182 pages

English

Vous pourrez modifier la taille du texte de cet ouvrage

Découvre YouScribe en t'inscrivant gratuitement

Je m'inscris

A User's Guide to the Universe , livre ebook

Turner Publishing Company - Jeff Blomquist , Dave Goldberg

Découvre YouScribe en t'inscrivant gratuitement

Je m'inscris

Obtenez un accès à la bibliothèque pour le consulter en ligne
En savoir plus

182 pages

English

Vous pourrez modifier la taille du texte de cet ouvrage

Obtenez un accès à la bibliothèque pour le consulter en ligne
En savoir plus

A propos
Informations
Extrait

Description

Answers to science's most enduring questions from "Can I break the light-speed barrier like on Star Trek?" and "Is there life on other planets?" to "What is empty space made of?"

This is an indispensable guide to physics that offers readers an overview of the most popular physics topics written in an accessible, irreverent, and engaging manner while still maintaining a tone of wry skepticism. Even the novice will be able to follow along, as the topics are addressed using plain English and (almost) no equations. Veterans of popular physics will also find their nagging questions addressed, like whether the universe can expand faster than light, and for that matter, what the universe is expanding into anyway.

Gives a one-stop tour of all the big questions that capture the public imagination including string theory, quantum mechanics, parallel universes, and the beginning of time
Explains serious science in an entertaining, conversational, and easy-to-understand way
Includes dozens of delightfully groan-worthy cartoons that explain everything from special relativity to Dark Matter

Filled with fascinating information and insights, this book will both deepen and transform your understanding of the universe.
Acknowledgments.

Introduction.

“So, what do you do?”

1 Special Relativity.

“What happens if I’m traveling at the speed of light, and I try to look at myself in a mirror?”

Why can’t you tell how fast a ship is moving through fog?

How fast does a light beam go if you’re running beside it?

If you head off in a spaceship traveling at nearly the speed of light, what horrors await you when you return?

Can you reach the speed of light (and look at yourself in a mirror)?

Isn’t relativity supposed to be about turning atoms into limitless power?

2 Quantum Weirdness.

“Is Schrödinger’s Cat Dead or Alive?”

Is light made of tiny particles, or a big wave?

Can you change reality just by looking at it?

If you look at them closely enough, what are electrons, really?

Is there some way I can blame quantum mechanics for all those times I lose things?

Can I build a transporter, like on Star Trek?

If a tree falls in the forest and no one hears it, does it make a sound?

3 Randomness.

“Does God play dice with the universe?”

If the physical world is so unpredictable, why doesn’t it always seem that way?

How does carbon dating work?

Does God play dice with the universe?

4 The Standard Model.

“Why didn’t the Large Hadron Collider destroy Earth?”

What do we need a multibillion-dollar accelerator for, anyway?

How do we discover subatomic particles?

Why are there so many different rules for different particles?

Where do the forces really come from?

Why can't I lose weight (or mass)—all of it?

How could little ol' LHC possibly destroy the great big world?

If we discover the Higgs, can physicists just call it a day?

5 Time Travel.

“Can I build a time machine?”

Can I build a perpetual motion machine?

Are black holes real, or are they just made up by bored physicists?

What happens if you fall into a black hole?

Can you go back in time and buy stock in Microsoft?

Who does time travel right?

How can I build a practical time machine?

What are my prospects for changing the past?

6 The Expanding Universe.

“If the universe is expanding, what’s it expanding into?”

Where is the center of the universe?

What’s at the edge of the universe?

What is empty space made of?

How empty is space?

Where’s all of the stuff?

Why is the universe accelerating?

What is the shape of the universe?

What’s the universe expanding into?

7 The Big Bang.

“What happened before the Big Bang?”

Why can’t we see all the way back to the Big Bang?

Shouldn’t the universe be (half) fi lled with antimatter?

Where do atoms come from?

How did particles gain all that weight?

Is there an exact duplicate of you somewhere else in time and space?

Why is there matter?

What happened at the very beginning of time?

What was before the beginning?

8 Extraterrestrials.

“Is there life on other planets?”

Where is everybody?

How many habitable planets are there?

How long do intelligent civilizations last?

What are the odds against our own existence?

9 The Future.

“What don’t we know?”

What is Dark Matter?

How long do protons last?

How massive or nuetinos?

What won’t we know anytime soon?

Further Reading.

Technical Reading.

Index.

