Touch the Universe A NASA Braille B o o k o f Astronom y
b y N o r e e n G r ice
The Joseph Henry Press 500 Fifth Str...
59 downloads
988 Views
2MB Size
Report
This content was uploaded by our users and we assume good faith they have the permission to share this book. If you own the copyright to this book and it is wrongfully on our website, we offer a simple DMCA procedure to remove your content from our site. Start by pressing the button below!
Report copyright / DMCA form
Touch the Universe A NASA Braille B o o k o f Astronom y
b y N o r e e n G r ice
The Joseph Henry Press 500 Fifth Street, NW Washington, DC 20001
Joseph Henry Press • 500 Fifth Street, NW • Washington, DC 20001 The Joseph Henry Press, an imprint of the National Academ ies Press, w a s c r e a t e d w i t h t h e g o a l o f m a k i n g b o o k s o n s c i e n c e , t e c h n o l o g y, a n d h e a l t h m o re widely available to professionals and the public. Joseph Henry was one of the early founders of the National Academ y o f S c i e n c e s a n d a l e a d e r in early A m e r ican science. Any opinions, findings, conclusions, or recomm e n d a t i o n s e x p r e s s e d in this volume are those of the author and do not necessarily reflect the v iew s o f t h e N a t i o n a l A c a d e m y o f Sciences or its affiliated institutions. Library of Congress Cataloging-in-Publication Data G rice, Noreen. To u c h t h e u n i v e r s e : a N A S A B r a i l l e b o o k o f a s t r o n o m y / b y N o r e e n G rice. p.cm . C a p t ions also in Braille; im a g e s e m b o s s e d to be perceivable to the v ision im p a ired. I S B N 0 - 3 0 9 - 0 8 3 3 2 - X ( p b k . : a lk. paper) 1 . A s t r o n o m y — P ictorial works. 2. Braille books— S p e c i m e n s . I. Title. QB68.G75 2002 520’.22’2— d c 2 1 2002010769 C o p y r i g h t © 2 0 0 2 b y N o r e e n G r i c e . A l l rights reserved. P rinted in the United States of Am e rica by the Reese Press, Baltim o re, M a ryland.
ii
Table of Contents
D e d i c a t i o n a n d A c k n o w l e d g m e n ts . . . . . . . . . . . v A b o u t the A u thor . . . . . . . . . . . . . . . . . . . . . . . . vii Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 T h e H u b b l e S p a c e Te l e s c o p e . . . . . . . . . . . . . . 3 T h e H u b b l e S p a c e Te lescope (illustration) . . . . 5 H S T o rbits Earth . . . . . . . . . . . . . . . . . . . . . . . . 7 H S T o rbits Earth (illustration) . . . . . . . . . . . . . . 9 Jupiter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Jupiter (illustration) . . . . . . . . . . . . . . . . . . . . . 1 3 S a turn . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 5 S a turn (illustration) . . . . . . . . . . . . . . . . . . . . . 1 7 U ranus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 U r a n u s ( illustration) . . . . . . . . . . . . . . . . . . . . . 2 1 T h e R i n g N e b u la . . . . . . . . . . . . . . . . . . . . . . . 2 3 T h e R i n g N e b u la (illustration) . . . . . . . . . . . . . 2 5 The Hourglass Nebula . . . . . . . . . . . . . . . . . . . 27 T h e H o u rglass Nebula (illustration) . . . . . . . . . 2 9 NGC 2392—The Eskimo Nebula . . . . . . . . . . 31
iii
N G C 2 3 9 2 — T h e E s k imo Nebula (illustration) E ta C a rinae . . . . . . . . . . . . . . . . . . . . . . . . . . E ta C a rinae (illustration) . . . . . . . . . . . . . . . . G a s e o u s P illars i n M 1 6 — T h e E a g le N e b u la . G a s e o u s P illars i n M 1 6 — T h e E a g le N e b u la (illustration) . . . . . . . . . . . . . . . . . . . . . . . . . G lobular Cluster NG C 6 0 9 3 . . . . . . . . . . . . . G lobular Cluster NG C 6 0 9 3 ( illustration) . . . . G a laxy NGC 4603 . . . . . . . . . . . . . . . . . . . . . G a l a x y N G C 4 6 0 3 ( illustration) . . . . . . . . . . . G a l a x y C luster Abell 2 2 1 8 . . . . . . . . . . . . . . . G a l a x y C luster Abell 2 2 1 8 ( illustration) . . . . . H u b b le N o rthern D e e p F ield . . . . . . . . . . . . . H u b b le N o rthern D e e p F ield (illustration) . . . Final Thoughts . . . . . . . . . . . . . . . . . . . . . . . .
