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Pathway building tool

This website hosts a pathway building tool based on the DDP Approach that allows to articulate physical and socio-economic transformations to develop new decarbonisation pathways.

You will need from one to a few hours to develop your first pathway, depending on your expertise and knowledge.
Starting from the development of your storyline, throughout eight categories of transformations, you can then visualize your pathway in six graphic categories. At this stage, you can compare your scenario with another one, validate and save its different elements (story, computation, dashboard and graphs) or go back to correct your storyline.

We also offer the possibility for external partners to join and support the community in:

Here is a beta version to build pathways for the passenger transport sector in France.
It will be regularly updated and enriched with new countries and sectors, starting with freight transport.

Let’s try it!Beta version

In which country would you like to build a passenger transport decarbonization pathways?

Develop your storyline(Click on section labels to build your pathway)

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• 1. Demography and economics
  • Population

    What will be the size of your country population in 2050?

    In 2010, France had a population of about 60 901 thousand citizens over 6 years, for a total of around 65 million people.
    Note: The mobility of children under 6 years is not considered.

    Direct assumption in 2050 69 065 thousands citizens.
    Other direct assumption in 2050 thousands citizens.
    
  • Household size

    What will be the average household size in 2050?

    In 2010, the average French households were composed by 2.2 people.

    Direct assumption in 2050 2.0 pers./household.
    Other direct assumption in 2050 pers./household.
    
  • Household income

    What will be the average household disposable income in 2050?

    In 2010, the average household disposable income in France amounted to 23,000 eur and the total household disposable income was about 30% of GDP. Over the period 2000-2010, the average annual GDP growth was 1.4% per year.

    Direct assumption in 2050 32,000 eur/year
    Other direct assumption in 2050 k€/year.
    Other underlying assumptions on GDP growth and wealth distribution.
    
    Average annual GDP growth over the period 2010-2050: %/year
    Total household disposable incomes is around: % of GDP in 2050
    Validate section
• 2. Human settlement, land development and spatial organization
  • Metropolitan population

    What will be the share of the population living in Metropolitan areas in 2050?

    In 2010, about 25% of the population lived in metropolitan areas and 75% in non-metropolitan areas, of which half in suburban areas and the other half in rural areas. The metropolitan areas in France have been defined as: Paris, Departments of the Paris region 92-93-94 and all city centers of “urban poles” with more than 100,000 inhabitants. in 2008 (the smallest city center is the city of Montbéliard with about 25,000 inhabitants).

    Direct assumption in 2050 24% of the population.
    Other direct assumption in 2050 % of the population.
    
  • Constrained mobility for metropolitan households

    What will be the average distance travelled for constrained mobility in metropolitan areas in 2050?

    In 2010, a French citizen living in metropolitan areas travelled approximately 4,770 km / year to connect his different constrained activities. Constrained activities are defined as work-and shopping and acces to public services like schools, health, sport and other social facilities, where your freedom to decide whether or not to complete this activity is limited.

    Direct assumption in 2050 4,100 km per capita (pkm/cap) for constrained mobility for inhabitants of metropolitan areas.
    Other direct assumption in 2050 km per capita (pkm/cap) for constrained mobility for inhabitants of metropolitan areas.
  • Constrained mobility for non-metropolitan households

    How will the distance between constrained activities in metropolitan and non-metropolitan areas change in 2050?

    In 2010, a French citizen living in Non-Metropolitan areas had to travel about 27% more than a French citizen living in Metropolitan areas to connect his different constrained activities. This means that the different constrained activities (work, home, going to school and reaching other public services) were further away from each other.

    Direct assumption in 2050.
    The distance to connect the constrained activities in metropolitan and non-metropolitan areas will be reduced to 10 % in 2050.
    Other direct assumption in 2050. The distance between constrained activities in metropolitan and non-metropolitanareas will be reduced to % by 2050.
    
