This thesis investigates transport of electrons through a symmetric double-barrier in a dissipative environment and its critical behavior near the resonant tunneling point. One recent experiment (H. Mebrahtu et al., Nature Physics 9, 732–737 (2013)), exhibits the existence of resonant tunneling in a dissipative system equivalent to a Luttinger liquid. In the experiment, such a system is realized by employing a carbon nanotube onto which a source lead and a drain lead are attached at two different points to form a quantum dot structure. A gate voltage is then applied on the dot to control the energy level, while two additional side gates placed near where the dot and the leads meet are used to tune the coupling from the leads to the dot. When the system is in “symmetric coupling”, conductance through the double-barrier could be tuned to resonance (G=e^2/h) by manipulating the gate voltage. It is found in the experiment that the conductances in equilibrium (eV≪k_B T) and non-equilibrium (eV≳k_B T) both have the same power law dependence of the gate voltage in the resonant tunneling region and weak tunneling region but are remarkably different in the crossover region. This is the first phenomenon in the experiment that we attempt to explain. Combining the non-equilibrium Green’s function technique and the renormalization group theory to derive the current through a double-barrier quantum dot under a finite bias voltage, we are able to find a considerably persuasive analytical solution for describing the non-equilibrium conductance. The second concern of this thesis is to study the critical behavior of the conductance near the resonance point. The experiment shows that there exists a power law dependence of the system’s temperature or bias voltage for conductance through the double-barrier at the resonance, which becomes different when conductance is off-resonance. We include the dissipation in the circuit to find the effective action describing the system. In addition, via renormalization group method, we find the power law of conductance which is consistent with the experiment result.