Starship Asterisk*

ErnieM wrote:Oooops. I mean concentric circles. From Wikipedia: "Concentric objects share the same center, axis or origin with one inside the other. Circles, tubes, cylindrical shafts, disks, and spheres may be concentric to one another. Concentric objects generally have different radii, as concentric objects with the same radius are equal."

I'm having difficulty figuring out what you're doing here (what are "concurrent circles?)

ErnieM wrote:two concurrent circles with r1 and r2 radi (r1 is 1/2 inch shorter than r2), you are standing at the shared center (c). r2 - r1 represents the space expansion from the center. draw a radius of the large circle (your line of site), mark two dots (d1 and d2) on the inner circle 1/4 inch equidistant from your line of site intersection. do the same on the outer circle (d3 and d4). mark two more dots (d5 and d6) on the outer circle 1/2 inch equidistant from you line of site. connect all the dots to the center (c). Are the angles identical? I see not.

No they aren't. The angles are identical. There's absolutely no way of telling that any expansion occurred by looking at the angular position of the dots. The only way to detect expansion is to measure the change in distance... something that we can't do in the case of the Universe, although we can infer distance and expansion velocity from the redshift.

ErnieM wrote:Ok, let us look at it your way. You are stationary at the center of your big balloon with two dots on the inside surface. Observation 1 is taken at 10 feet radius. Factoring the balloons elasticity out, as the balloon expands, observation 2 is taken at radius plus two inches (same distance as the separation between the dots). The line of site angles at observation 2 and subsequent observations is greater than that of observation 1.

ErnieM wrote:
No arguments when it comes to angular movement. Allow me to illustrate. Observation 1. Using a partially inflated balloon placed ten feet from me, I marked two dots one half inch apart. I inflated the balloon until the distance between the dots are two inches apart (a 2d representation of space expansion). Then I move the balloon one inch away, now I have a 3d illustration of space expansion. This is observation 2. The line of site angles at observation 2 and subsequent observations is greater than that of observation 1. This illustration does not involve any angular motion.

I fail to see any connection between this analogy and the Universe. We are not viewing a balloon from the outside. We are at the center of the balloon. There is nothing to suggest that different parts of the Universe are independently expanding around local centers.

There's no reason to think that gravity was any stronger in the early Universe than it is now. Of course, there have been many galactic collisions and mergers, many of which we do see.

ErnieM wrote:The young galaxies are closer to each other before space between them expanded.

Yes, but that doesn't mean gravity is stronger. It just means those galaxies feel stronger forces from gravity. Perhaps that's what you meant? There's no evidence that the Universal Gravitational Constant has changed with time.

ErnieM wrote:No arguments when it comes to angular movement. Allow me to illustrate. Observation 1. Using a partially inflated balloon placed ten feet from me, I marked two dots one half inch apart. I inflated the balloon until the distance between the dots are two inches apart (a 2d representation of space expansion). Then I move the balloon one inch away, now I have a 3d illustration of space expansion. This is observation 2. The line of site angles at observation 2 and subsequent observations is greater than that of observation 1. This illustration does not involve any angular motion.

There's no reason to think that gravity was any stronger in the early Universe than it is now. Of course, there have been many galactic collisions and mergers, many of which we do see.

The young galaxies are closer to each other before space between them expanded.

You can wait until the end of time, and you'll never see the slightest angular movement between galaxies due to the expansion of space, because there is none. Put differently, the coordinates of galaxies on the sky are absolutely fixed in terms of cosmological expansion.

There's no reason to think that gravity was any stronger in the early Universe than it is now. Of course, there have been many galactic collisions and mergers, many of which we do see.

ErnieM wrote:The universe is expanding in all directions, galaxies are moving away from us and from one another. It is also conceivable that these galaxies (both visible and dark matter components) in close proximity have collided and merged given gravity was at full force at those times. So it takes a long time. There is no need to rush. The quest for knowledge is not a race against time.

There is no "lateral" expansion as you describe. The angular position of an object on the sky does not change with time because of the expansion of the Universe (and in fact, we cannot see ordinary lateral motion between different bodies at cosmological distances because doing so would require observations over thousands or millions of years, not decades).

