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CHAPTER 6 BLACK HOLES
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The term black hole is of very recent origin. It was coinedin 1969 by the American scientist John Wheeler as a graphicdescription of an idea that goes back at least two hundredyears, to a time when there were two theories about light: one,which Newton favored, was that it was composed of particles;the other was that it was made of waves. We now know thatreally both theories are correct. By the wave/particle duality ofquantum mechanics, light can be regarded as both a wave anda particle. Under the theory that light is made up of waves, itwas not clear how it would respond to gravity. But if light iscomposed of particles, one might expect them to be affected1 bygravity in the same way that cannonballs, rockets, and planetsare. At first people thought that particles of light traveledinfinitely fast, so gravity would not have been able to slow themdown, but the discovery by Roemer that light travels at a finitespeed meant that gravity might have an important effect.
On this assumption, a Cambridge don, John Michell, wrote apaper in 1783 in the Philosophical2 Transactions of the RoyalSociety of London in which he pointed3 out that a star that wassufficiently massive and compact would have such a stronggravitational field that light could not escape: any light emittedfrom the surface of the star would be dragged back by thestar’s gravitational attraction before it could get very far. Michellsuggested that there might be a large number of stars like this.
Although we would not be able to see them because the lightfrom them would not reach us, we would still feel theirgravitational attraction. Such objects are what we now call blackholes, because that is what they are: black voids in space. Asimilar suggestion was made a few years later by the Frenchscientist the Marquis de Laplace, apparently5 independently ofMichell. Interestingly enough, Laplace included it in only the firstand second editions of his book The System of the World, andleft it out of later editions; perhaps he decided6 that it was acrazy idea. (Also, the particle theory of light went out of favorduring the nineteenth century; it seemed that everything couldbe explained by the wave theory, and according to the wavetheory, it was not clear that light would be affected by gravityat all.)In fact, it is not really consistent to treat light likecannonballs in Newton’s theory of gravity because the speed oflight is fixed7. (A cannonball fired upward from the earth will beslowed down by gravity and will eventually stop and fall back;a photon, however, must continue upward at a constant speed.
How then can Newtonian grav-ity affect light?) A consistenttheory of how gravity affects light did not come along untilEinstein proposed general relativity in 1915. And even then itwas a long time before the implications of the theory formassive stars were understood.
To understand how a black hole might be formed, we firstneed an understanding of the life cycle of a star. A star isformed when a large amount of gas (mostly hydrogen) startsto collapse8 in on itself due to its gravitational attraction. As itcontracts, the atoms of the gas collide with each other moreand more frequently and at greater and greater speeds - thegas heats up. Eventually, the gas will be so hot that when thehydrogen atoms collide they no longer bounce off each other,but instead coalesce9 to form helium. The heat released in thisreaction, which is like a controlled hydrogen bomb explosion, iswhat makes the star shine. This additional heat also increasesthe pressure of the gas until it is sufficient to balance thegravitational attraction, and the gas stops contracting. It is a bitlike a balloon - there is a balance between the pressure of theair inside, which is trying to make the balloon expand, and thetension in the rubber, which is trying to make the balloonsmaller. Stars will remain stable like this for a long time, withheat from the nuclear reactions balancing the gravitationalattraction. Eventually, however, the star will run out of itshydrogen and other nuclear fuels. Paradoxically, the more fuel astar starts off with, the sooner it runs out. This is because themore massive the star is, the hotter it needs to be to balanceits gravitational attraction. And the hotter it is, the faster it willuse up its fuel. Our sun has probably got enough fuel foranother five thousand million years or so, but more massivestars can use up their fuel in as little as one hundred millionyears, much less than the age of the universe. When a starruns out of fuel, it starts to cool off and so to contract. Whatmight happen to it then was first understood only at the endof the 1920s.
In 1928 an Indian graduate student, SubrahmanyanChandrasekhar, set sail for England to study at Cambridge withthe British astronomer10 Sir Arthur Eddington, an expert ongeneral relativity. (According to some accounts, a journalist toldEddington in the early 1920s that he had heard there wereonly three people in the world who understood generalrelativity. Eddington paused, then replied, “I am trying to thinkwho the third person is.”) During his voyage from India,Chandrasekhar worked out how big a star could be and stillsupport itself against its own gravity after it had used up all itsfuel. The idea was this: when the star becomes small, thematter particles get very near each other, and so according tothe Pauli exclusion11 principle, they must have very differentvelocities. This makes them move away from each other andso tends to make the star expand. A star can thereforemaintain itself at a constant radius13 by a balance between theattraction of gravity and the repulsion that arises from theexclusion principle, just as earlier in its life gravity was balancedby the heat.
Chandrasekhar realized, however, that there is a limit to therepulsion that the exclusion principle can provide. The theory ofrelativity limits the maximum difference in the velocities12 of thematter particles in the star to the speed of light. This meansthat when the star got sufficiently4 dense15, the repulsion causedby the exclusion principle would be less than the attraction ofgravity. Chandrasekhar calculated that a cold star of more thanabout one and a half times the mass of the sun would not beable to support itself against its own gravity. (This mass is nowknown as the Chandrasekhar limit.) A similar discovery wasmade about the same time by the Russian scientist LevDavidovich Landau.
This had serious implications for the ultimate fate of massivestars. If a star’s mass is less than the Chandrasekhar limit, itcan eventually stop contracting and settle down to a possiblefinal state as a “white dwarf16” with a radius of a few thousandmiles and a density17 of hundreds of tons per cubic inch. Awhite dwarf is supported by the exclusion principle repulsionbetween the electrons in its matter. We observe a largenumber of these white dwarf stars. One of the first to bediscovered is a star that is orbiting around Sirius, the brighteststar in the night sky.
Landau pointed out that there was another possible finalstate for a star, also with a limiting mass of about one or twotimes the mass of the sun but much smaller even than a whitedwarf. These stars would be supported by the exclusionprinciple repulsion between neutrons19 and protons, rather thanbetween electrons. They were therefore called neutron18 stars.
They would have a radius of only ten miles or so and adensity of hundreds of millions of tons per cubic inch. At thetime they were first predicted, there was no way that neutronstars could be observed. They were not actually detected untilmuch later.
