Willie's link, and the indirect suggestion that graded algebras may be relevant to my question, prompts me to add some further thoughts on my own question.
It turns out that the exterior algebra is a graded algebra and, at least for electromagnetic quantities, the exterior algebra is definitely relevant.
My $41^{st}$ edition (1959-1960) of the Handbook of Chemistry and Physics, page 3177, gives the dimension of electric charge, $Q$, as either $\epsilon^{1/2}m^{1/2}l^{3/2}t^{-1}$ or $\mu^{-1/2}m^{1/2}l^{1/2}$. If we formally multiply these two dimensions together, we get:
$Q^2=(\textit{ml}^2/t)\sqrt{\epsilon/\mu}$.
Similarly, for magnetic pole strength, $\Phi$ (page 3185), we get:
$\Phi^2=(\textit{ml}^2/t)\sqrt{\mu/\epsilon}$.
It turns out that all of the electromagnetic quantities come in pairs like this, with some mass-length-time dimension, multiplied by either $G=\sqrt{\epsilon/\mu}$ or $R=\sqrt{\mu/\epsilon}$, where G and R are electrical conductance and resistance, repectively:
$
\begin{array}{2}
G=\sqrt{\epsilon/\mu} & R=\sqrt{\mu/\epsilon} \\
C=t\sqrt{\epsilon/\mu} & L=t\sqrt{\mu/\epsilon} \\
Q^2=(\textit{ml}^2/t)\sqrt{\epsilon/\mu} & \Phi^2=(\textit{ml}^2/t)\sqrt{\mu/\epsilon} \\
I^2=(\textit{ml}^2/t^3)\sqrt{\epsilon/\mu} & E^2=(\textit{ml}^2/t^3)\sqrt{\mu/\epsilon} \\
\vec{D}^2=(m/l^2t)\sqrt{\epsilon/\mu} & \vec{B}^2=(m/l^2t)\sqrt{\mu/\epsilon} \\
\vec{H}^2=(m/l^2t)\sqrt{\epsilon/\mu} & \vec{E}^2=(m/l^2t)\sqrt{\mu/\epsilon} \\
\rho_e^2=(m/t)\sqrt{\epsilon/\mu} & \rho_m^2=(m/t)\sqrt{\mu/\epsilon} \\
etc. & \\
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Here, $C$ and $L$ are capacitance and inductance, while $I$ and $E$ are current and potential, respectively.
In Discrete Differential Forms for Computational Modelling, by Mathieu Desbrun, Eva Kanso, & Yiying Tong, (Source: http://www.geometry.caltech.edu/pubs/DKT05.pdf), it says (pages 15, 12):
The constitutive relation
$\vec{D}=\epsilon \vec{E}$ and $\vec{H}=\mu \vec{B}$
are very similar to the Hodge star operator that transforms a $k$-form to an ($n-k$)-form. Here, $\epsilon$ operates on the electric field $\vec{E}$ , a 1-form, to yield the electric displacement $\vec{D}$, a 2-form, while $\mu$ transforms the magnetic field $\vec{B}$, a 2-form, into the magnetic field intensity $\vec{H}$, a 1-form. To this end, one may think of both $\epsilon$ and $\mu$ as Hodge star operators induced from appropriately chosen metrics.
We must use the inverse of the Hodge star to go from a dual ($n-k$)-cochain to a $k$-chain. We will, however use indistinguishably $\star$ to mean either the star or its inverse.
There are three different Hodge stars on $\Re^3$, one for each simplex dimension. But as we discussed for all the other operators, the dimension of the form on which this operator is applied disambiguates which star is meant. So we will not encumber our notation with unnecessary indices, and will use the symbol $\star$ for any of the three stars implied.
The author mentions that the charge density $\rho_e$ is a 3-form, but he doesn't give a clue what the appropriate Hodge operator on a 3-form might be - and I am left wondering why there isn't also a Hodge operator for 0-forms.
All that aside, however, what can we say that we have learned from this about the nature of what we call a "dimension"? My gears are grinding, but I will have to wait for my muses to give me something to continue...
@twitter-style in front of his name (not necessary now because he was notified by the present comment). – t.b. Sep 04 '11 at 14:25