    Validate section
• 3. Sociocultural practices and lifestyles
  • Teleworking for metropolitan households

    In metropolitan areas, which share of constrained mobility will be removed by 2050 due to teleworking ?

    Many remote activities are now possible thanks to the rapid development of telecommunications. Working is one of the most constrained activities and requires daily commuting. In 2010, commuting represented 44% of the constrained distance travelled.

    Direct assumption in 2050 4% of total constrained activities.
    Other direct assumption in 2050 % of total constrained activities.
    Other underlying assumptions on the share of the Metropolitan Population concerned and days of teleworking:
    Share of population concerned by teleworking in 2050 : % metropolitan population in 2050
    Days of teleworking for a concerned employee in Metropolitan areas in 2050: days/month
  • Teleworking for non-metropolitan households

    In non-metropolitan areas, which share of constrained mobility will be removed by 2050 due to teleworking?

    Many remote activities are now possible thanks to the rapid development of telecommunications. Working is one of the most constrained activity which needs a daily commuting activity. In 2010, commuting represented 44% of the constrained distance travelled.

    Direct assumption in 2050 4% of total constrained activities.
    Other direct assumption in 2050 % of total constrained activities.
    Other underlying assumptions on the share of Metropolitan Population concerned and days of tyeleworking:
    Population Share concerned by teleworking in 2050: % Non-metropolitan Population in 2050
    Days of teleworking for a concerned employee in Non-metropolitan Population in 2050: days/month
  • ICTs and collaborative mobility

    What will be the occupancy rate of vehicles in 2050 due to development of the collaborative mobility?

    The development of Information and Communication Technologies and other tehnological transformations will support the development of the collaborative mobility. In 2010, the average occupancy rate of cars amounted to 1.43 persons:

    	Constrained trips	Non constrained trips
    Metropolitan population	1.29	1.46
    Non-metropolitan population	1.36	1.53

    
    
    Direct assumption in 2050

    Variation (%) of car occupancy rate (pass/veh)	Constrained trips	Non constrained trips
    Metropolitan population	1	60
    Non-metropolitan population	-1	25

    Variation (%) of bus occupancy rate (pass/veh)	Constrained trips	Non constrained trips
    Metropolitan population	20	20
    Non-metropolitan population	20	20

    Other direct assumption in 2050

    Variation (%) of car occupancy rate (pass/veh)	Constrained trips	Non constrained trips
    Metropolitan population
    Non-metropolitan population

    Variation (%) of bus occupancy rate (pass/veh)	Constrained trips	Non constrained trips
    Metropolitan population
    Non-metropolitan population

    Validate section
• 4. Technological development of vehicles
  • Car energy consumptions

    By how much new cars will reduce their energy consumption between 2010 and 2050?

    In 2010, the average energy efficiency of cars in France amounted to 2.3 MJ/vkm and the car stock was almost only composed by Internal Combustion Engine (ICE) vehicles.

    The energy consumption of new car sales reached

    ICE	1.9	MJ/vkm
    BEV	0.2	kWh/vkm
    FCEV	1.3	MJ/vkm

    ICE = Internal Combustion Engine | BEV = Battery Electric Vehicle | FCEV= Fuel-Cell Electric Vehicle

    Direct assumption in 2050
    

    Reduction (%) of energy consumption compared to 2010

    ICE	20 %
    BEV	10%
    FCEV	20%

    Other direct assumption in 2050
    

    Reduction (%) of energy consumption compared to 2010

    ICE	%
    BEV	%
    FCEV	%

  • Car sale prices

    What will be the sale prices of new cars in 2050?

    In 2010, car mobility represented more than 80% of total passenger mobility and around 417 Gvkm (vehicle-km) with almost 100% based on diesel and gasoline cars. The penetration of alternative motorization is a key technological solution for the future and purchase price is a sensitive parameter in this regard.

