29.2 A model of the universe (Page 5/10)

Astronomy Page 5 / 10

In an empty universe (the dashed line [link] and the coasting universe in [link] ), neither gravity nor dark energy is important enough to affect the expansion rate, which is therefore constant throughout all time.

In a universe with dark energy, the rate of the expansion will increase with time, and the expansion will continue at an ever-faster rate. Curve 4 in [link] , which represents this universe, has a complicated shape. In the beginning, when the matter is all very close together, the rate of expansion is most influenced by gravity. Dark energy appears to act only over large scales and thus becomes more important as the universe grows larger and the matter begins to thin out. In this model, at first the universe slows down, but as space stretches, the acceleration plays a greater role and the expansion speeds up.

The cosmic tug of war

We might summarize our discussion so far by saying that a “tug of war” is going on in the universe between the forces that push everything apart and the gravitational attraction of matter, which pulls everything together. If we can determine who will win this tug of war, we will learn the ultimate fate of the universe.

The first thing we need to know is the density of the universe. Is it greater than, less than, or equal to the critical density? The critical density today depends on the value of the expansion rate today, H ₀ . If the Hubble constant is around 20 kilometers/second per million light-years, the critical density is about 10 ^–26 kg/m ³ . Let’s see how this value compares with the actual density of the universe.

Critical density of the universe

As we discussed, the critical density is that combination of matter and energy that brings the universe coasting to a stop at time infinity. Einstein’s equations lead to the following expression for the critical density ( ρ _crit ):

ρ_{crit} = \frac{3 H^{2}}{8 π G}

where H is the Hubble constant and G is the universal constant of gravity (6.67 × 10 ^–11 Nm ² /kg ² ).

Solution

Let’s substitute our values and see what we get. Take an H = 22 km/s per million light-years. We need to convert both km and light-years into meters for consistency. A million light-years = 10 ⁶ × 9.5 × 10 ¹⁵ m = 9.5 × 10 ²¹ m. And 22 km/s = 2.2 × 10 ⁴ m/s. That makes H = 2.3 ×10 ^–18 /s and H ² = 5.36 × 10 ^–36 /s ² . So,

ρ_{crit} = \frac{3 \times 5.36 \times 10^{–36}}{8 \times 3.14 \times 6.67 \times 10^{–11}} = 9.6 \times 10^{–27} {kg/m}^{3}

which we can round off to the 10 ^–26 kg/m ³ . (To make the units work out, you have to know that N , the unit of force, is the same as kg × m/s ² .)

Now we can compare densities we measure in the universe to this critical value. Note that density is mass per unit volume, but energy has an equivalent mass of m = E / c ² (from Einstein’s equation E = mc ² ).

Check your learning

A single grain of dust has a mass of about 1.1 × 10 ^–13 kg. If the average mass-energy density of space is equal to the critical density on average, how much space would be required to produce a total mass-energy equal to a dust grain?
If the Hubble constant were twice what it actually is, how much would the critical density be?

Answer:

a. In this case, the average mass-energy in a volume V of space is E = ρ _crit V . Thus, for space with critical density, we require that

V = \frac{E_{grain}}{ρ_{crit}} = \frac{1.1 \times 10^{–13} kg}{9.6 \times 10^{–26} {kg/m}^{3}} = 1.15 \times 10^{12} m^{3} = {(10,500 m)}^{3} ≅ {(10.5 km)}^{3}

Thus, the sides of a cube of space with mass-energy density averaging that of the critical density would need to be slightly greater than 10 km to contain the total energy equal to a single grain of dust!

b. Since the critical density goes as the square of the Hubble constant, by doubling the Hubble parameter, the critical density would increase by a factor a four. So if the Hubble constant was 44 km/s per million light-years instead of 22 km/s per million light-years, the critical density would be $ρ_{crit} = 4 \times 9.6 \times 10^{–27} {kg/m}^{3} = 3.8 \times 10^{–26} {kg/m}^{3} .$

Questions & Answers

Biology is a branch of Natural science which deals/About living Organism.

Ahmedin Reply

what is phylogeny

Odigie Reply

evolutionary history and relationship of an organism or group of organisms

AI-Robot

Deng

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Hajah Reply

cell is the smallest unit of the humanity biologically

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Victoria Reply

what is biology

Abraham

HOW CAN MAN ORGAN FUNCTION

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the diagram of the digestive system

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allimentary cannel

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How does twins formed

William Reply

They formed in two ways first when one sperm and one egg are splited by mitosis or two sperm and two eggs join together

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what is genetics

Josephine Reply

Genetics is the study of heredity

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What is manual

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discuss biological phenomenon and provide pieces of evidence to show that it was responsible for the formation of eukaryotic organelles

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the study of living organisms and their interactions with one another and their environment.

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discuss the biological phenomenon and provide pieces of evidence to show that it was responsible for the formation of eukaryotic organelles in an essay form

Joseph Reply

what is the blood cells

Shaker Reply

list any five characteristics of the blood cells

Shaker

lack electricity and its more savely than electronic microscope because its naturally by using of light

Abdullahi Reply

advantage of electronic microscope is easily and clearly while disadvantage is dangerous because its electronic. advantage of light microscope is savely and naturally by sun while disadvantage is not easily,means its not sharp and not clear

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cell theory state that every organisms composed of one or more cell,cell is the basic unit of life

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is like gone fail us

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cells is the basic structure and functions of all living things

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What is classification

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is organisms that are similar into groups called tara

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Source: OpenStax, Astronomy. OpenStax CNX. Apr 12, 2017 Download for free at http://cnx.org/content/col11992/1.13

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