Stars with masses above the Chandrasekhar limit, on theother hand, have a big problem when they come to the end oftheir fuel. In some cases they may explode or manage tothrow off enough matter to reduce their mass below the limitand so avoid catastrophic gravitational collapse, but it wasdifficult to believe that this always happened, no matter how bigthe star. How would it know that it had to lose weight? Andeven if every star managed to lose enough mass to avoidcollapse, what would happen if you added more mass to awhite dwarf ‘or neutron star to take it over the limit? Would itcollapse to infinite density? Eddington was shocked by thatimplication, and he refused to believe Chandrasekhar’s result.
Eddington thought it was simply not possible that a star couldcollapse to a point. This was the view of most scientists:
Einstein himself wrote a paper in which he claimed that starswould not shrink to zero size. The hostility20 of other scientists,particularly Eddington, his former teacher and the leadingauthority on the structure of stars, persuaded Chandrasekhar toabandon this line of work and turn instead to other problemsin astronomy, such as the motion of star clusters. However,when he was awarded the Nobel Prize in 1983, it was, at leastin part, for his early work on the limiting mass of cold stars.
Chandrasekhar had shown that the exclusion principle couldnot halt the collapse of a star more massive than theChandrasekhar limit, but the problem of understanding whatwould happen to such a star, according to general relativity,was first solved by a young American, Robert Oppenheimer, in1939. His result, however, suggested that there would be noobservational consequences that could be detected by thetelescopes of the day. Then World War II intervened andOppenheimer himself became closely involved in the atom bombproject. After the war the problem of gravitational collapse waslargely forgotten as most scientists became caught up in whathappens on the scale of the atom and its nucleus21. In the1960s, however, interest in the large-scale problems ofastronomy and cosmology was revived by a great increase inthe number and range of astronomical22 observations broughtabout by the application of modern technology. Oppenheimer’swork was then rediscovered and extended by a number ofpeople.
The picture that we now have from Oppenheimer’s work isas follows. The gravitational field of the star changes the pathsof light rays in space-time from what they would have beenhad the star not been present. The light cones23, which indicatethe paths followed in space and time by flashes of light emittedfrom their tips, are bent24 slightly inward near the surface of thestar. This can be seen in the bending of light from distantstars observed during an eclipse of the sun. As the starcontracts, the gravitational field at its surface gets stronger andthe light cones get bent inward more. This makes it moredifficult for light from the star to escape, and the light appearsdimmer and redder to an observer at a distance. Eventually,when the star has shrunk to a certain critical radius, thegravitational field at the surface becomes so strong that thelight cones are bent inward so much that light can no longerescape (Fig. 6.1). According to the theory of relativity, nothingcan travel faster than light. Thus if light cannot escape, neithercan anything else; everything is dragged back by thegravitational field. So one has a set of events, a region ofspace-time, from which it is not possible to escape to reach adistant observer. This region is what we now call a black hole.
Its boundary is called the event horizon and it coincides withthe paths of light rays that just fail to escape from the blackhole.
In order to understand what you would see if you werewatching a star collapse to form a black hole, one has toremember that in the theory of relativity there is no absolutetime. Each observer has his own measure of time. The time forsomeone on a star will be different from that for someone at adistance, because of the gravitational field of the star. Supposean intrepid25 astronaut on the surface of the collapsing26 star,collapsing inward with it, sent a signal every second, accordingto his watch, to his spaceship orbiting about the star. At sometime on his watch, say 11:00, the star would shrink below thecritical radius at which the gravitational field becomes so strongnothing can escape, and his signals would no longer reach thespaceship. As 11:00 approached his companions watching fromthe spaceship would find the intervals27 between successive signalsfrom the astronaut getting longer and longer, but this effectwould be very small before 10:59:59. They would have to waitonly very slightly more than a second between the astronaut’s10:59:58 signal and the one that he sent when his watch read10:59:59, but they would have to wait forever for the 11:00signal. The light waves emitted from the surface of the starbetween 10:59:59 and 11:00, by the astronaut’s watch, wouldbe spread out over an infinite period of time, as seen from thespaceship. The time interval28 between the arrival of successivewaves at the spaceship would get longer and longer, so thelight from the star would appear redder and redder and fainterand fainter. Eventually, the star would be so dim that it couldno longer be seen from the spaceship: all that would be leftwould be a black hole in space. The star would, however,continue to exert the same gravitational force on the spaceship,which would continue to orbit the black hole. This scenario29 isnot entirely30 realistic, however, because of the following problem.
Gravity gets weaker the farther you are from the star, so thegravitational force on our intrepid astronaut’s feet would alwaysbe greater than the force on his head. This difference in theforces would stretch our astronaut out like spaghetti or tearhim apart before the star had contracted to the critical radiusat which the event horizon formed! However, we believe thatthere are much larger objects in the universe, like the centralregions of galaxies31, that can also undergo gravitational collapseto produce black holes; an astronaut on one of these wouldnot be torn apart before the black hole formed. He would not,in fact, feel anything special as he reached the critical radius,and could pass the point of no return without noticing itHowever, within just a few hours, as the region continued tocollapse, the difference in the gravitational forces on his headand his feet would become so strong that again it would tearhim apart.
The work that Roger Penrose and I did between 1965 and1970 showed that, according to general relativity, there must bea singularity of infinite density and space-time curvature withina black hole. This is rather like the big bang at the beginningof time, only it would be an end of time for the collapsingbody and the astronaut. At this singularity the laws of scienceand our ability to predict the future would break down.
However, any observer who remained outside the black holewould not be affected by this failure of predictability, becauseneither light nor any other signal could reach him from thesingularity. This remarkable32 fact led Roger Penrose to proposethe cosmic censorship hypothesis, which might be paraphrasedas “God abhors33 a naked singularity.” In other words, thesingularities produced by gravitational collapse occur only inplaces, like black holes, where they are decently hidden fromoutside view by an event horizon. Strictly34, this is what is knownas the weak cosmic censorship hypothesis: it protects observerswho remain outside the black hole from the consequences ofthe breakdown35 of predictability that occurs at the singularity,but it does nothing at all for the poor unfortunate astronautwho falls into the hole.
There are some solutions of the equations of generalrelativity in which it is possible for our astronaut to see anaked singularity: he may be able to avoid hitting thesingularity and instead fall through a “wormhole” and come outin another region of the universe. This would offer greatpossibilities for travel in space and time, but unfortunately itseems that these solutions may all be highly unstable36; the leastdisturbance, such as the presence of an astronaut, may changethem so that the astronaut could not see the singularity untilhe hit it and his time came to an end. In other words, thesingularity would always lie in his future and never in his past.