Sujets

Astronomie

Astrophysique

Physique

Physical attractiveness

Science

Cosmology

Sciences et techniques

Space Science

Informations

Publié par	Turner Publishing Company
Date de parution	02 février 2010
Nombre de lectures	0
EAN13	9780470559512
Langue	English

Informations légales : prix de location à la page 0,1200€. Cette information est donnée uniquement à titre indicatif conformément à la législation en vigueur.

Extrait

Table of Contents

Title Page
Copyright Page
Acknowledgments
Introduction

Chapter 1 - Special Relativity

Why can’t you tell how fast a ship is moving through fog?
How fast does a light beam go if you’re running beside it?
If you head off in a spaceship traveling at nearly the speed of light, what ...
Can you reach the speed of light (and look at yourself in a mirror)?
Isn’t relativity supposed to be about turning atoms into limitless power?

Chapter 2 - Quantum Weirdness

Is light made of tiny particles, or a big wave?
Can you change reality just by looking at it?
If you look at them closely enough, what are electrons, really?
Is there some way I can blame quantum mechanics for all those times I lose things?
Can I build a transporter, like on Star Trek?
If a tree falls in the forest and no one hears it, does it make a sound?

Chapter 3 - Randomness

If the physical world is so unpredictable, why doesn’t it always seem that way?
How does carbon dating work?
Does God play dice with the universe?

Chapter 4 - The Standard Model

What do we need a multibillion-dollar accelerator for, anyway?
How do we discover subatomic particles?
Why are there so many different rules for different particles?
Where do the forces really come from?
Why can’t I lose weight (or mass)—all of it?
How could little ol’ LHC possibly destroy the great big world?
If we discover the Higgs, can physicists just call it a day?

Chapter 5 - Time Travel

Can I build a perpetual motion machine?
Are black holes real, or are they just made up by bored physicists?
What happens if you fall into a black hole?
Can you go back in time and buy stock in Microsoft?
Who does time travel right?
How can I build a practical time machine?
What are my prospects for changing the past?

Chapter 6 - The Expanding Universe

Where is the center of the universe?
What’s at the edge of the universe?
What is empty space made of?
How empty is space?
Where’s all of the stuff?
Why is the universe accelerating?
What is the shape of the universe?
What’s the universe expanding into?

Chapter 7 - The Big Bang

Why can’t we see all the way back to the Big Bang?
Shouldn’t the universe be (half) filled with antimatter?
Where do atoms come from?
How did particles gain all that weight?
Is there an exact duplicate of you somewhere else in time and space?
Why is there matter?
What happened at the very beginning of time?
What was before the beginning?

Chapter 8 - Extraterrestrials

Where is everybody?
How many habitable planets are there?
How long do intelligent civilizations last?
What are the odds against our own existence?

Chapter 9 - The Future

What is dark matter?
How long do protons last?
How massive are neutrinos?
What won’t we know anytime soon?

Further Reading
Technical Reading
Index

This book is printed on acid-free paper.
Copyright © 2010 by Dave Goldberg and Jeff Blomquist. All rights reserved
Published by John Wiley & Sons, Inc., Hoboken, New Jersey Published simultaneously in Canada
Photo credits: page 48, © Akira Tonomura; page 187, Andrew Fruchter (STScI) et al., WFPC2, HST, NASA; page 204, NASA/WMAP Science Team; page 231, J. R. Gott & L.-X. Li

No part of this publication may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic, mechanical, photocopying, recording, scanning, or otherwise, except as permitted under Section 107 or 108 of the 1976 United States Copyright Act, without either the prior written permission of the Publisher, or authorization through payment of the appropriate per-copy fee to the Copyright Clearance Center, 222 Rosewood Drive, Danvers, MA 01923, (978) 750-8400, fax (978) 646-8600, or on the web at www.copyright.com . Requests to the Publisher for permission should be addressed to the Permissions Department, John Wiley & Sons, Inc., 111 River Street, Hoboken, NJ 07030, (201) 748-6011, fax (201) 748-6008, or online at http://www.wiley.com/go/permissions .
Limit of Liability/Disclaimer of Warranty: While the publisher and the author have used their best efforts in preparing this book, they make no representations or warranties with respect to the accuracy or completeness of the contents of this book and specifically disclaim any implied warranties of merchantability or fitness for a particular purpose. No warranty may be created or extended by sales representatives or written sales materials. The advice and strategies contained herein may not be suitable for your situation. You should consult with a professional where appropriate. Neither the publisher nor the author shall be liable for any loss of profit or any other commercial damages, including but not limited to special, incidental, consequential, or other damages. For general information about our other products and services, please contact our Customer Care Department within the United States at (800) 762-2974, outside the United States at (317) 572-3993 or fax (317) 572-4002.

