The High Q resonance characteristics of the CEWL Electron Model [1] [2], suggests that virtual photons and Neutrinos will form in 2 specific directions relative to a Lepton (see below). The Charged Electromagnetic Wave Loop (CEWL) model is the only known model of the Electron which explains pair production and also exactly matches all known values of the electron, including energy, de Broglie frequency, charge, mass, and generates the correct magnetic moment without resorting to superluminal velocities. The model also explains the previous mystery of why the Electron’s g-factor is 2 rather than one (½ spin) [2]. Two new insights stemming from the CEWL model are explored in this paper:One new insight is that since the model represents an electromagnetic oscillation with zero internal resistance, the capacitive and inductive reactance must match each other, and also match the reactive impedance of free space, leading to unique values for the Electron’s capacitance and inductance in free space, i.e. 3.41912126348 x 10-24 Farads and 4.85262 x 10-19 Henries. (An LC resonant loop using these two values matches the Electron’s de Broglie frequency as well as the CEWL rotational frequency). The second new insight (which might be testable) predicts the probable directionality of virtual photons and Neutrinos. This stems from the fact that the loop characteristics of the CEWL Model, in which the loop circumference exactly matches the wavelength of a (virtual) photon equal to the Electron’s energy, is analogous to the characteristics of a high Q (resonant) loop antennae in which the circumference must also exactly match the wavelength in order to achieve high Q resonance, which leads to a prediction that the virtual photons of leptons will be generated in the same directions as high Q loop antennas i.e. in the North and South magnetic directions generated by the CEWL loop (loop antennas without these high Q resonance characteristics have very different radiation/absorption patterns). This new insight about probable directionality might help guide future research into how and where Neutrinos and virtual photons form near the Electron, Muon, and Tau Leptons.