The strong version of the cosmic censorship hypothesis statesthat in a realistic solution, the singularities would always lieeither entirely in the future (like the singularities of gravitationalcollapse) or entirely in the past (like the , big bang). I stronglybelieve in cosmic censorship so I bet Kip Thorne and JohnPreskill of Cal Tech that it would always hold. I lost the bet ona technicality because examples were produced of solutions witha singularity that was visible from a long way away. So I hadto pay up, which according to the terms of the bet meant Ihad to clothe theirnakedness. But I can claim a moral victory. The nakedsingularities were unstable: the least disturbance37 would causethem either to disappear or to be hidden behind an eventhorizon. So they would not occur in realistic situations.
The event horizon, the boundary of the region of space-timefrom which it is not possible to escape, acts rather like aone-way membrane38 around the black hole: objects, such asunwary astronauts, can fall through the event horizon into theblack hole, but nothing can ever get out of the black holethrough the event horizon. (Remember that the event horizonis the path in space-time of light that is trying to escape fromthe black hole, and nothing can travel faster than light.) Onecould well say of the event horizon what the poet Dante saidof the entrance to Hell: “All hope abandon, ye who enterhere.” Anything or anyone who falls through the event horizonwill soon reach the region of infinite density and the end oftime.
General relativity predicts that heavy objects that are movingwill cause the emission39 of gravitational waves, ripples40 in thecurvature of space that travel at the speed of light. These aresimilar to light waves, which are ripples of the electromagneticfield, but they are much harder to detect. They can beobserved by the very slight change in separation they producebetween neighboring freely moving objects. A number ofdetectors are being built in the United States, Europe, andJapan that will measure displacements42 of one part in athousand million million million (1 with twenty-one zeros afterit), or less than the nucleus of an atom over a distance of tenmiles.
Like light, gravitational waves carry energy away from theobjects that emit them. One would therefore expect a system ofmassive objects to settle down eventually to a stationary43 state,because the energy in any movement would be carried awayby the emission of gravitational waves. (It is rather likedropping a cork44 into water: at first it bobs up and down agreat deal, but as the ripples carry away its energy, iteventually settles down to a stationary state.) For example, themovement of the earth in its orbit round the sun producesgravitational waves. The effect of the energy loss will be tochange the orbit of the earth so that gradually it gets nearerand nearer to the sun, eventually collides with it, and settlesdown to a stationary state. The rate of energy loss in the caseof the earth and the sun is very low - about enough to run asmall electric heater. This means it will take about a thousandmillion million million million years for the earth to run into thesun, so there’s no immediate45 cause for worry! The change inthe orbit of the earth is too slow to be observed, but thissame effect has been observed over the past few yearsoccurring in the system called PSR 1913 + 16 (PSR stands for“pulsar,” a special type of neutron star that emits regular pulsesof radio waves). This system contains two neutron stars orbitingeach other, and the energy they are losing by the emission ofgravitational waves is causing them to spiral in toward eachother. This confirmation46 of general relativity won J. H. Taylorand R. A. Hulse the Nobel Prize in 1993. It will take aboutthree hundred million . years for them to collide. Just beforethey do, they will be orbiting so fast that they will emit enoughgravitational waves for detectors41 like LIGO to pick up.
During the gravitational collapse of a star to form a blackhole, the movements would be much more rapid, so the rateat which energy is carried away would be much higher. Itwould therefore not be too long ‘ before it settled down to astationary state. What would this final stage look like? Onemight suppose that it would depend on all the complex featuresof the star from which it had formed - not only its mass andrate of rotation47, but also the different densities48 of various partsof the star, and the complicated movements of the gases withinthe star. And if black holes were as varied49 as the objects thatcollapsed to form them, it might be very difficult to make anypredictions about black holes in general.
In 1967, however, the study of black holes was revolutionizedby Werner Israel, a Canadian scientist (who was born in Berlin,brought up in South Africa, and took his doctoral degree inIreland). Israel showed that, according to general relativity,non-rotating black holes must be very simple; they wereperfectly spherical52, their size depended only on their mass, andany two such black holes with the same mass were identical.
They could, in fact, be described by a particular solution ofEinstein’s equations that had been known since 1917, found byKarl Schwarzschild shortly after the discovery of generalrelativity. At first many people, including Israel himself, arguedthat since black holes had to be perfectly51 spherical, a blackhole could only form from the collapse of a perfectly sphericalobject. Any real star - which would never be perfectly spherical- could therefore only collapse to form a naked singularity.
There was, however, a different interpretation53 of Israel’sresult, which was advocated by Roger Penrose and JohnWheeler in particular. They argued that the rapid movementsinvolved in a star’s collapse would mean that the gravitationalwaves it gave off would make it ever more spherical, and bythe time it had settled down to a stationary state, it would beprecisely spherical. According to this view, any non-rotating star,however complicated its shape and internal structure, would endup after gravitational collapse as a perfectly spherical black hole,whose size would depend only on its mass. Further calculationssupported this view, and it soon came to be adopted generally.
Israel’s result dealt with the case of black holes formed fromnon-rotating bodies only. In 1963, Roy Kerr, a New Zealander,found a set of solutions of the equations of general relativitythat described rotating black holes. These “Kerr” black holesrotate at a constant rate, their size and shape depending onlyon their mass and rate of rotation. If the rotation is zero, theblack hole is perfectly round and the solution is identical to theSchwarzschild solution. If the rotation is non-zero, the blackhole bulges54 outward near its equator (just as the earth or thesun bulge55 due to their rotation), and the faster it rotates, themore it bulges. So, to extend Israel’s result to include rotatingbodies, it was conjectured56 that any rotating body that collapsedto form a black hole would eventually settle down to astationary state described by the Kerr solution. In 1970 acolleague and fellow research student of mine at Cambridge,Brandon Carter, took the first step toward proving thisconjecture. He showed that, provided a stationary rotating blackhole had an axis58 of symmetry, like a spinning top, its size andshape would depend only on its mass and rate of rotation.
