## What does the graph show? ##

The graph plots the average fuel required per distance as a function of the *total* flight distance. It does *not* show fuel flow rate as a function of time during the flight.

## Why is it going up for short flights? ##

For short flights, the takeoff and climb to cruise altitude are a larger fraction of the total fuel required. Since the aircraft uses more fuel during the climb part compared to cruise, this will increase the average fuel per distance figure. The longer the flight gets, the less important is the climb.

## Why is it going up again for long flights? ##

The problem here is that you have to carry the fuel for the entire flight, which makes the aircraft significantly heavier. This is not an issue for short regional airliners, but for long-haul flights the fuel weight can be enormous. E.g., the 777-200LR has a max. fuel capacity of [145 t][1], which is about equal to its OEW (Operating Empty Weight).

Since the aircraft is now significantly heavier during the initial stage of the flight, it will burn more fuel due to the higher weight and due to the lower initial cruise altitude (e.g. optimum cruise altitude for a 777-200LR at a weight of 340 t is only FL285, but after burning 100 t of fuel it has increased to FL360). Long haul flights will usually perform step climbs to increase their cruise altitude during the flight as their weight decreases. This further reduces the fuel burn during the flight, but the *average* fuel burn for the long haul flight is still higher.


  [1]: https://en.wikipedia.org/wiki/Boeing_777#Specifications