iv
. . . .
33 35 37 39
. . . . . . . . . .
41 43 45 47 49 51 53 55 57 59
D E D ICATION T h e s p a c e p r o g r a m is bringing our universe into focus. This book is dedicated to science enthusiasts of all visual abilities - enjoy!
ACKNOWLEDGMENTS T h e ideas that led to the creation of Touch the Universe: A NASA Braille Book of Astronomy, w e r e d e v e l o p e d j o i n t l y b y N o r e e n G r i c e a n d D r. B e r n h a r d B e c k - W i n c h a t z ( D e P a u l U n iversity), who gratefully a c k n o w ledge fundi n g b y N A S A’s H u b b le S p a c e Te l e s c o p e C y c l e 9 E d u c a t i o n a n d P u b lic O u treach G rant. The tactile illustrations were created by N o r e e n G rice w ith evaluation by Benning W e n tworth, Disney’s 2001 Te a c h e r o f t h e Year, and his students at the Colorado School for the Deaf and B lind.
v
T h e text w a s c h e c k e d for scientific accuracy by Dr. B e c k - W i n c h a t z a n d D r. D e n n is D a w s o n ( W e s t e r n C o n n e c ticut S tate University). T h a n k s t o S h i r l e y K e ller and Irm a G o ldberg, of C reative Adaptations for Learning, who e n thusiastically assisted the author with the design a n d p roduction of the prototype tactile illustrations, a n d to Pauline Gobeil for assistance with the design of the cover illustration. S p e c ial thanks to Steve M a r a n a n d R a y V illa r d o f N A S A , S k i p B a r k e r, t h e J o s e p h H e n r y P r e s s , R e e s e P r e s s , a n d N a t i o n a l Braille Press for their unique collaboration during the final production phase, and to the astronom e r s w h o a llo w e d their celestial images to be part of this book.
vi
ABOUT THE AUTHOR N o r e e n G r i c e h o l d s a B a c h e lor of A r t s d e g r e e in A s tronom y f r o m B o s t o n U n i v e r s i t y, a M a s ter of S c ience degree in A s tronom y from S a n D iego State U n iversity, a P rofessional Certificate in M u s e u m S tudies from Tufts University, a n d a C e r t ificate in Nonprofit M a n a g e m e n t t h r o u g h t h e B o s t o n C e n t e r for Adult Education. She has taught astronom y courses for students of all ages, from g ram m a r s c h o o l t h r o u g h c o lle g e , a n d h a s w o r k e d in the planetarium fie ld since 1984. Her first book on astronom y, Touch the Stars , is a Braille/print edition using tactile illustrations.
vii
viii
INTRODUCTION T h e u n iverse exi s t e d l o n g b e f o r e t h e d a y y o u w e r e b o rn! In fact, astronom e rs believe that it is billions of years old. W h a t you m a y n o t k n o w is that our u n d e r s t a n d i n g o f t h e u n iverse has com e a b o u t only fairly recently. T h o u s a n d s o f y e a r s a g o , a n c ient sky w a tchers o b s e r v e d t h e o b jects of the night sky. T h e y s a w tiny stars, “w a n d e r ing” stars (w h i c h w e c a l l planets), and the changing moon. F o u r hundred years ago, telescopes were first p o inted at the night sky, b ringing into view distant stars that w e r e n o t v i s ible to the unaided eye. M o o n s w e r e s e e n o r b iting Jupiter, a n d c r a t e r s w e r e s e e n o n o u r o w n m o o n . Larger telescopes allow e d observers to glim p s e fuzzy patches of light; som e w e re large groups of stars, som e w e re rem n a n ts of stars’ d e a ths, and others were “citie s o f stars” called g a laxies.