Then, in 1971, I proved that any stationary rotating black holewould indeed have such an axis of symmetry. Finally, in 1973,David Robinson at Kings College, London, used Carter’s andmy results to show that the conjecture57 had been correct: sucha black hole had indeed to be the Kerr solution. So aftergravitational collapse a black hole must settle down into a statein which it could be rotating, but not pulsating59. Moreover, itssize and shape would depend only on its mass and rate ofrotation, and not on the nature of the body that had collapsedto form it. This result became known by the maxim14: “A blackhole has no hair.” The “no hair” theorem is of great practicalimportance, because it so greatly restricts the possible types ofblack holes. One can therefore make detailed60 models of objectsthat might contain black holes and compare the predictions ofthe models with observations. It also means that a very largeamount of information about the body that has collapsed50 mustbe lost when a black hole is formed, because afterward61 all wecan possibly measure about the body is its mass and rate ofrotation. The significance of this will be seen in the nextchapter.
Black holes are one of only a fairly small number of cases inthe history of science in which a theory was developed in greatdetail as a mathematical model before there was any evidencefrom observations that it was correct. Indeed, this used to bethe main argument of opponents of black holes: how could onebelieve in objects for which the only evidence was calculationsbased on the dubious62 theory of general relativity? In 1963,however, Maarten Schmidt, an astronomer at the PalomarObservatory in California, measured the red shift of a faintstarlike object in the direction of the source of radio wavescalled 3C273 (that is, source number 273 in the thirdCambridge catalogue of radio sources). He found it was toolarge to be caused by a gravitational field: if it had been agravitational red shift, the object would have to be so massiveand so near to us that it would disturb the orbits of planets inthe Solar System. This suggested that the red shift was insteadcaused by the expansion of the universe, which, in turn, meantthat the object was a very long distance away. And to bevisible at such a great distance, the object must be very bright,must, in other words, be emitting a huge amount of energy.
The only mechanism63 that people could think of that wouldproduce such large quantities of energy seemed to be thegravitational collapse not just of a star but of a whole centralregion of a galaxy64. A number of other similar “quasi-stellarobjects,” or quasars, have been discovered, all with large redshifts. But they are all too far away and therefore too difficultto observe to provide conclusive65 evidence of black holes.
Further encouragement for the existence of black holes camein 1967 with the discovery by a research student at Cambridge,Jocelyn Bell-Burnell, of objects in the sky that were emittingregular pulses of radio waves. At first Bell and her supervisor,Antony Hewish, thought they might have made contact with analien civilization in the galaxy! Indeed, at the seminar at whichthey announced their discovery, I remember that they calledthe first four sources to be found LGM 1 - 4, LGM standingfor “Little Green Men.” In the end, however, they andeveryone else came to the less romantic conclusion that theseobjects, which were given the name pulsars, were in factrotating neutron stars that were emitting pulses of radio wavesbecause of a complicated interaction between their magneticfields and surrounding matter. This was bad news for writersof space westerns, but very hopeful for the small number of uswho believed in black holes at that time: it was the firstpositive evidence that neutron stars existed. A neutron star hasa radius of about ten miles, only a few times the critical radiusat which a star becomes a black hole. If a star could collapseto such a small size, it is not unreasonable66 to expect that otherstars could collapse to even smaller size and become blackholes.
How could we hope to detect a black hole, as by its verydefinition it does not emit any light? It might seem a bit likelooking for a black cat in a coal cellar. Fortunately, there is away. As John Michell pointed out in his pioneering paper in1783, a black hole still exerts a gravitational fierce on nearbyobjects. Astronomers67 have observed many systems in whichtwo stars orbit around each other, attracted toward each otherby gravity. They also observe systems in which there is onlyone visible star that is orbiting around some unseencompanion. One cannot, of course, immediately conclude thatthe companion is a black hole: it might merely be a star thatis too faint to be seen. However, some of these systems, likethe one called Cygnus X-1 (Fig. 6.2), are also strong sources ofX-rays. The best explanation for this phenomenon is thatmatter has been blown off the surface of the visible star. As itfalls toward the unseen companion, it develops a spiral motion(rather like water running out of a bath), and it gets very hot,emitting X-rays (Fig. 63). For this mechanism to work, theunseen object has to be very small, like a white dwarf, neutronstar, or black hole. From the observed orbit of the visible star,one can determine the lowest possible mass of the unseenobject. In the case of Cygnus X-l, this is about six times themass of the sun, which, according to Chandrasekhar’r result, istoo great for the unseen object to be a white dwarf. It is alsotoo large a mass to be a neutron star. It seems, therefore, thatit must be a black hole.
There are other models to explain Cygnus X-1 that do notinclude a black hole, but they are all rather far-fetched. A blackhole seems to be the only really natural explanation of theobservations. Despite this, I had a bet with Kip Thorne of theCalifornia Institute of Technology that in fact Cygnus X-1 doesnot contain a black hole! This was a form f insurance policyfor me. I have done a lot of work on black holes, and itwould all be wasted if it turned out that black holes do notexist. But in that case, I would have the consolation68 of winningmy bet, which would bring me four years of the magazinePrivate Eye. In fact, although the situation with Cygnus X-1 hasnot changed much since we made the bet in 1975, there isnow so much other observational evidence in favor of blackholes that I have conceded the bet. I paid the specified69 penalty,which was a one-year subscription70 to Penthouse, to the outrageof Kip’s liberated71 wife.
We also now have evidence for several other black holes insystems like Cygnus X-1 in our galaxy and in two neighboringgalaxies called the Magellanic Clouds. The number of blackholes, however, is almost certainly very much higher; in thelong history of the universe, many stars must have burned alltheir nuclear fuel and have had to collapse. The number ofblack holes may well be greater even than the number ofvisible stars, which totals about a hundred thousand million inour galaxy alone. The extra gravitational attraction of such alarge number of black holes could explain why our galaxyrotates at the rate it does: the mass of the visible stars isinsufficient to account for this. We also have some evidencethat there is a much larger black hole, with a mass of about ahundred thousand times that of the sun, at the center of ourgalaxy. Stars in the galaxy that come too near this black holewill be torn apart by the difference in the gravitational forceson their near and far sides. Their remains72 and gas that isthrown off other stars, will fall toward the black hole. As in thecase of Cygnus X-l, the gas will spiral inward and will heat up,though not as much as in that case. It will not get hot enoughto emit X rays, but it could account for the very compactsource of radio waves and infrared73 rays that is observed at thegalactic center.
