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\begin{document}
Formlas, missing J, L, M, N 


\noindent{A. \it Einstein mass/energy:} 

$${\bf E_0 = mc^2}$$
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\noindent{B. \it Maxwell's Equations in Vacuum:a}
$$ \begin{array}{l}
{\bf \nabla \cdot  B}  = 0 \\
\nabla \times {\bf B}  = \frac{\ds 1}{\ds c}\frac {\ds \partial {\bf E}}
{\ds \partial t}\\
\end{array}~~~~~
\begin{array}{l}
\nabla \cdot {\bf E}  = 0 \\
\nabla \times {\bf E}  = -\frac{\ds 1}{\ds c}\frac{\ds \partial {\bf B}}
{\ds \partial t}\\
\end{array}$$
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\noindent{C. \it Stokes' Theorem}
$$\int_{M}d\omega=\int_{\partial M}\omega$$
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\noindent{D. \it }
$$\{Q,Q\} = P$$
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\noindent{E. \it Primes and the zeta function:} 
$$ \prod_p \frac{1}{1-\frac{1}{p^s}} = 
\sum_{n=1}^{\infty}\frac{1}{n^s}$$
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\noindent{F. \it Heisenberg Uncertainty Principle:}
$$\Delta x \Delta p \geq  \hbar/2$$
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\noindent{G. \it Kepler's Second Law} 

$$\frac{d\theta}{dt} \propto \frac{1}{r}$$
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\noindent{H. \it Kepler's Third Law} 

$$ T \propto a^{\frac{2}{3}}$$
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\noindent{I. \it Newton's Law of Gravitation:}
$$ F = \frac{\ds G m_1m_2}{\ds r^2}$$
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\noindent{K. \it Einstein's General Relativity Equation: }
$$R_{\mu\nu}-\frac{1}{2}R g_{\mu\nu}  = 8 \pi T_{\mu\nu}$$
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\noindent{O. \it Yang-Mills equations:}
$$F = dA + A \wedge A$$

$$D_A^*F_A = 0$$
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Non-curved medallion formulas:

\noindent{IV \it Equations for Lorenz attractor:} 
$$\frac{\ds dx}{\ds dt} = \sigma(y-x)$$
$$\frac{\ds dy}{\ds dt} = x(\rho-z) -y$$
$$\frac{\ds dz}{\ds dt} = xy - \beta z$$
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\noindent{XII. \it Golden mean  
= partial fraction expansion:}
$$\lim_{n\rightarrow\infty}\frac{F_{n+1}}{F_n} = {1}+ \frac{\ds 1}{1+\dots} $$
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