1
T h e largest telescopes on Earth are located on m o u n taintops, far from c ity lights and high above m a n y o f the Earth’s cloud layers. H o w e v e r, Earthb a s e d t e l e s c o p e s s u ffer from the haze of the Earth’s atm o s p h e r e a n d a r e a t t h e m e r c y o f c h a n g e a b l e w e a ther patterns. N A S A’s H u b b l e S p a c e Te l e s c o p e d o e s n ’t have these problems; it orbits the Earth a b o v e t h e c l o u d s a n d t h e a t m o s p h e r e a n d is able to s e e c e lestial objects w ith incredible clarity. It is w ith t h e H u b b le S p a c e Te l e s c o p e t h a t w e b e g i n o u r v o y a g e o f d iscovery, starting at Earth and m o v ing to t h e e d g e o f o u r u n d e r s t a n d ing. Prepare to be a s t o n i s h e d a s y o u t o u c h t h e u n iverse! N o te: The Saturn, N G C 4 6 0 3 , a n d A b e ll 2 2 1 8 tactile illustrations m u s t b e v i e w e d h o r izontally. Please turn t h e b o o k c lockwise so that the binding is at the top.
2
F igure 1. THE HUBBLE SPACE TELESCOPE T h e H u b b l e S p a c e Te l e s c o p e ( H S T ) w a s n a m e d after the A m e rican astronom e r E d w in H u b b le. It is 4 3 .5 feet (13.1 m e ters) long and 14 feet (4.27 m e ters) w ide. The telescope w e i g h s 2 5 , 5 0 0 p o u n d s (11,000 kilogram s ) . T h e H S T w a s c o n s t r u c t e d o n E a r t h a n d d e p loyed into space by the space shuttle in 1990. Two solar p a n e ls, one on either side of the telescope, provide p o w e r for the telescope’s equipm e n t. A s tro n o m e rs o n E a r t h c o n t r o l the telescope. Im a g e s a r e r e layed b y s a t e llite s d o w n to the control center in Baltim o re, M a ryland.
3
F i g u r e 1 s h o w s t h e H u b b l e S p a c e Te l e s c o p e in space. The solar panels have a checkered texture. T h e t e l e s c o p e a n d s o lar panels are raised by a tactile outline.
4
Figure 2. HST ORBITS EARTH T h e H S T o r b its a b o u t 3 7 0 m ile s ( 6 0 0 k m ) above the Earth’s surface. Because it is above the Earth, it d o e s n o t h a v e t o s e e t h r o u g h t h e h a z e o f t h e E a r t h ’s atm o s p h e r e . H u b b le is not affected by clouds, rain, o r o t h e r t y p e s o f b a d o b s e r v i n g c o n d itio n s c a u s e d b y E a r t h ’s atm o s p h e r e . W ith its c l e a r v i e w o f s p a c e , t h e H S T h a s p r o v i d e d s o m e o f the m o s t am a z ing views of distant celestial o b jects. From n e ighboring planets, to the birth and d e a th of stars, to groups of stars and galaxies b e y o n d t h e M ilk y W a y, H u b b le is helping us to better u n d e r s t a n d o b jects of our universe and our place w ithin it.
7
F i g u r e 2 d e p icts the HST orbiting the Earth. The Earth’s edge (lim b ) i s s h o w n a s a b r o k e n c u r v e . T h e b o rder of A frica is show n b y a d o tte d lin e . This image also appears on the cover of this book.