It is thought that similar but even larger black holes, withmasses of about a hundred million times the mass of the sun,occur at the centers of quasars. For example, observations withthe Hubble telescope of the galaxy known as M87 reveal that itcontains a disk of gas 130 light-years across rotating about acentral object two thousand million times the mass of the sun.
This can only be a black hole. Matter falling into such asupermassive black hole would provide the only source ofpower great enough to explain the enormous amounts ofenergy that these objects are emitting. As the matter spiralsinto the black hole, it would make the black hole rotate in thesame direction, causing it to develop a magnetic field rather likethat of the earth. Very high-energy particles would be generatednear the black hole by the in-falling matter. The magnetic fieldwould be so strong that it could focus these particles into jetsejected outward along the axis of rotation of the black hole,that is, in the directions of its north and south poles. Such jetsare indeed observed in a number of galaxies and quasars. Onecan also consider the possibility that there might be black holeswith masses much less than that of the sun. Such black holescould not be formed by gravitational collapse, because theirmasses are below the Chandrasekhar mass limit: stars of thislow mass can support themselves against the force of gravityeven when they have exhausted74 their nuclear fuel. Low-massblack holes could form only if matter was compressed toenormous densities by very large external pressures. Suchconditions could occur in a very big hydrogen bomb: thephysicist John Wheeler once calculated that if one took all theheavy water in all the oceans of the world, one could build ahydrogen bomb that would compress matter at the center somuch that a black hole would be created. (Of course, therewould be no one left to observe it!) A more practical possibilityis that such low-mass black holes might have been formed inthe high temperatures and pressures of the very early universe.
Black holes would have been formed only if the early universehad not been perfectly smooth and uniform, because only asmall region that was denser75 than average could becompressed in this way to form a black hole. But we knowthat there must have been some irregularities, becauseotherwise the matter in the universe would still be perfectlyuniformly distributed at the present epoch76, instead of beingclumped together in stars and galaxies.
Whether the irregularities required to account for stars andgalaxies would have led to the formation of a significantnumber of “primordial77” black holes clearly depends on thedetails of the conditions in the early universe. So if we coulddetermine how many primordial black holes there are now, wewould learn a lot about the very early stages of the universe.
Primordial black holes with masses more than a thousandmillion tons (the mass of a large mountain) could be detectedonly by their gravitational influence on other, visible matter oron the expansion of the universe. However, as we shall learnin the next chapter, black holes are not really black after all:
they glow like a hot body, and the smaller they are, the morethey glow. So, paradoxically, smaller black holes might actuallyturn out to be easier to detect than large ones!

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1 affected TzUzg0     
adj.不自然的,假装的
参考例句:
  • She showed an affected interest in our subject.她假装对我们的课题感到兴趣。
  • His manners are affected.他的态度不自然。
2 philosophical rN5xh     
adj.哲学家的,哲学上的,达观的
参考例句:
  • The teacher couldn't answer the philosophical problem.老师不能解答这个哲学问题。
  • She is very philosophical about her bad luck.她对自己的不幸看得很开。
3 pointed Il8zB4     
adj.尖的,直截了当的
参考例句:
  • He gave me a very sharp pointed pencil.他给我一支削得非常尖的铅笔。
  • She wished to show Mrs.John Dashwood by this pointed invitation to her brother.她想通过对达茨伍德夫人提出直截了当的邀请向她的哥哥表示出来。
4 sufficiently 0htzMB     
adv.足够地,充分地
参考例句:
  • It turned out he had not insured the house sufficiently.原来他没有给房屋投足保险。
  • The new policy was sufficiently elastic to accommodate both views.新政策充分灵活地适用两种观点。
5 apparently tMmyQ     
adv.显然地;表面上,似乎
参考例句:
  • An apparently blind alley leads suddenly into an open space.山穷水尽,豁然开朗。
  • He was apparently much surprised at the news.他对那个消息显然感到十分惊异。
6 decided lvqzZd     
adj.决定了的,坚决的;明显的,明确的
参考例句:
  • This gave them a decided advantage over their opponents.这使他们比对手具有明显的优势。
  • There is a decided difference between British and Chinese way of greeting.英国人和中国人打招呼的方式有很明显的区别。
7 fixed JsKzzj     
adj.固定的,不变的,准备好的;(计算机)固定的
参考例句:
  • Have you two fixed on a date for the wedding yet?你们俩选定婚期了吗?
  • Once the aim is fixed,we should not change it arbitrarily.目标一旦确定,我们就不应该随意改变。
8 collapse aWvyE     
vi.累倒;昏倒;倒塌;塌陷
参考例句:
  • The country's economy is on the verge of collapse.国家的经济已到了崩溃的边缘。
