with Multi-wavelength Observations of Distant Galaxies. Kazuaki Ota

RFI Detectives Activity for Large Public Venues

Part two of a year-long introduction to astrophysics:

Extrasolar Planets: Molecules and Disks

Space Physics Questions CfE

II. The Universe Around Us. ASTR378 Cosmology : II. The Universe Around Us 23

ASTRONOMY CURRICULUM Unit 1: Introduction to Astronomy

LOFAR Key Science Projects and Science Network in Germany

PICO - Probe of Inflation and Cosmic Origins

Astronomy 1504 Section 10 Final Exam Version 1 May 6, 1999

Name Date Period. 10. convection zone 11. radiation zone 12. core

PoS(Cosmology2009)022

Exam Board Edexcel There are 2 exams, each is worth 50% of the GCSE

Active Galactic Nuclei

Number of Stars: 100 billion (10 11 ) Mass : 5 x Solar masses. Size of Disk: 100,000 Light Years (30 kpc)

Moon disc temperature as a function of phase at 1700 MHz

Future Radio Interferometers

Astronomy Ch. 22 Neutron Stars and Black Holes. MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

The Birth Of Stars. How do stars form from the interstellar medium Where does star formation take place How do we induce star formation

Universe Now. 12. Revision and highlights

Study Guide Chapter 2

Lecture Outlines. Chapter 24. Astronomy Today 8th Edition Chaisson/McMillan Pearson Education, Inc.

ASTR 2310: Chapter 6

The Dynamic Radio Sky: On the path to the SKA. A/Prof Tara Murphy ARC Future Fellow

Extrasolar planets. Lecture 23, 4/22/14

The Dawn of Time - II. A Cosmos is Born

Dark Matter ASTR 2120 Sarazin. Bullet Cluster of Galaxies - Dark Matter Lab

The Black Hole in the Galactic Center. Eliot Quataert (UC Berkeley)

Radio Telescopes of the Future

Properties of the Solar System

Transcription:

HOW TO GET LIGHT FROM THE DARK AGES Anthony Smith Lunar Seminar Presentation 2/2/2010

OUTLINE Basics of Radio Astronomy Why go to the moon? What should we find there?

BASICS OF RADIO ASTRONOMY Blackbody Radiation: B 2h c ( 2 3 ) h kt e 1 1 Rayleigh-Jeans Approximation: h e h kt B 1 kt 1 2kT 2 h kt 1 h kt Thus the blackbody function becomes:

For a total power receiver: ΔT T A Predetection Section T RT G ν Square- Law detector -V D The amplifier power output: W G ( T T) sys Low-pass Amplifierintegrator G LF ν LF Recorder The detector has an output voltage that varies with input voltage squared. This means that the detector d-c output voltage is directly proportional to the input power or: V D V G kt sys G k T

Because ΔV << V D i.e. ΔT << T sys high amplification of ΔV is needed to get a reading on the recorder. To make this easier an external voltage of V D is introduced leaving ΔV as the signal output voltage. Thus the signal power becomes: W ' C ' ( k T ) A detector output voltage also exists generating a power density of: W LF G LF 2C ( kt sys The corresponding noise from ΔT is: ' ) 2 2 LF W ' G LF C ' ( k T ) 2

ΔT min =T rms the minimum detectable signal is defined to be the ΔT which produces a power equal to the noise output power W LF. Thus setting the equations equal: T min Given that 0 0 G G T sys ( ( ) d ) 2 2 d 2 LF And the gain function of an ideal integrator: G( ) 2 sin (0.5 (0.5 t LF LF t ) LF 2 0 ) G G LF ( LF ) d (0)

Thus Δν LF =0.5/t LF Combining this with the T min and altering the equation slightly for a dipole array yields: T rms KT t LF N(N And then substituting in the Rayleigh-Jeans Approximation: B min 2 2kKT sys sys tn( N 1) 1)

Earlier we assumed that the T rms was much less than the system temperature. In the Very Long Wavelength VLW this is true because the system temperature is dominated not by the mechanics but by the sky temperature.

WHY GO TO THE MOON?

