Is Understanding the 4th Dimension Beyond Our Current Comprehension?

  • Context: Graduate 
  • Thread starter Thread starter Spastik_Relativity
  • Start date Start date
  • Tags Tags
    Dimensions
Click For Summary

Discussion Overview

The discussion revolves around the concept of the 4th dimension, specifically a non-time dimension, and whether it can be comprehended or defined. Participants explore theoretical implications of dimensionality, topology, and the nature of points in various dimensions, with a focus on whether a stationary point can be situated within a dimensional framework.

Discussion Character

  • Exploratory
  • Technical explanation
  • Conceptual clarification
  • Debate/contested

Main Points Raised

  • One participant questions whether a stationary point can be defined within a dimensional context, suggesting that movement is not necessary for existence in a dimension.
  • Another participant agrees that a point can exist in a dimension without movement, but raises the issue of absolute motion and its implications for reality.
  • A different viewpoint emphasizes that a single point has no dimension, and that the concept of dimension is tied to the notion of a manifold, which requires more than one point.
  • One participant elaborates on the topological nature of dimension, stating that the concept of "open balls" and proximity between points is essential for defining dimensionality, regardless of movement.
  • This participant also introduces the idea of Lebesgue covering dimension as a minimal structure needed to define dimension, contrasting it with more complex definitions like those of vector spaces and manifolds.
  • There is mention of the importance of neighborhood structure in topology, with a focus on how mappings can differ in continuity and the implications for defining dimensions.

Areas of Agreement / Disagreement

Participants express varying views on the nature of dimensionality and the role of movement, with no consensus reached on whether a stationary point can be adequately defined within a dimensional framework. The discussion remains unresolved regarding the implications of these ideas.

Contextual Notes

The discussion touches on complex concepts in topology and dimensional theory, with references to specific mathematical notions such as homeomorphisms and the Lebesgue covering dimension, which may require further clarification for those unfamiliar with advanced mathematics.

Spastik_Relativity
Messages
46
Reaction score
0
Ive been reading a couple of threads concerning the 4th(non-time) dimension. This has got me thinking wether we are closer to realising the 4th dimension than we actually think.
Say for instance a point A in the 1st dimension can move left to right in its dimension. In the 2nd dimension an identical point can move left to right, and up and down. In the 3rd an identical point can move left to right, up and down, and back and forth. But what if that particle or point wasn't to move at all. Is it possible to define what dimension it lies in?
Just a thought that confused me for a while. :rolleyes:
 
Physics news on Phys.org
lol its funny, and logically yes it is possible. If that point never moves it still exist in a spot within the system or universe or whateva. Therefore, from your reference point, whateva it may be, you can locate it whereva it exist relative to you. But this doesn't fit in with reality because everything is always in motion, but no one has ever proved that it's impossible to reach absolute zero. Also even if things are always in motion you can still locate any point relative to your own so actually i guess it does represent reality acurately
 
But what if that particle or point wasn't to move at all. Is it possible to define what dimension it lies in?

A single point has no dimension. It's trajectory (in coordinate space, phase space, etc.(?)) has dimension. The notion of dimension is immanent to the notion of manifold. I think you can't define a non-trivial manifold with only one point.

P.S.
Many dimension threads, lately. :confused:
 
Spastik_Relativity said:
Ive been reading a couple of threads concerning the 4th(non-time) dimension. This has got me thinking wether we are closer to realising the 4th dimension than we actually think.
Say for instance a point A in the 1st dimension can move left to right in its dimension. In the 2nd dimension an identical point can move left to right, and up and down. In the 3rd an identical point can move left to right, up and down, and back and forth. But what if that particle or point wasn't to move at all. Is it possible to define what dimension it lies in?
Just a thought that confused me for a while. :rolleyes:

Dimension is in essence a topological concept. This means that the concept of "open balls", the set of points "close to" a given point, determine the dimensionality of a space. It's not necessary for any points to actually move, but it is necessary to have some concept of what points are close to other points in order for the space to have a topology and hence a dimension.

The usual way to define a topology is to have a metric, a way of measuring the distance between any two points. Then one can say that points within some given (small) distance delta are "close to" or "in the neighborhood" of some point. These sets of points that are close to other points are called "open balls" or "open sets" in topology.

Given a topology, a space naturally has a "Lebesque covering dimension". (This is something I learned about from this forum, btw). This notion of dimension - the "Lebesque covering dimension" requires (IMO) the least amount of structure to define - the more usual notions of dimension, the notion of the dimension of a vector space for instance, require more axioms to define what a vector space is. (A manifold requires even more structure to define than a vector space - every manifold has a tangent vector space at any given point, and all the tangent vector spaces have the same dimension, so the dimension of a vector space defines the dimension of a manifold).

Toppology is important to the concept of dimension for the following reason. It is possible to map all the points in a line to all the points in a plane with a 1:1 mapping!

Such mappings, however, are not _continuous_ - they do not preserve the structure of the neighborhood (what points are close to other points).

Mappings which preserve the neighborhood structure are homeomorphisms. In order to tell a homeomorphism from a non-homeomorphism, one needs a concept of neighborhood. This makes the concept of neighborhood _necessary_ to define dimension - with no concept of neighborhood, we can't distinguish between a line and a plane. The existence of the Lebesque covering dimension makes the concept of neighborhood _sufficient_ to define dimension.

See
this past thread

for more - another poster here (Chronon) introduced me to the concept.
 

Similar threads

High School What Is the Fourth Dimension and How Does It Work?
  • · Replies 3 ·
Replies
3
Views
3K
High School I can't understand more than 3 spatial dimensions
  • · Replies 6 ·
Replies
6
Views
4K
Graduate The spin of an entity, an additional (4th/5th) dimension?
  • · Replies 4 ·
Replies
4
Views
1K
Graduate Understanding M Theory's 11 Dimensions
  • · Replies 5 ·
Replies
5
Views
5K
Graduate Time, String Theory & Beyond: Brett's Quest for Understanding
  • · Replies 7 ·
Replies
7
Views
3K
Graduate What is the concept of multiple orthogonal time dimensions?
  • · Replies 12 ·
Replies
12
Views
3K
Graduate Defining Superstring's Additional Dimensions
  • · Replies 70 ·
3
Replies
70
Views
11K
Graduate A completely different look at the 4th dimension
  • · Replies 3 ·
Replies
3
Views
4K
Graduate Infinite scaling limit of an elliptic charged surface
  • · Replies 5 ·
Replies
5
Views
415
Graduate M-Theory : listing the 11 dimensions
  • · Replies 36 ·
2
Replies
36
Views
114K