  • The engineer made a complete diagnosis of the bridge's collapse.工程师对桥的倒塌做了一次彻底的调查分析。
9 coalesce oWhyj     
v.联合,结合,合并
参考例句:
  • And these rings of gas would then eventually coalesce and form the planets.这些气体环最后终于凝结形成行星。
  • They will probably collide again and again until they coalesce.他们可能会一次又一次地发生碰撞,直到他们合并。
10 astronomer DOEyh     
n.天文学家
参考例句:
  • A new star attracted the notice of the astronomer.新发现的一颗星引起了那位天文学家的注意。
  • He is reputed to have been a good astronomer.他以一个优秀的天文学者闻名于世。
11 exclusion 1hCzz     
n.拒绝,排除,排斥,远足,远途旅行
参考例句:
  • Don't revise a few topics to the exclusion of all others.不要修改少数论题以致排除所有其他的。
  • He plays golf to the exclusion of all other sports.他专打高尔夫球,其他运动一概不参加。
12 velocities 64d80206fdcbbf917808c5b00e0a8ff5     
n.速度( velocity的名词复数 );高速,快速
参考例句:
  • In experimenting we find out that sound travels with different velocities through different substances. 在实验中,我们发现声音以不同的速度通过不同的物质而传播。 来自《现代汉英综合大词典》
  • A gas in thermal equilibrium has particles of all velocities. 处于热平衡的气体,其粒子有一切速度。 来自辞典例句
13 radius LTKxp     
n.半径,半径范围;有效航程,范围,界限
参考例句:
  • He has visited every shop within a radius of two miles.周围两英里以内的店铺他都去过。
  • We are measuring the radius of the circle.我们正在测量圆的半径。
14 maxim G2KyJ     
n.格言,箴言
参考例句:
  • Please lay the maxim to your heart.请把此格言记在心里。
  • "Waste not,want not" is her favourite maxim.“不浪费则不匮乏”是她喜爱的格言。
15 dense aONzX     
a.密集的,稠密的,浓密的;密度大的
参考例句:
  • The general ambushed his troops in the dense woods. 将军把部队埋伏在浓密的树林里。
  • The path was completely covered by the dense foliage. 小路被树叶厚厚地盖了一层。
16 dwarf EkjzH     
n.矮子,侏儒,矮小的动植物;vt.使…矮小
参考例句:
  • The dwarf's long arms were not proportional to his height.那侏儒的长臂与他的身高不成比例。
  • The dwarf shrugged his shoulders and shook his head. 矮子耸耸肩膀,摇摇头。
17 density rOdzZ     
n.密集,密度,浓度
参考例句:
  • The population density of that country is 685 per square mile.那个国家的人口密度为每平方英里685人。
  • The region has a very high population density.该地区的人口密度很高。
18 neutron neutron     
n.中子
参考例句:
  • Neutron is neutral and slightly heavier than the proton.中子是中性的,比质子略重。
  • Based on the neutron energy,the value of weighting factor was given.根据中子能量给出了相应的辐射权重因子的数值。
19 neutrons 8247a394cf7f4566ae93232e91c291b9     
n.中子( neutron的名词复数 )
参考例句:
  • The neutrons and protons form the core of the atom. 中子和质子构成了原子核。 来自《简明英汉词典》
  • When an atom of U235 is split,several neutrons are set free. 一个铀235原子分裂时,释放出几个中子。 来自《简明英汉词典》
20 hostility hdyzQ     
n.敌对,敌意;抵制[pl.]交战,战争
参考例句:
  • There is open hostility between the two leaders.两位领导人表现出公开的敌意。
  • His hostility to your plan is well known.他对你的计划所持的敌意是众所周知的。
21 nucleus avSyg     
n.核,核心,原子核
参考例句:
  • These young people formed the nucleus of the club.这些年轻人成了俱乐部的核心。
  • These councils would form the nucleus of a future regime.这些委员会将成为一个未来政权的核心。
22 astronomical keTyO     
adj.天文学的,(数字)极大的
参考例句:
  • He was an expert on ancient Chinese astronomical literature.他是研究中国古代天文学文献的专家。
  • Houses in the village are selling for astronomical prices.乡村的房价正在飙升。
23 cones 1928ec03844308f65ae62221b11e81e3     
n.(人眼)圆锥细胞;圆锥体( cone的名词复数 );球果;圆锥形东西;(盛冰淇淋的)锥形蛋卷筒
参考例句:
  • In the pines squirrels commonly chew off and drop entire cones. 松树上的松鼠通常咬掉和弄落整个球果。 来自辞典例句
  • Many children would rather eat ice cream from cones than from dishes. 许多小孩喜欢吃蛋卷冰淇淋胜过盘装冰淇淋。 来自辞典例句
24 bent QQ8yD     
n.爱好,癖好;adj.弯的;决心的,一心的
参考例句:
  • He was fully bent upon the project.他一心扑在这项计划上。
  • We bent over backward to help them.我们尽了最大努力帮助他们。
25 intrepid NaYzz     
adj.无畏的,刚毅的
参考例句:
  • He is not really satisfied with his intrepid action.他没有真正满意他的无畏行动。
  • John's intrepid personality made him a good choice for team leader.约翰勇敢的个性适合作领导工作。
26 collapsing 6becc10b3eacfd79485e188c6ac90cb2     
压扁[平],毁坏,断裂
参考例句:
  • Rescuers used props to stop the roof of the tunnel collapsing. 救援人员用支柱防止隧道顶塌陷。
  • The rocks were folded by collapsing into the center of the trough. 岩石由于坍陷进入凹槽的中心而发生褶皱。
27 intervals f46c9d8b430e8c86dea610ec56b7cbef     
n.[军事]间隔( interval的名词复数 );间隔时间;[数学]区间;(戏剧、电影或音乐会的)幕间休息
参考例句:
  • The forecast said there would be sunny intervals and showers. 预报间晴,有阵雨。
  • Meetings take place at fortnightly intervals. 每两周开一次会。
28 interval 85kxY     
n.间隔,间距;幕间休息,中场休息
参考例句:
  • The interval between the two trees measures 40 feet.这两棵树的间隔是40英尺。
  • There was a long interval before he anwsered the telephone.隔了好久他才回了电话。
29 scenario lZoxm     
n.剧本,脚本;概要
参考例句:
  • But the birth scenario is not completely accurate.然而分娩脚本并非完全准确的。
  • This is a totally different scenario.这是完全不同的剧本。
30 entirely entirely     
ad.全部地,完整地;完全地,彻底地
参考例句:
  • The fire was entirely caused by their neglect of duty. 那场火灾完全是由于他们失职而引起的。
  • His life was entirely given up to the educational work. 他的一生统统献给了教育工作。
31 galaxies fa8833b92b82bcb88ee3b3d7644caf77     
星系( galaxy的名词复数 ); 银河系; 一群(杰出或著名的人物)
参考例句:
  • Quasars are the highly energetic cores of distant galaxies. 类星体是遥远星系的极为活跃的核心体。
