Kannan, B., Ruckriegel, M.J., Campbell, D.L., Kockum, A.F., et al.: Waveguide quantum electrodynamics with superconducting artificial giant atoms. Wang, X., Shui, T., Li, L., Li, X., Wu, Z., Yang, W.X.: Tunable single-photon diode and circulator via chiral waveguide-emitter couplings. Masson, S.J., Asenjo-Garcia, A.: Atomic-waveguide quantum electrodynamics. A 98(4), 043852 (2018)ĭong, J.H., Jiang, Q., Hu, Q.M., Zou, B.S., Zhang, Y.Y.: Transport and entanglement for single photons in optical waveguide ladders. Yan, W.B., Ni, W.Y., Zhang, J., Zhang, F.Y., Fan, H.: Tunable single-photon diode by chiral quantum physics. Jiang, Q., Hu, Q., Zou, B., Zhang, Y.: Single microwave photon switch controlled by an external electrostatic field. Gu, X., Kockum, A.F., Miranowicz, A., Liu, Y., Nori, F.: Microwave photonics with superconducting quantum circuits. Huang, J.F., Shi, T., Sun, C.P., Nori, F.: Controlling single-photon transport in waveguides with finite cross section. 12, 043052 (2010)Ĭhen, W., Chen, G.Y., Chen, Y.N.: Coherent transport of nanowire surface plasmons coupled to quantum dots. Witthaut, D., Sørensen, A.S.: Photon scattering by a three-level emitter in a one-dimensional waveguide.
Tsoi, T.S., Law, C.K.: Single-photon scattering on \(\Lambda \)-type three-level atoms in a one-dimensional waveguide. Coupling to a whispering-gallery resonator containing a two-level atom. Shen, J.T., Fan, S.: Theory of single-photon transport in a single-mode waveguide. Coupling to a cavity containing a two-level atom. 95(21), 213001 (2005)Ĭhang, D.E., Sørensen, A.S., Demler, E.A., Lukin, M.D.: A single-photon transistor using nano-scale surface plasmons. Shen, J.T., Fan, S.: Coherent single photon transport in a one-dimensional waveguide coupled with superconducting quantum bits. Shen, J.T., Fan, S.: Coherent photon transport from spontaneous emission in one-dimensional waveguides. Zhou, L., Gong, Z.R., Liu, Y.X., Sun, C.P., Nori, F.: Controllable scattering of a single photon inside a one-dimensional resonator waveguide. If the transistor is on, the Collector voltage is 1.6 volts higher than the Emitter voltage.Goban, A., Hung, C.L., Yu, S.P., Hood, J.D., Muniz, J.A., Lee, J.H., Martin, M.J., McClung, A.C., Choi, K.S., Chang, D.E., Painter, O., Kimble, H.J.: Atom-light interactions in photonic crystals.
#TRANSISTOR EMITTER PLUS#
I measured 19.20 mA at point E, so that would be roughly the collector/emitter current plus the base/emitter current.ĭoes all that sound right? And does that make this quote incorrect? I measured 60 mV at point D, so it would appear that the collector/emitter voltage drop was closer to 0.1V than 1.6V.
I measured 12.06 V at the +12 V point, and 10.28 at point C, giving a voltage drop of 1.78 V in circuit. Measured was 18.57 mA, so that is pretty close. Measured was 0.857 mA, so that is reasonably close. Meanwhile, on this page (Transistors 101):Ģ.) If the transistor is on, the Collector voltage is 1.6 volts higher than the Emitter voltage. In fact he measured around a 0.1V drop between collector and emitter due to manufacturing issues.
In that he said that whilst there was a 0.7V drop between base and emitter, because of the PN junction, there was "almost no" drop between collector and emitter because the PNP junction "cancelled it out".
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