8
Figure 3. JUPITER Jupiter is the largest planet in our solar system . It h a s a d i a m e ter over eleven tim e s that of Earth. O v e r o n e t h o u s a n d E a r t h s c o u ld fit inside Jupiter! T h is giant planet orbits the sun five tim e s farther out than Earth. It takes about tw e lve years for Jupiter to c o m p lete one trip around the sun. Jupiter is a gas planet, m a d e m o s tly of hydrogen, h e liu m , am m o n ia, and m e thane. To t h e n a k e d e y e , i t a p p e a rs as a bright white star. T h r o u g h a t e l e s c o p e , it reveals stripes called bands. The planet rotates o n c e i n a b o u t 1 0 h o u r s a n d t h is m a k e s the planet v e r y w indy. A s t h e b a n d s m o v e p a s t e a c h o t h e r, th e y w h irl a r o u n d c ircular storm s .
11
Jupiter boasts the largest storm in the solar system . It is called the Great Red Spot and has been observed for hundreds of years. T h is photograph of Jupiter w a s t a k e n b y R i t a B e e b e ( N e w M e x ico State U n iversity) and Am y S i m o n ( C o r n e ll U n iversity) w ith t h e H S T i n F e b r u a r y 1 9 9 5 . F i g u r e 3 s h o w s t h e o u t l ine of Jupiter. T h e b a n d s a r e displayed as tactile lines that cross the planet. The b r o k e n c u r v e d l ines indicate different currents in the b a n d s o f g a s . T h e G reat R e d S p o t is r a i s e d a long w ith a few s m a ller storm s ( s h o w n a s h o llo w c ircles).
12
F igure 4. SATURN S a turn, the sixth planet from the sun, is often called the “ringed planet.” It is not the only planet with rin g s , but it does have the m o s t num e r o u s a n d s p e c t a c u lar rings. The rings are m a d e o f ice and s m a ll rocks. S a turn is the second largest gas-giant planet in our solar system . It h a s a d iameter of alm o s t n i n e a n d a h a lf tim e s that of Earth. Saturn orbits the sun at a distance that is m o r e t h a n n ine and a half tim e s the distance betw e e n t h e E a r t h a n d s u n . To t h e n a k e d e y e , S a t u r n a p p e a r s a s a d im yellow star; but when s e e n t h r o u g h a s m a ll b a c k y a r d t e lescope, Saturn a p p e a rs as a disk with elongations that resem b le e a rs!
15
F igure 4 is an im a g e o f Saturn that was taken with the HST in January 1998 by E. Karkoschka (University of Arizona). D iffe r e n t s h a d e s o f b l u e indicate variations of cloud p a rticle s i z e s a n d c h e m ical com p o s itio n s . G r e e n a n d y e llo w indicate haze. The diffe rent colors are represented by tactile stripes across the planet. The rin g s a r e s h o w n w ith a b u m p y texture.
16
F igure 5. URANUS U r a n u s is the seventh planet from the sun. It is about half the size of Saturn and orbits t h e s u n a t o v e r n ineteen tim e s t h e d i s t a n c e b e t w e e n t h e E a r t h a n d s u n . T h e p l a n e t c o m p letes one full orbit around t h e s u n e v e r y e ighty-four years. U r a n u s is a “tipped” planet because its poles s o m e tim e s face directly tow a rd the sun. M a n y astronom e r s b e lie v e t h a t U r a n u s w a s tip p e d o n its s i d e w h e n a n o t h e r o b ject collided w ith it b illio n s o f years ago. U r a n u s is not visible with the naked eye. Through a large telescope, the planet appears as a blue-green disk.
19
F igure 5 is an im a g e o f U r a n u s t h a t w a s c a p t u r e d b y E . K a r k o s c h k a ( U n iversity of A rizona) u s i n g t h e H S T in A u g u s t 1998. A b right ring is visible and the planet a p p e a r s t o a l s o h a v e a f e w f a inter rings. Blue and green colors indicate clear layers of the atm o s p h e r e . Yello w indicates reflective layers and orange/red colors are the highest layers of the atm o s p h e r e . The b o u n d a r ies betw e e n the different colors are represented with raised lines across the planet. The brightest ring is shown with a dotted tactile line. B a s e d o n o b s e r v a t ions of Uranus, astronom e rs b e lieve that som e c louds orbit this gas planet at s p e e d s g r e a t e r t h a n 3 0 0 m ile s ( 4 8 0 k ilo m e ters) per hour!