  • We still don't know how many galaxies there are in the universe. 我们还不知道宇宙中有多少个星系。
32 remarkable 8Vbx6     
adj.显著的,异常的,非凡的,值得注意的
参考例句:
  • She has made remarkable headway in her writing skills.她在写作技巧方面有了长足进步。
  • These cars are remarkable for the quietness of their engines.这些汽车因发动机没有噪音而不同凡响。
33 abhors e8f81956d0ea03fa87889534fe584845     
v.憎恶( abhor的第三人称单数 );(厌恶地)回避;拒绝;淘汰
参考例句:
  • For the same reason, our party abhors the deification of an individual. 因为这样,我们党也厌弃对于个人的神化。 来自《简明英汉词典》
  • She abhors cruelty to animals. 她憎恶虐待动物。 来自《现代英汉综合大词典》
34 strictly GtNwe     
adv.严厉地,严格地;严密地
参考例句:
  • His doctor is dieting him strictly.他的医生严格规定他的饮食。
  • The guests were seated strictly in order of precedence.客人严格按照地位高低就座。
35 breakdown cS0yx     
n.垮,衰竭;损坏,故障,倒塌
参考例句:
  • She suffered a nervous breakdown.她患神经衰弱。
  • The plane had a breakdown in the air,but it was fortunately removed by the ace pilot.飞机在空中发生了故障,但幸运的是被王牌驾驶员排除了。
36 unstable Ijgwa     
adj.不稳定的,易变的
参考例句:
  • This bookcase is too unstable to hold so many books.这书橱很不结实,装不了这么多书。
  • The patient's condition was unstable.那患者的病情不稳定。
37 disturbance BsNxk     
n.动乱,骚动;打扰,干扰;(身心)失调
参考例句:
  • He is suffering an emotional disturbance.他的情绪受到了困扰。
  • You can work in here without any disturbance.在这儿你可不受任何干扰地工作。
38 membrane H7ez8     
n.薄膜,膜皮,羊皮纸
参考例句:
  • A vibrating membrane in the ear helps to convey sounds to the brain.耳膜的振动帮助声音传送到大脑。
  • A plastic membrane serves as selective diffusion barrier.一层塑料薄膜起着选择性渗透屏障的作用。
39 emission vjnz4     
n.发出物,散发物;发出,散发
参考例句:
  • Rigorous measures will be taken to reduce the total pollutant emission.采取严格有力措施,降低污染物排放总量。
  • Finally,the way to effectively control particulate emission is pointed out.最后,指出有效降低颗粒排放的方向。
40 ripples 10e54c54305aebf3deca20a1472f4b96     
逐渐扩散的感觉( ripple的名词复数 )
参考例句:
  • The moon danced on the ripples. 月亮在涟漪上舞动。
  • The sea leaves ripples on the sand. 海水在沙滩上留下了波痕。
41 detectors bff80b364ed19e1821aa038fae38df83     
探测器( detector的名词复数 )
参考例句:
  • The report advocated that all buildings be fitted with smoke detectors. 报告主张所有的建筑物都应安装烟火探测器。
  • This is heady wine for experimenters using these neutrino detectors. 对于使用中微子探测器的实验工作者,这是令人兴奋的美酒。 来自英汉非文学 - 科技
42 displacements 9e66611008a27467702e6346e1664419     
n.取代( displacement的名词复数 );替代;移位;免职
参考例句:
  • The laws of physics are symmetrical for translational displacements. 物理定律对平移是对称的。 来自辞典例句
  • We encounter only displacements of the first type. 我们只遇到第一类的驱替。 来自辞典例句
43 stationary CuAwc     
adj.固定的,静止不动的
参考例句:
  • A stationary object is easy to be aimed at.一个静止不动的物体是容易瞄准的。
  • Wait until the bus is stationary before you get off.你要等公共汽车停稳了再下车。
44 cork VoPzp     
n.软木,软木塞
参考例句:
  • We heard the pop of a cork.我们听见瓶塞砰的一声打开。
  • Cork is a very buoyant material.软木是极易浮起的材料。
45 immediate aapxh     
adj.立即的;直接的,最接近的;紧靠的
参考例句:
  • His immediate neighbours felt it their duty to call.他的近邻认为他们有责任去拜访。
  • We declared ourselves for the immediate convocation of the meeting.我们主张立即召开这个会议。
46 confirmation ZYMya     
n.证实,确认,批准
参考例句:
  • We are waiting for confirmation of the news.我们正在等待证实那个消息。
  • We need confirmation in writing before we can send your order out.给你们发送订购的货物之前,我们需要书面确认。
47 rotation LXmxE     
n.旋转;循环,轮流
参考例句:
  • Crop rotation helps prevent soil erosion.农作物轮作有助于防止水土流失。
  • The workers in this workshop do day and night shifts in weekly rotation.这个车间的工人上白班和上夜班每周轮换一次。
48 densities eca5c1ea104bef3058e858fe084fb6d0     
密集( density的名词复数 ); 稠密; 密度(固体、液体或气体单位体积的质量); 密度(磁盘存贮数据的可用空间)
参考例句:
  • The range of densities of interest is about 3.5. 有用的密度范围为3.5左右。
  • Densities presumably can be probed by radar. 利用雷达也许还能探测出气体的密度。
49 varied giIw9     
adj.多样的,多变化的
参考例句:
  • The forms of art are many and varied.艺术的形式是多种多样的。
  • The hotel has a varied programme of nightly entertainment.宾馆有各种晚间娱乐活动。
50 collapsed cwWzSG     
adj.倒塌的
参考例句:
  • Jack collapsed in agony on the floor. 杰克十分痛苦地瘫倒在地板上。
  • The roof collapsed under the weight of snow. 房顶在雪的重压下突然坍塌下来。
51 perfectly 8Mzxb     
adv.完美地,无可非议地,彻底地
参考例句:
  • The witnesses were each perfectly certain of what they said.证人们个个对自己所说的话十分肯定。
  • Everything that we're doing is all perfectly above board.我们做的每件事情都是光明正大的。
52 spherical 7FqzQ     
adj.球形的;球面的
参考例句:
  • The Earth is a nearly spherical planet.地球是一个近似球体的行星。
  • Many engineers shy away from spherical projection methods.许多工程师对球面投影法有畏难情绪。
53 interpretation P5jxQ     
n.解释,说明,描述;艺术处理
参考例句:
  • His statement admits of one interpretation only.他的话只有一种解释。
  • Analysis and interpretation is a very personal thing.分析与说明是个很主观的事情。
54 bulges 248c4c08516697064a5c8a7608001606     
膨胀( bulge的名词复数 ); 鼓起; (身体的)肥胖部位; 暂时的激增
参考例句:
  • His pocket bulges with apples. 他的衣袋装着苹果鼓了起来。
  • He bulges out of his black T-shirt. 他的肚子在黑色T恤衫下鼓鼓地挺着。
55 bulge Ns3ze     
n.突出,膨胀,激增;vt.突出,膨胀
参考例句:
  • The apple made a bulge in his pocket.苹果把他口袋塞得鼓了起来。
  • What's that awkward bulge in your pocket?你口袋里那块鼓鼓囊囊的东西是什么?
