This study aims to investigate the thermal conductivity of a single nylon-6 nanofiber. It has been shown that an ultra-drawn polyethylene nanofiber has a thermal conductivity much larger than its bulk value. However, the physical mechanisms which result in the thermal conductivity enhancement in the polymer nanofiber are not fully understood. In this study, the thermal conductivity of a single nylon-6 nanofiber was investigated. Nylon-6 has a simple molecular structure as that in polyethylene. Thus, it is expected that it might exhibit similar thermal conductivity enhancement during nano-structuring. A micro-device array was made to measure the thermal conductivity of the a nylon-6 nanofiber and an ultra-high-vacuum cryostat with a temperature ranged from 30 K to 200 K was adopted to study the heat transfer at low-to-moderate temperature conditions. Thermal conductivity of the nanofiber not only depends on temperature but also depends on time (called thermal rheology). The secondary phase transition in the amorphous nylon-6 nanofiber is presumably responsible for the observed phenomena. At low temperature, the thermal conductivity of the nylon-6 nanofiber increases with temperature due to its elastic characteristic, whereas the viscous characteristic of the nanofiber causes the large thermal conductivity reduction at approximately 150 K. Moreover, at low temperature, thermal conductivity of the nanofiber increases with annealing time because of the physical-aging of the polymer. A maximum thermal conductivity of approximately 42W/m-K was obtained at 150 K, which is 140 times that of bulk nylon. This is the first work demonstrating that the amorphous polymer can have a large thermal conductivity comparable to steel.