WHAT S WRONG WITH THE EARTH? The same effect creating the high sky temperatures also occurs in Earth s ionosphere to a much greater degree. Beyond 30MHz, the plasma frequency of the ionosphere kicks in and the atmosphere becomes opaque

Worse than that, fluctuations in the electron density lead to high magnitude scintillations all the way up to the 300MHz range. The moon does have an ionosphere of electrons but its much less dense than that of the Earth producing a lower plasma frequency and thus a lower cutoff. n e

RADIO FREQUENCY INTERFERENCE (RFI) One of the biggest problems in radio astronomy is telling the difference in local and astronomical sources.

The lunar far side always faces away from the Earth creating a dead zone with much less interference. RAE-2 1973

GALACTIC SYNCHROTRON EMISSION A lunar array may eliminate RFI and lower the plasma frequency but it doesn t eliminate synchrotron emission which is 10 6 times brighter than the modeled 21-cm line. Despite this hurdle, it should be noted that astronomers working on the CMB get a signal out of the same amount of noise.

COSMOLOGY After the big bang at ~z=1000 the universe cooled and entered the cosmic dark ages.

Finding the 21 cm line both at the epoch of reionization and during the dark ages will help constrain cosmological models. Epoch of Reionization: Gas heated above CMB by X-rays Early Dark Ages: Collisions cool gas faster than the CMB Late Dark Ages: Population III stars emit Lyα and recouple spin temperature to gas

Given that the signal is expected to be redshifted to less than 100MHz it would be nearly impossible to find on the Earth but a single lunar dipole could find the Cosmic Dark Ages signal in 40 days.

DARK MATTER DECAY DETECTION Another wonderful thing about the dark ages is the simplicity of the universe. This allows a unique chance to look for exotic heat signatures since without stars to provide heat even very small sources could be discovered One possible source that astronomers are on the lookout for is dark matter decay. As the dark matter decays it should heat the gas and alter the profile of the 21-cm line in a measureable way.

EXTRASOLAR PLANET DETECTION Planets with large magnetic fields bend the particles of the local solar wind generating electron cyclotron masers Information from the magnetic field s signature can constrain information on the planet s composition, rotation period, number of satellites, and habitability.

OTHER AREAS OF RESEARCH Surveying for Radio galaxies and quasars that are very bright at long wavelengths Discovering high redshift sources Pinning down the age of quasars and galaxies with jets Constraining galaxy cluster formation models Identifying the structure of the ISM Analyze the properties of the Warm Interstellar Medium Mapping electron densities to find the source of cosmic rays Ultra high energy cosmic rays Detection of hadronic cosmic rays Detection of neutrinos Detection of meteoritic impacts

NECESSARY STEPPING STONES I. Start with a pathfinder mission with a single antenna. This should be able to measure the effects of the moon s ionosphere, the electrical properties of the surface, confirm the RFI environment and detect the redshift of the EoR. II. III. IV. Send a two element interferometer to prove lunar interferometry and do a simple sky survey. Send a three element telescope to look for high energy particles. Build a 30-300 element telescope over 30-100km to look for ISM tomography, planetary bursts, and to do extragalactic surveys. V. Construct the full 10 3-10 7 element telescope over tens of kilometers to finally investigate the cosmic dark ages and measure the magnetic bursts of extrasolar planets.

OPEN QUESTIONS How does the moon s ionosphere vary? What are the electrical properties of the lunar surface? What effects do meteoritic impacts have on measurements? How does the optical depth of the ISM vary? How much scattering do the IPM and ISM do at frequencies?

Questions?

REFERENCES Jester S. and Falke, H. (2009) Science with a lunar low-frequency array: From the dark ages of the Universe to nearby exoplanets. New Astronomy Reviews, 53, 1-26. Pritchard, J. and Loeb, A. (2008) Evolution of the 21 cm signal throughout cosmic history. Physical Review D, 78, 103511. Zarka, P. (2000) Plasma interactions of exoplanets with their parent star and associated radio emissions. Planetary Space Sciences, 55, 598-617. Kraus, John D. (1986). Radio Astronomy. Powell, Ohio: Cygnus-Quasar Books

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback