Now do one where you A) normalize this to the same trip distance (not speed, so that these choices for a single trip become meaningfull) and B) convert the kWh into CO2 emissions, including the emissions in growing and transporting the various power and food production methods used (coal to solar, locally produced veggies-air shipped beef)
Trip distance is dependent on methods of transportation at the aggregate level. That’s only relevant for policy decisions or collective actions, not individuals of course, but if we are going to deal with climate change, collective action is necessary.
Given the graph is normalized by km traveled, its overly generous to cars.
Yeah, if you account for the amount of CO2 that goes into producing food the ebike will be much more efficient in terms of co2/km than a regular bicycle. Even if you cheat by making the regular bicycle drive slower than the ebike, like they did for this chart.
Now do one where you A) normalize this to the same trip distance (not speed, so that these choices for a single trip become meaningfull) and B) convert the kWh into CO2 emissions, including the emissions in growing and transporting the various power and food production methods used (coal to solar, locally produced veggies-air shipped beef)
It’s already normalized to distance, the graph is showing kWh/km. The site speed is just there for additional context.
Trip distance is dependent on methods of transportation at the aggregate level. That’s only relevant for policy decisions or collective actions, not individuals of course, but if we are going to deal with climate change, collective action is necessary.
Given the graph is normalized by km traveled, its overly generous to cars.
Yeah, if you account for the amount of CO2 that goes into producing food the ebike will be much more efficient in terms of co2/km than a regular bicycle. Even if you cheat by making the regular bicycle drive slower than the ebike, like they did for this chart.