    In 2010, purchase prices (including all taxes and subventions) amounted to:

    New ICE	21 keur
    New CNG	24 keur
    New BEV	28 keur
    New PHEV	30 keur
    New FCEV	64 keur

    ICE = Internal Combustion Engine | CNG = Compressed Natural Gas | BEV = Battery Electric Vehicle | PHEV = Plug-and-Hybrid Electric Vehicle | FCEV= Fuel-Cell Electric Vehicle

    Direct assumption in 2050
    

    Average final purchase price (all taxes/subventions included)

    New ICE	29 keur/car
    New CNG	25 keur/car
    New BEV	20 keur/car
    New PHEV	27 keur/car
    New FCEV	23 keur/car

    Other direct assumption in 2050
    

    Average final purchase price (all taxes/subventions included)

    New ICE	keur/car
    New CNG	keur/car
    New BEV	keur/car
    New PHEV	keur/car
    New FCEV	keur/car

  • Mileage life car

    What will be the theoretical mileage over the lifetime of different car technologies in 2050?

    We estimated that the new ICE Liquid Fuel and Natural Gas car sold in 2010 had an average mileage life of 200 000 km.

    Related value of other technologies (% of new ICE sold):

    BEV	60%
    PHEV	70%
    FCEV	60%

    BEV = Battery Electric Vehicle | PHEV = Plug-and-Hybrid Electric Vehicle | FCEV= Fuel-Cell Electric Vehicle

    Direct assumption in 2050
    

    By 2050, the mileage over the lifetime of new ICE cars amounts to 250 000 kilometers over its lifetime.

    Value in relation to other technologies:

    BEV	100%
    PHEV	100%
    FCEV	100%

    Other direct assumption in 2050
    

    By 2050, average mileage lifetime of new ICE cars amounts to kilometers

    Related value for other technologies:

    BEV	%
    PHEV	%
    FCEV	%

  • Energy consumption for other vehicles

    By how much other models will reduce their energy consumption in 2050?

    The average energy consumption of the different modes in 2010 reached respectively :

    	ICE	electric	unit
    2W	1.5	0.10	MJ/vkm
    Buses	12.3	1.7	MJ/vkm
    Rail	0.45	0.11	MJ/pkm
    Air domestic	2.2	—	MJ/pkm
    Air international	1.8	—	MJ/pkm

    Direct assumption in 2050 Average efficiency gains compared to 2010 values are:

    	ICE	electric	unit
    2W	10%	0%	MJ/vkm
    Buses	15%	15%	MJ/vkm
    Rail	5%	5%	MJ/pkm
    Air domestic	17%	–	MJ/pkm
    Air international	17%	–	MJ/pkm

    Other direct assumption in 2050 Average efficiency gains compared to 2010-values are:

    	ICE	electric	unit
    2W	%	%	MJ/vkm
    Buses	%	%	MJ/vkm
    Rail	%	%	MJ/pkm
    Air domestic	%	–	MJ/pkm
    Air international	%	–	MJ/pkm

    Validate section
• 5. Fuel generation and carbon content
  • Electricity mix

    What will be the electricity mix in 2050 ?

    In 2010, average carbon content of final electricity is about 63 gCO2/kWh.

    In 2010, the French electric consumption came from

    Coal	3%
    Liquid fuels	1%
    Gas	6%
    Nuclear	75%
    Renewables (mainly hydro)	15%

    Direct assumption in 2050

    In 2050, the French electric consumption will came from

    Coal	0%
    Liquid fuels	0%
    Gas	4%
    Nuclear	31%
    Renewables (solar, wind and hydro)	65%

    Other direct assumption in 2050
    

    In 2050, the French electric consumption will came from

    Coal	%
    Liquid fuels	%
    Gas	%
    Nuclear	%
    Renewables (solar, wind and hydro)	%

  • Biofuels and hydrogen

    What will be the amount of biofuels and hydrogen produced for the transport sector in 2050 ?

