With the likelihood of autonomous vehicle technologies in public transport and taxi systems prior to privately-owned vehicles increasing, their actual impact on commuting in real-world road networks is insufficiently studied. In this study, an agent-based model is developed to simulate how commuters travel by autonomous taxis (aTaxis) in real-world road networks. The model evaluates the travel costs and environmental implications of substituting conventional personal vehicle travel with aTaxi travel. The proposed model is applied to the City of Ann Arbor, MI to demonstrate the effectiveness of aTaxis. Our results indicate that to meet daily commute demand with wait times less than 3 minutes, the optimized autonomous taxi fleet size is only 20% of the conventional solo-commuting personal car fleet. The commuting cost decreases by 38%, and daily vehicle utilization increases from 14 minutes to 92 minutes. In case of utilizing internal combustion engine aTaxis, energy consumption, GHG emissions, and SO2 emissions are respectively 16%, 25%, and 10% higher than conventional solo commuting, mainly due to unoccupied repositioning between trips. Given the emission intensity of the local electricity grid, the environmental impacts of electric aTaxis do not show significant improvement over conventional vehicles.