20
F igure 6. THE RING NEBULA W e n o w l e a v e o u r s o lar system a n d travel tow a rd a c o n s t e llation called Lyra. W ithin this star pattern is a planetary nebula called the Ring Nebula. This cloud is the rem a ins of a star, near the end of its life, w h ich i s s h e d d i n g its o u ter layers. Early astronom e rs using t e l e s c o p e s o b s e r v e d s u c h “ p lanet-shaped” clouds in s p a c e a n d n a m e d them p lanetary nebulae, but they are not really related to planets. T h e R i n g N e b u la resem b les a “sm o k e r ing” in s p a c e . T h e d y ing star is visible in the center. A telescope is required to see the Ring Nebula.
23
T h e H u b b le Heritage Te a m u s e d t h e H S T to im a g e t h e R i n g N e b u l a i n O c t o b e r 1 9 9 8 , a s s e e n i n F igure 6 . T h e t r u e c o lors in this im a g e indicate different layers of gases: helium (blue), oxygen (green), and nitrogen (red). The outline of the outer layer of cool nitrogen is represented by a dotted texture, the m iddle hot layer w ith o x y g e n h a s a t e x t u r e o f p a r a lle l lin e s , a n d t h e v e r y h o t c e n t e r a r e a o f h e liu m , with a star, has no texture.
24
F igure 7. THE HOURGLASS NEBULA T h e H o u rglass Nebula is a planetary nebula located about 8,000 li g h t y e a r s a w a y, m e a n ing that its light takes 8,000 years to reach Earth. A dying star in the c e n t e r o f t h e n e b u la is ejecting gaseous m a terial into space. The first astronom e rs to view this collection of star debris through a telescope thought it resem b l e d t h e s h a p e o f a n h o u r g lass, so they g a v e it that nam e . T h is January 1996 picture, taken by R . S a h a i a n d J . Trauger of the Jet Propulsion Laboratory, re v e a ls the n e b u la’s detailed wispy structure and a pair of intersecting elliptical rings at the center.
27
In this photograph, different colors are used to represent layers of gases: nitrogen (red), hydrogen ( g r e e n ) , a n d o x y g e n ( b l u e ) . T h e d y ing star is seen in t h e c e n t e r. T h e c u r v e d h o u r g l a s s - s h a p e d g a s e o u s structure is raised as curved solid lines and incom p lete lines.
28
F igure 8. NGC 2392 - THE ESKIMO NEBULA A s a s tar’ s g a s e s u n d e r g o n u c lear reactions, they are converted from low e r m a s s e lem e n t s i n t o h i g h e r mass ones. When a star can no longer create new elem e n ts, it b e c o m e s u n s table. A b o u t 1 0 , 0 0 0 y e a r s a g o , a s u n - like star in the c o n s t e llation of G e m ini becam e u n s t a b l e a n d b e g a n to fling its gases into space. The gaseous relic of this star is called the Eskim o N e b u l a b e c a u s e it resem b les the shape of a head surrounded by a fur h o o d fro m a w inter coat. The “head” is a bubble of g a s s u r r o u n d i n g t h e d y ing star, and the “fur” is g a s e o u s m a terial m o v ing away from the star. T h e E s k imo Nebula, also called NGC 2392, is visible o n ly w ith a telescope.
31
A . Fruchter and the Early Release O b s e rvation ( E R O ) Te a m u s e d t h e H S T i n J a n u a r y 2 0 0 0 t o t a k e this im a g e ( F igure 8) of the Eskim o N e b u la. The n e b u l a ’ s g l o w i n g g a s e s p r o d u c e t h e c o lors used in this im a g e : nitrogen (red), hydrogen (green), oxygen (blue), and helium (violet). T h e “ h e a d ” a n d s u r r o u n d ing gases are raised w ith tactile lines. G a s e s in the “fur” shell are shown as raised curved lines.