    In 2010, about 0.03 EJ of bioethanol and biodiesel were produced, or about 3% of the total liquid fuels consumed that year.

    Direct assumption in 2050
    Liquid biofuel generation could produce up to 0.08 EJ by 2050
    Gaseous biofuel generation could produce up to 0.01 EJ by 2050
    Hydrogen generated by electrolysis from renewable electricity could produce up to 0.0 EJ by 2050
    Other direct assumption in 2050
    
    Liquid biofuel generation could produce up to EJ by 2050
    Gaseous biofuel generation could produce up to EJ by 2050
    Hydrogen generated by electrolysis from renewable electricity could produce up to EJ by 2050
  • Fuel prices

    What will be the final fuel prices in 2050?

    Final fuel prices could change due to a variety of measures (taxes, new generation technologies, global price changes…)

    2010 average final liquid fuel prices

    Liquid fuel (diesel, gasoline, liquid biofuels)	1.2 €/liter
    Methane fuel (natural gas, biogas)	1.1 €/kg
    Electricity	0.1 €/kWh
    Hydrogen	20.0 €/kg

    Direct assumption in 2050

    In 2050, the final fuel prices will reach:

    Liquid fuel (diesel, gasoline, liquid biofuels)	2.6 €/liter
    Methane fuel (natural gas, syngas, biogas)	2.3 €/kg
    Electricity	0.2 €/kWh
    Hydrogen	10.0 €/kg

    Other direct assumption in 2050
    

    In 2050, the final fuel prices will reach:

    Liquid fuel (diesel, gasoline, liquid biofuels)	€/liter
    Methane fuel (natural gas, syngas, biogas)	€/kg
    Electricity	€/kWh
    Hydrogen	€/kg

    Validate section
• 6. Penetration of alternative motorizations in the car stock
  • Car ownership model

    What will be the motorization rate of households in 2050?

    The development of Information and Communication Technologies (ICTs) supports the growth of a collaborative mobility economy and can change the way different transport modes are used. However, the ownership model depends on many other parameters, such as the evolution of households’ size and spending power, the availability of other modes of transport in rural areas, and issues related to social status.
    In 2010, France was home of 510 cars per 1000 inhabitants, or 31.1 million cars.

    Direct assumption in 2050 319 veh / 1000’s inhabitants.
    Other direct assumption in 2050 veh / 1000’s inhabitants.
  • Car stock and sales

    What will the car fleet look like in 2050?

    In 2010, the car stock was made almost exclusively of liquid fuel cars. Over the period 2001-2010, about 2,2 million vehicles were sold per year, with a stock lifetime of around 14 years.
    Cars’ sale , final fuel prices and households’ spending capacity are related to the penetration of new vehicles.

    ICE = Internal Combustion Engine | BEV = Battery Electric Vehicle | PHEV = Plug-and-Hybrid Electric Vehicle | FCEV= Fuel-Cell Electric Vehicle

    Direct assumption in 2050

    Stock by vehicle motorization in 2050

    ICE stock	45%
    CNG stock	1%
    BEV stock	22%
    PHEV stock	32%
    FCEV stock	0%

    Other direct assumption in 2050
    

    Stock by vehicle motorization in 2050

    ICE stock	%
    CNG stock	%
    BEV stock	%
    PHEV stock	%
    FCEV stock	%

    Other underlying assumptions
    

    Real lifetime of the stock in 2050

    Average lifetime of car stock	years

    Car sales shares by technology for the period 2041-2050:

    ICE share	%
    CNG share	%
    BEV share	%
    PHEV share	%
    FCEV share	%

  • Electric and gas mobility for other modes

    What will be the place of electricity and gas in 2050’s mobility ?

    In 2010, the vast majority of the 2-3 wheelers was powered with liquid fuels. Bus mobility was supported at 98% with liquid fuels, but there were already signs of what was to come with gas and electric vehicles. Rail passenger kilometers were covered at 80% with electricity and the remaining 20% with liquid fuels. domestic and international air travels were only possible with liquid fuels. We do not enable the choice of electric aircraft or other alternatives to to liquid fuels for jet engines in 2050.