56 conjectured c62e90c2992df1143af0d33094f0d580     
推测,猜测,猜想( conjecture的过去式和过去分词 )
参考例句:
  • The old peasant conjectured that it would be an unusually cold winter. 那老汉推测冬天将会异常地寒冷。
  • The general conjectured that the enemy only had about five days' supply of food left. 将军推测敌人只剩下五天的粮食给养。
57 conjecture 3p8z4     
n./v.推测,猜测
参考例句:
  • She felt it no use to conjecture his motives.她觉得猜想他的动机是没有用的。
  • This conjecture is not supported by any real evidence.这种推测未被任何确切的证据所证实。
58 axis sdXyz     
n.轴,轴线,中心线;坐标轴,基准线
参考例句:
  • The earth's axis is the line between the North and South Poles.地轴是南北极之间的线。
  • The axis of a circle is its diameter.圆的轴线是其直径。
59 pulsating d9276d5eaa70da7d97b300b971f0d74b     
adj.搏动的,脉冲的v.有节奏地舒张及收缩( pulsate的现在分词 );跳动;脉动;受(激情)震动
参考例句:
  • Lights were pulsating in the sky. 天空有闪烁的光。
  • Spindles and fingers moved so quickly that the workshop seemed to be one great nervously-pulsating machine. 工作很紧张,全车间是一个飞快的转轮。 来自子夜部分
60 detailed xuNzms     
adj.详细的,详尽的,极注意细节的,完全的
参考例句:
  • He had made a detailed study of the terrain.他对地形作了缜密的研究。
  • A detailed list of our publications is available on request.我们的出版物有一份详细的目录备索。
61 afterward fK6y3     
adv.后来;以后
参考例句:
  • Let's go to the theatre first and eat afterward. 让我们先去看戏,然后吃饭。
  • Afterward,the boy became a very famous artist.后来,这男孩成为一个很有名的艺术家。
62 dubious Akqz1     
adj.怀疑的,无把握的;有问题的,靠不住的
参考例句:
  • What he said yesterday was dubious.他昨天说的话很含糊。
  • He uses some dubious shifts to get money.他用一些可疑的手段去赚钱。
63 mechanism zCWxr     
n.机械装置;机构,结构
参考例句:
  • The bones and muscles are parts of the mechanism of the body.骨骼和肌肉是人体的组成部件。
  • The mechanism of the machine is very complicated.这台机器的结构是非常复杂的。
64 galaxy OhoxB     
n.星系;银河系;一群(杰出或著名的人物)
参考例句:
  • The earth is one of the planets in the Galaxy.地球是银河系中的星球之一。
  • The company has a galaxy of talent.该公司拥有一批优秀的人才。
65 conclusive TYjyw     
adj.最后的,结论的;确凿的,消除怀疑的
参考例句:
  • They produced some fairly conclusive evidence.他们提供了一些相当确凿的证据。
  • Franklin did not believe that the French tests were conclusive.富兰克林不相信这个法国人的实验是结论性的。
66 unreasonable tjLwm     
adj.不讲道理的,不合情理的,过度的
参考例句:
  • I know that they made the most unreasonable demands on you.我知道他们对你提出了最不合理的要求。
  • They spend an unreasonable amount of money on clothes.他们花在衣服上的钱太多了。
67 astronomers 569155f16962e086bd7de77deceefcbd     
n.天文学者,天文学家( astronomer的名词复数 )
参考例句:
  • Astronomers can accurately foretell the date,time,and length of future eclipses. 天文学家能精确地预告未来日食月食的日期、时刻和时长。 来自《简明英汉词典》
  • Astronomers used to ask why only Saturn has rings. 天文学家们过去一直感到奇怪,为什么只有土星有光环。 来自《简明英汉词典》
68 consolation WpbzC     
n.安慰,慰问
参考例句:
  • The children were a great consolation to me at that time.那时孩子们成了我的莫大安慰。
  • This news was of little consolation to us.这个消息对我们来说没有什么安慰。
69 specified ZhezwZ     
adj.特定的
参考例句:
  • The architect specified oak for the wood trim. 那位建筑师指定用橡木做木饰条。
  • It is generated by some specified means. 这是由某些未加说明的方法产生的。
70 subscription qH8zt     
n.预订,预订费,亲笔签名,调配法,下标(处方)
参考例句:
  • We paid a subscription of 5 pounds yearly.我们按年度缴纳5英镑的订阅费。
  • Subscription selling bloomed splendidly.订阅销售量激增。
71 liberated YpRzMi     
a.无拘束的,放纵的
参考例句:
  • The city was liberated by the advancing army. 军队向前挺进,解放了那座城市。
  • The heat brings about a chemical reaction, and oxygen is liberated. 热量引起化学反应,释放出氧气。
72 remains 1kMzTy     
n.剩余物,残留物;遗体,遗迹
参考例句:
  • He ate the remains of food hungrily.他狼吞虎咽地吃剩余的食物。
  • The remains of the meal were fed to the dog.残羹剩饭喂狗了。
73 infrared dx0yp     
adj./n.红外线(的)
参考例句:
  • Infrared is widely used in industry and medical science.红外线广泛应用于工业和医学科学。
  • Infrared radiation has wavelengths longer than those of visible light.红外辐射的波长比可见光的波长长。
74 exhausted 7taz4r     
adj.极其疲惫的,精疲力尽的
参考例句:
  • It was a long haul home and we arrived exhausted.搬运回家的这段路程特别长,到家时我们已筋疲力尽。
  • Jenny was exhausted by the hustle of city life.珍妮被城市生活的忙乱弄得筋疲力尽。
75 denser denser     
adj. 不易看透的, 密集的, 浓厚的, 愚钝的
参考例句:
  • The denser population necessitates closer consolidation both for internal and external action. 住得日益稠密的居民,对内和对外都不得不更紧密地团结起来。 来自英汉非文学 - 家庭、私有制和国家的起源
  • As Tito entered the neighbourhood of San Martino, he found the throng rather denser. 蒂托走近圣马丁教堂附近一带时,发现人群相当密集。
76 epoch riTzw     
n.(新)时代;历元
参考例句:
  • The epoch of revolution creates great figures.革命时代造就伟大的人物。
  • We're at the end of the historical epoch,and at the dawn of another.我们正处在一个历史时代的末期,另一个历史时代的开端。
77 primordial 11PzK     
adj.原始的;最初的
参考例句:
  • It is the primordial force that propels us forward.它是推动我们前进的原始动力。
  • The Neanderthal Man is one of our primordial ancestors.的尼安德特人是我们的原始祖先之一.


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