In recent decades, the advance of nanotechnology has led to a lot of developments such as semiconductor manufacturer, quantum device manufacturer or even in the biology and medical research at the nanoscales. Nanostructure devices also display interesting phenomena with physical quantities such as electric conductivity or thermal conductivity that cannot be well explained by macroscopic or classical models. Quantum effects are important in understanding these phenomena at nanoscales and low temperatures. My research topic focuses on a problem of one-dimensional heat transfer via a nanoscale quantum two-level system. Proposals that phonons carrying heat can be manipulated similarly to electrons and photons have been put forward, thus enabling controlled heat transport. Here we investigate the heat transfer properties of a local quantum two-level system driven by a temperature bias described by a spin-Boson model with attached two phononic reservoirs (baths) at two different temperatures. Several theoretical methods have been suggested to calculate the heat transfer, heat current and thermal conductivity of the quantum heat transport problems in the literature but they involve various and different degrees of approximations. We adopt here a so-called dissipaton equation of motion (DEOM) formalism to investigate the heat transport problems. The DEOM approach is not only suitable for solving the dynamics of the reduced system but also convenient to calculate physical quantities and multi-time correlation functions involving both system and bath operators. Furthermore, the DEOM formalism can deal with cases with system-bath coupling strength from weak to strong and bath temperature from low to high. It also can accommodate either a factorized (tensor product) or a correlated (entangled) initial system-bath state. Using the DEOM approach, we investigate the behaviors of the heat transport currents and current-current two-time correlation functions which lead to heat current noise spectrum for different bath cutoff frequencies.