32
Figure 9. ETA CARINAE Travelin g to the constellation of Carina, w e s e e a star called Eta Carinae, one hundred ti m e s m o r e m a s s ive than our sun. This star becam e v e r y unstable and had a tremendous explosion when, o n e h u n d red fifty years ago, it becam e o n e o f the brightest naked-eye stars in the southern h e m isphere. In Septem b e r 1995, J. M o rse (University of C o lorado) used the HST to image Eta Carinae. Huge “blobs” of gases are seen on each side, m o v i n g a w a y f r o m the center at speeds of 1.5 m illio n m iles (2.5 m illio n k ilo m e ters) per hour. T h e central star, not visible in this im a g e , radiates five m illio n tim e s m o r e p o w e r t h a n o u r s u n !
35
In Figure 9, Eta Carinae is shown as a tactile o u tlin e . G a s e s a r e r e p r e s e n t e d b y b r o k e n c u r v e d lines.
36
Figure 10. G A S E O U S P ILLARS IN M16 THE EAGLE NEBULA N o t all n e b u lae are the result of dying stars. W ithin t h e c o n s t e llation of Serpens is M 1 6 , also called the E a g le N e b u la. This is an area of gases that r e s e m b l e s t h e s h a p e o f a n e a g l e ’s wing. W e a p p roach the tip of a wing and see pilla r s o f g a s , thousands of li g h t y e a r s a w a y, in space! (A light year is the distance that light travels in one year, about 6 trillio n m iles or 9.5 trillion kilom e ters.) This is the a s t o n ishing discovery m a d e b y J . H e s t e r a n d P. S c o w e n o f Arizona State University, using the H S T, w ith w h ich they captured this im a g e in April 1995. T h e p illar-like structures are actually colum n s o f cool interstellar hydrogen gas and dust that act as incubators for new stars.
39
U ltraviolet radiation from n e a r b y s tars is eroding the pillars. Young stars will eventually em e rge from the pillars. F i g u r e 1 0 s h o w s t h e E a g le Nebula pillars with a m ixture of colors that represent different layers of g a s : s u lfu r (red), hydrogen (green), and oxygen (blue). The pillars are outlined by a solid tactile line w ith broken curved lin e s i n s ide representing the m ixing gas layers.
40
F igure 11. GLOBULAR CLUSTER NGC 6093 N o w let’s step back from o u r local area of the g a laxy. G a laxies are som e tim e s c a lled “star cities.” A lmost every star visible to the naked eye in our night sky is located within our M ilk y W a y G a laxy. O n the clearest night, far from c ity lig h ts, it is possible to s e e a f e w t h o u s a n d s t a r s , a p p e a r i n g a s p i n p o ints of lig h t against the black night sky. T h e M ilk y W a y c o n t a ins hundreds of billio n s o f stars, so w e a c tually o n l y s e e a h a n d f u l of th e g a laxy’s population. O u r Milky Way Galaxy is called a spiral galaxy b e c a u s e it has spiral arm s i n a p i n w h e e l s h a p e . W e d o n ’t live in the center of the galaxy; we live near a spiral arm , about two thirds of the distance from the c e n t e r.
43
S w a rming like bees around the center of our M ilky W a y a r e d e n s e g r o u p s o f s t a r s c a lle d g lobular c lusters. These star clusters contain hundreds of thousands of stars, all b o u n d together by gravity. T h r o u g h a s m a ll telescope, they look like “ s n o w b a lls” of stars w ith bright centers so that the individual stars seem to “blend” together. N G C 6 0 9 3 (also called M 8 0 ) is a g lobular cluster l o c a t e d 2 8 , 0 0 0 lig h t years from E a rth. W h a t w e s e e t o d a y i s h o w t h e g lobular cluster looked 28,000 years ago! T h e H u b b le Heritage Te a m a t N A S A u s e d t h e H S T to capture this im a g e o f N G C 6 0 9 3 in early 1999. The stars in N G C 6 0 9 3 a r e b e lie v e d t o b e s o m e o f the oldest stars in the universe, with ages up to 15 billio n y e a r s . I n F igure 11, the stars are shown as raised dots.
44
Figure 12. GALAXY NGC 4603 L e a v ing our M ilk y W a y G a laxy, w e tra v e l to another spiral galaxy called NG C 4 6 0 3 . It lies 108 m illio n lig h t years from u s .