    Direct assumption in 2050

    Electrification of 2/3 wheeler mobility	90% of 2W-vkm with electricity (the rest with liquid fuels)
    Electricfication of bus mobility	40% of bus-vkm with electricity
    Development of gas mobility for buses	25% of bus-vkm with gas (the rest with liquid fuels)
    Electrification of rail mobility	93% of rail-pkm with electricity (the rest with liquid fuels)

    Other direct assumption in 2050
    

    2W – kilometer travelled with electricity	% (the rest with liquid fuels)
    Bus – kilometer travelled with electricity	%
    Bus – kilometer travelled with methane gas	% (the rest with liquid fuels)
    Rail – kilometer travelled with electricity	% (the rest with liquid fuels)

    Validate section
• 7. Income dedicated to transport, modal distribution and costs
  • Income dedicated to transport

    What will be the share of the household disposable income dedicated to transport in 2050 ?

    In 2010, the average household expenditure dedicated to mobility was 17% of disposable income. More information in: Les comptes des transports en 2015, CGDD, July 2016.

    Direct assumption in 2050
    Share of the household disposable income dedicated to transport sector
    • For metropolitan household, it amounts to 4.6%
    For non-metropolitan household, it amounts to 8%
    Other direct assumption in 2050
    
    Share of the household disposable income dedicated to transport sector
    For metropolitan household, it amounts to %
    For non-metropolitan household, it amounts to %
  • Modal choice for constrained mobility

    Which modes of transport will be used for constrained mobility in 2050?

    In 2010, mobility for constrained purposes represented around 4,770 pkm for metropolitan individuals and 6,067 pkm for non-metropolitan individuals.

    Different modes (% of pkm) and related prices were:

    	Metropolitan	Non-metropolitan	Average costs
    Car	61%	86%	0.17 €/pkm
    2W	1%	1%	0.17 €/pkm
    Bus	7%	6%	0.06 €/pkm
    Rail	15%	2%	0.01 €/pkm
    Air – domestic	2%	1%	0.04 €/pkm
    Air – international	10%	3%	0.02 €/pkm
    Non motorised	5%	2%	0.00 €/pkm

    Direct assumption in 2050

    Constrained mobility distribution among modes (% of constrained passenger-kilometer)

    	Metropolitan	Non-metropolitan
    Car	45%	69%
    2W	1%	1%
    Bus	6%	7%
    Rail	15%	2%
    Air – domestic	2%	2%
    Air – international	11%	4%
    Non motorised	20%	16%

    Other direct assumption in 2050
    

    Constrained mobility distribution among modes (% of constrained passenger-kilometer)

    	Metropolitan	Non-metropolitan
    Car	%	%
    2W	%	%
    Bus	%	%
    Rail	%	%
    Air – domestic	%	%
    Air – international	%	%
    Non motorised	%	%

    Other underlying assumptions on 2050 modal prices
    

    Constrained mobility average modal price

    <!– –>

    	Metropolitan	Non-metropolitan
    Car (has been set before)	xlG320 €/pkm	xlG320 €/pkm
    Car (has been set before)	€/pkm	€/pkm
    2W	€/pkm	€/pkm
    Bus	€/pkm	€/pkm
    Rail	€/pkm	€/pkm
    Air – domestic	€/pkm	€/pkm
    Air – international	€/pkm	€/pkm
    Non motorised	€/pkm	€/pkm

  • Modal choice for non-constrained mobility

    Which modes of transport will be used for non-constrained mobility in 2050?

    In 2010, mobility for non-constrained purposes represented around 8,160 pkm for metropolitan individuals and 7,990 pkm for non-metropolitan individuals.