We measure the rate the Universe is expanding by comparing redshift and distance. Redshift is a primary measurement; distance is often problematic, and depends on multiple proxies, each with various strengths and weaknesses.

ErnieM wrote:Color shifting is a "property/characteristic" of light waves as the line of site's distance between the emitting source and the observer changes. As space expands in all directions the distance between the 1BLY galaxies grew. Even at such large distance a periodic observations (say every 10 or more years) of these blank spots can reveal the current lateral positions of the emitting sources. Given these data, we can extrapolate the "space rate of expansion".

ErnieM wrote:
I vision the galaxies when the universe was only 1BLY old to be closer to each other and now have "moved away?" from each other and in our real time have "moved out" of the Hubble's line of site due to the expansion of space.

Chris wrote:
I'm not sure what you mean by that. Where the galaxies are "now" doesn't matter. All that we can see is where they were when the photons we are now capturing were emitted.

ErnieM wrote:I vision the galaxies when the universe was only 1BLY old to be closer to each other and now have "moved away?" from each other and in our real time have "moved out" of the Hubble's line of site due to the expansion of space.

That makes sense. However, I suspect that this doesn't reflect the known position of any of the objects, but is simply a statistical distribution based on size, color, and the fact that the volume of space in this image is greater for objects seen earlier in the Universe.

BMAONE23 wrote:Here is a good visual displaying the relative distances of various objects in the Hubble Extreme Deep Field image

Chris Peterson wrote:

BMAONE23 wrote:Perhaps what is needed is another copy of the image with a rollover giving the various distances to some of the galaxies like different colored circles for varying distances, this would stop confusion with the misinterpretation of the text implying that all the galaxies in the image are 13GLY away. Anyone up for the task?

Determining the redshift means placing a spectroscopic instrument on different galaxies- something that I doubt has been done for many of those showing in this image. And tracking down the handful that have been measured and finding them in this image sounds like quite a lot of effort.

ErnieM wrote:The HEDF 2012Oct12 is a "blank" spot towards the Forrmax constellation. Where HDF-S and HDG-N? How do this three "blank" spots triangulate? What would it mean if the farthest red-shifting galaxies in these "blank" spots were relatively of the same age of 13 billion years, equidistant to and moving away from earth in opposite directions? Is this even possible? Could it be that the 14+ billion years to the BB is simply a limitation of current technological capabilities?

kimmeyh wrote:What would a version of this picture look like if everything < 12.5 billion years old was removed?

Chris Peterson wrote: I assume you are asking what the image would look like if all the galaxies that formed in the first billion years of the Universe were removed? There would be a lot fewer galaxies in the image. Probably only a few percent are that old.

ErnieM wrote:... What would it mean if the farthest red-shifting galaxies in these "blank" spots were relatively of the same age of 13 billion years, equidistant to and moving away from earth in opposite directions? ... .

ErnieM wrote:
Is this the only sweet spot Hubble is able to see galaxies as young as 13 billions years ago? Are we looking towards the direction of a long (13 billion years) elongated tapering tube of a Picard horn shaped universe? The farther we are able to see, space are more compact and dense hence the red-shifted young galaxies are much closer to each other.

This is just one relatively "blank" spot in the sky where they chose to aim the Hubble. We could choose any other "blank" spot and get much the same results, just different galaxies. The HDF-S and HDF-N are two early results of the same type of images.

kimmeyh wrote:What would a version of this picture look like if everything < 12.5 billion years old was removed?

kimmeyh wrote:What would a version of this picture look like if everything < 12.5 billion years old was removed?

starchaser wrote:

This image compares the angular size of the XDF field to the angular size of the full Moon. The XDF is a very small fraction of sky area, but it provides a "core sample" of the heavens by penetrating deep into space over a sightline of over 13 billion light-years. Several thousand galaxies are contained within this small field of view. At an angular diameter of one-half degree, the Moon spans an area of sky only one-half the width of a finger held at arm's length.

Source: http://hubblesite.org/newscenter/archiv ... 7/image/c/

Truly amazing, and gets things into perspective about the vastness of our Universe!