47
T h is 1999 im a g e w a s t a k e n b y J . N e w m a n (University of C a lifo r n ia, Berkeley) using the HST. In F igure 12, w e s e e a b r ight galactic center and the spiral arm s o f s t a r s . T h e g a l a x y, w ith s p iral arms, is in tactile outline. Stars are show n a s r a i s e d d o t s a n d b u m p y texture.
48
Figure 13. GALAXY CLUSTER ABELL 2218 G a laxies com e in different shapes. O u r M i l k y W a y G a laxy is spiral-shaped. Som e g a l a x i e s h a v e o n ly c ircular or slightly elongated shapes; these are called elliptical galaxies. Som e g a l a x i e s a r e s h a p e d lik e S a turn, with a circular center and elongated s ides; these are called lenticular galaxies. Som e g a laxies look like spirals but have a line of stars (calle d a b a r ) c r o s s ing their centers; these are called b a rre d s p ira l galaxies. Som e g a l a x i e s h a v e n o n s y m m e trical shapes; they are called irregular or p e c u lia r g a laxies. G a laxies are gravitationally bound together in groups. O u r Milky Way is part of the Local Group w h ich, w ith o ther clusters of galaxies, form s the L o c a l Supercluster.
51
I n J a n u a r y 2 0 0 0 , A . F r u c h t e r a n d t h e E R O team u s e d t h e H S T t o image a cluster of galaxies called A b e ll 2 2 1 8 , located in the constellation of Draco. T h is galaxy cluster is shown in Figure 13. This group of galaxies lies 2 billion light years from E a rth. The c luster contains spiral, lenticular, a n d e lliptical g a laxies. The spiral galaxies are raised to show the spiral arms, the lenticular galaxies are raised to s h o w e longations, and the ellip tic a l g a laxies are filled circles and elongated circles.
52
Figure 14. HUBBLE NORTHERN DEEP FIELD H o w far can our telescopes see into space? In 1995, R . Williams (NASA) and the Hubble Deep Field Te a m u s e d t h e H S T t o i m a g e a n a r e a a b o v e t h e fam o u s B ig D ipper star pattern--an area that a p p e a red devoid of stars. The astronom e r s t o o k 3 0 0 i m a g e s o f t h e s a m e a rea of the sky over a period of 10 days, hoping to see objects four billio n tim e s fainter than the lim it o f hum a n v ision. W h e n the p h o t o g r a p h s w e r e c o m b ined, astronom e rs w e re a s t o n ished to find that they had discovered t h o u s a n d s o f p r e v i o u s l y u n d e t e c t e d g a laxies, lying billio n s o f lig h t y e a r s a w a y ! S o m e o f t h e s e g a laxies are seen in the process of form a tion. The final image is called the Hubble Northern Deep Field (of G a laxies).
55
Figure 14 shows the Hubble Northern Deep Field. G a laxies in a variety of shapes are visible and have b e e n r a ised in tactile form . The field of view in this image is tiny, only about 1/30th the diam e ter of the full m o o n . This im a g e s h o w s o n ly 25% o f the entire H u b b le N o rthern D e e p F ield, just a sm a ll s a m p le of the m a n y g a laxies in the view !
56
Final Thoughts T h e i m a g e s a n d p h o t o g r a p h s i n t h is book are only a s m a ll sa m p le of the m a n y o u tstanding views taken w ith the H S T. T h e y p r o v i d e s t e p p i n g - s t o n e s o f travel, from E a rth orbit to galaxies billions of light y e a r s a w a y. T h e H u b b l e S p a c e Te l e s c o p e h a s b r o u g h t a s h a r p e r v iew of the night sky. O ther orbiting telescopes and n e w innovative ground-based technologies will continue to expand the limits of our understanding. O n l y a h u n d r e d y e a r s a g o , w e b e g a n t o e x p lore the s ize and structure of our ow n G a laxy. W h o k n o w s w h a t w o n d e r s a w a it us as w e c o n t i n u e o u r v o y a g e of discovery into the universe?
59