    Different modes (% of passenger-kilometer) and the related prices were:

    	Metropolitan	Non-metropolitan	Average costs
    Car	58%	66%	0.17 €/pkm
    2W	0.5%	1%	0.17 €/pkm
    Bus	4%	3%	0.06 €/pkm
    Rail	10.5%	12.5%	0.01 €/pkm
    Air – domestic	1%	1%	0.04 €/pkm
    Air – international	23%	14.5%	0.02 €/pkm
    Non motorised	3%	2%	0.00 €/pkm

    Direct assumption in 2050

    Non-constrained mobility distribution among modes (% of non-constrained passenger kilometer)

    	Metropolitan	Non-metropolitan
    Car	52%	52%
    2W	0.5%	1%
    Bus	11%	7%
    Rail	12%	24%
    Air – domestic	0%	0%
    Air – international	15%	9%
    Non motorised	9.5%	7%

    Other direct assumption in 2050
    

    Non-constrained mobility distribution among modes (% of non-constrained passenger kilometer)

    	Metropolitan	Non-metropolitan
    Car	%	%
    2W	%	%
    Bus	%	%
    Rail	%	%
    Air – domestic	%	%
    Air – international	%	%
    Non motorised	%	%

    Other underlying assumptions on 2050 modal prices
    

    Non-constrained mobility average modal price

    <!– –>

    	Metropolitan	Non-metropolitan
    Car (has been set before)	xlG320 €/pkm	xlG320 €/pkm
    Car (has been set before)	€/pkm	€/pkm
    2W	€/pkm	€/pkm
    Bus	€/pkm	€/pkm
    Rail	€/pkm	€/pkm
    Air – domestic	€/pkm	€/pkm
    Air – international	€/pkm	€/pkm
    Non motorised	€/pkm	€/pkm

    Validate section
• 8. Speed, infrastructure and time dedicated to transport
  • Modal speeds for constrained mobility

    What will be the speed of travel for constrained activities using different modes in 2050?

    In 2010, the average speed to carry out constrained activities was:
    

    	Metropolitan	Non-metropolitan
    Car	34 km/h	38 km/h
    2W	26 km/h	30 km/h
    Bus	16 km/h	19 km/h
    Rail	24 km/h	6 km/h
    Non motorised	4 km/h	4 km/h

    Note : Air transport is excluded from this calculation.

    Direct assumption in 2050

    Average modal speed	Metropolitan	Non-metropolitan
    Car	38 km/h	40 km/h
    2W	28 km/h	32 km/h
    Bus	18 km/h	23 km/h
    Rail	26 km/h	5 km/h
    Non motorised	8 km/h	9 km/h

    Other direct assumption in 2050
    

    Average modal speed	Metropolitan	Non-metropolitan
    Car	km/h	km/h
    2W	km/h	km/h
    Bus	km/h	km/h
    Rail	km/h	km/h
    Non motorised	km/h	km/h

  • Modal speeds for non-constrained mobility

    What will be the speed of travel for non-constrained activities using different modes in 2050?

    In 2010, the average speed to carry out non-constrained activities was:

    	Metropolitan	Non-metropolitan
    Car	34 km/h	38 km/h
    2W	26 km/h	30 km/h
    Bus	16 km/h	19 km/h
    Rail	24 km/h	6 km/h
    Non motorised	4 km/h	4 km/h

    Note : Air transport is excluded from this calculation.

    Direct assumption in 2050

    Average modal speed	Metropolitan	Non-metropolitan
    Car	38 km/h	40 km/h
    2W	28 km/h	32 km/h
    Bus	18 km/h	23 km/h
    Rail	26 km/h	5 km/h
    Non motorised	8 km/h	9 km/h

    Other direct assumption in 2050
    

    Average modal speed	Metropolitan	Non-metropolitan
    Car	km/h	km/h
    2W	km/h	km/h
    Bus	km/h	km/h
    Rail	km/h	km/h
    Non motorised	km/h	km/h

    Validate section
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