Wiley also publishes its books in a variety of electronic formats. Some content that appears in print may not be available in electronic books. For more information about Wiley products, visit our web site at www.wiley.com .
Library of Congress Cataloging-in-Publication Data:
Goldberg, Dave, date.
A user’s guide to the universe: surviving the perils of black holes, time paradoxes, and quantum uncertainty / Dave Goldberg and Jeff Blomquist. p. cm.
Includes index.
ISBN 978-0-470-49G51-0 (cloth)
1. Physics—Popular works. I. Blomquist, Jeff II. Title. QC24.5.G65 2010 530—dc22
2009028773

Acknowledgments
This book has been a labor of love. We’ve tried to translate our love of teaching and our love of physics into something that could be understood and enjoyed by people at every level. We are so grateful for the feedback from our friends, family, and colleagues. First and foremost, Dave wants to thank his wife, Emily Joy, who was so supportive throughout, and who gave her honest opinions at every turn. Jeff wishes to thank his family (especially his brother), who remained politely neutral during the majority of his winded tirades and pointless doodling; he is also grateful to Frank McCulley, Harry Augensen, and Dave Goldberg, the three physicists who inspired him to give physics a fair shake. We are also indebted to feedback from Erica Caden, Amy Fenton, Floyd Glenn, Rich Gott, Dick Haracz, Doug Jones, Josh Kamensky, Janet Kim, Amy Lackpour, Patty Lazos, Sue Machler (aka Dave’s mom), Jelena Maricic, Liz Patton, Gordon Richards, David Spergel, Dan Tahaney, Brian Theurer, Michel Vallieres, Enrico Vesperini, Alf Whitehead, Alyssa Wilson, and Steve Yenchik. We also would like to acknowledge Geoff Marcy and Evelyn Thomson, with whom we had several enlightening discussions. We appreciate Rich Gott and Akira Tonomura allowing us to reproduce their figures. Thanks also to our very hardworking agent, Andrew Stuart, and our excellent editors, Eric Nelson and Constance Santisteban
Introduction
“So, what do you do?”

The life of a physicist can be a lonely one.
Imagine this: You sit down in an airplane, and the person next to you asks you what you do for a living. You reply that you’re a physicist. From here, the conversation can go one of two ways. Nine times out of ten, the first thing out of his or her mouth is something along these lines: “Physics? I hated that class!” 1
You’ll then spend the rest of the trip (or party, or elevator ride, or date) apologizing for the emotional trauma that physics has apparently inflicted on your erstwhile friend. These random encounters often reveal an almost joyful contempt, reserved specifically for the fields of physical science and mathematics. “Oh, I’m terrible at algebra!” for example, is said in an almost boastful tone, in a way that “I barely even know how to read!” never would. But why?
Physics has a somewhat unfair reputation for being hard, impractical, and boring. Hard? Perhaps. Impractical? Definitely not. Indeed, when people try to “sell” physics to the public, it is almost always in terms of how it can be used to build bridges or launch rockets—that is, how physics is ultimately the foundation for engineering or chemistry.
But boring? That’s where we really take issue. The problem, as we see it, is that the practical side of physics is almost always put forward at the expense of the interesting side. Even folks with technical focuses such as engineering and computer science typically don’t get past mechanics and electromagnetism to the really fun stuff. And that’s a shame, because quite frankly there has been very little cutting-edge research done on pulleys in the past few years.
This hostility to physics seems to be ingrained, and makes it difficult to have discussions without jading an audience. In starting a scientific conversation with a “civilian,” we purveyors of physics often feel like we’re trying to force people to eat their vegetables, and rationalize it in the same way. We never begin physics discussions with “It’s fun!” but almost always with “It’s necessary,” which naturally drains all of the fun out of it.
In an era when new technologies are constantly emerging, scientific literacy should be fundamental. On the other hand, it isn’t necessary that you have four extra years of college sciences to understand them. You don’t need to have a detailed knowledge of exactly how the physics works to appreciate the revolutions in quantum computing or cosmology. It is important, rather, to understand why these developments are significant, and how they are poised to change technology and our lives.
And it’s not simply that people need to understand a particular theory. Physics is the archetypal inductive science, and by understanding how science proceeds, people are better able to make informed decisions about issues from