Here is a common ground between two different meanings, as to what may be thought of as working to help at defining what may be termed of as being "Complex Manifolds.":
Let us initially consider a Complex Manifold -- that is as such, because it is a substringular manifold, that is not initially Gaussian to what may here be termed of as being a Real Reimmanian Manifold of substringular eigenidices. This will then work to mean, that the two different respective Ward-Cauchy-related conglomerate spaces, are here to not be viable -- the one to the other. These two different compared manifolds are here of such a case, to where if these are being made Yukawa to the right given arbitrary Li-Gaussian-related Hamiltonian operator, -- that these may then later ensue to become Gaussian relative to each other in a Real Reimmanian-related manner, -- and thereby act in so as to then become of the nature of being Ward-Cauchy-related conglomerate spaces, that are here to then be viable -- the one to the other. The two different distinct said spaces may only be able to interact, in so as to be in such a condition to be able to potentially touch each other, if a Li-Operator is implemented upon the proximal region in which these are working to bear a potentially viable interdependent interaction. This first said case, -- is if one is to be working with two different spaces, -- that are not intrinsically of the same universal setting. Manifolds that are of different universal settings, may often alter, in so as to be of the same universal setting -- if these are to be enacted upon by a phenomenon that works here as a Li-Gaussian-related Hamiltonian Operator.
Next, -- let us consider a Complex Manifold -- that is as such, because it is a substringular manifold that is to be Gaussian to another manifold in a manner, that Is actually of a Real Reimmanian nature. It will then elude to a situation, in which -- that given arbitrary Yukawa coupling that is here to be implemented upon the respective proximal region, in which both of the so-eluded-to substringular manifolds are to be interacting with each other -- will not need to be of a Li-Gaussian-related Hamiltonian nature, -- it (the activity of the eluded-to Hamiltonian operator) will only need to bear a Yukawa Coupling to relate the two different inferred spaces, in a Gaussian manner that is of a Real Reimmanian nature. These two different distinct said spaces may actually bear the possibility of being able to able to interact, in so as to be in such a condition to be able to potentially touch each other -- without the need for a Li-Operator to be implemented upon the proximal region in which these are working to bear a potentially viable interdependent interaction. This latter case -- is if one is to have two different manifolds, that are either "invisible" in one manner or another, and/or are of a different Layer Of Reality -- but are here to be consistently of the same universal setting.
I will continue with the suspense later! To Be Continued! Sincerely, Samuel David Roach.
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