Abstract
Transportation of people and of goods plays an important role in modern life. It is a major source of anthropogenic CO2. This chapter, after introducing some fundamentals of natural climate fluctuations as described by Milankovitch cycles, describes the causes and consequences of man-made climate change and the motivation for increased fuel efficiency in transportation systems. To this end, contemporary and future ground-based and air-based transportation technologies are discussed. It is shown that concepts that were already given up, such as turbine-driven cars, might be worthwhile for further studies. Alternative fuels such as hydrogen, ethanol and biofuels, and alternative power sources, e.g., compressed air engines and fuel cells, are presented from various perspectives. The chapter also addresses the contribution of CO2 emissions of the supply chain and over the entire life cycle for different transportation technologies.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Agresti F (2010) Hydrogen storage in metal and complex hydrides: from possible niche applications towards promising high performance systems. VDM Verlag Dr. Müller, Saarbrücken. ISBN 9783639313444
Åhman M (2001) Primary energy efficiency of alternative powertrains in vehicles. Energy 26(11):973–989 (Original Research Article)
Åkerman J, Höjer M (2006) How much transport can the climate stand? – Sweden on a sustainable path in 2050. Energy Policy 34(14):1944–1957
Allan T (2011) Virtual water: tackling the threat to our planet's most precious resource. IB Tauris, London. ISBN 978-1845119843
Ally J, Pryor T (2007) Life-cycle assessment of diesel, natural gas and hydrogen fuel cell bus transportation systems. J Power Source 170(2):401–411
Azar C, Lindgren K, Andersson BA (2003) Global energy scenarios meeting stringent CO2 constraints – cost-effective fuel choices in the transportation sector. Energy Policy 31(10):961–976
Babikian R, Lukachko SP, Waitz IA (2002) The historical fuel efficiency characteristics of regional aircraft from technological, operational, and cost perspectives. J Air Transp Manag 8(6):389–400
Cadarso M, López L-A, Gómez N, Tobarra M (2010) CO2 emissions of international freight transport and offshoring: measurement and allocation. Ecol Econ 69(8):1682–1694
Chen H, Ding Y, Li Y, Zhang X, Tan C (2011) Air fuelled zero emission road transportation: a comparative study. Appl Energy 88(1):337–342
Chester MV, Horvath A (2009) Environmental assessment of passenger transportation should include infrastructure and supply chains. Environ Res Lett 4:024008
Chèze B, Gastineau P, Chevallier J (2011) Forecasting world and regional aviation jet fuel demands to the mid-term (2025). Energy Policy 39(9):5147–5158
DeCicco J, Fung F, An F (2015) Global warming on the road, environmental defense. http://www.edf.org/documents/5301_Globalwarmingontheroad.pdf
Eaves S, Eaves J (2004) A cost comparison of fuel-cell and battery electric vehicles. J Power Source 130(1–2):208–212
Fitzgerald WB, Howitt OJA, Smith IJ (2011) Greenhouse gas emissions from the international maritime transport of New Zealand's imports and exports. Energy Policy 39(3):1521–1531
Flannery T (2006) The weather makers. Grove Atlantic, New York. ISBN 9780802142924
Geerlings H, van Duin R (2011) A new method for assessing CO2-emissions from container terminals: a promising approach applied in Rotterdam. J Cleaner Prod 19(6–7):657–666
Gibson consulting (2015) http://www.gibsonconsulting.com/
Greene DL (2004) Transportation and energy. In: Encyclopedia of energy. Academic, Amsterdam/Boston, pp 179–188
Gross KJ, Thomas GJ, Jensen CM (2002) Catalyzed alanates for hydrogen storage. J Alloy Compound 330–332:683–690
Hamelinck CN, Suurs RAA, Faaij APC (2003) International bioenergy transport costs and energy balance. Universiteit Utrecht, Copernicus Institute, Science Technology Society, Utrecht. ISBN The book seems to be not published officially. But an article was published: Biomass and Bioenergy, Volume 29 Issue 2 Pages 114–134, DOI 10.1016/j.biombioe.2005.04.002
Hao H, Wang H, Yi R (2011) Hybrid modeling of China’s vehicle ownership and projection through 2050. Energy 36(2):1351–1361
Hege JB (2006) The Wankel rotary engine: a history. Mcfarland, Jefferson. ISBN 9780786429059
Heitmann N, Khalilian S (2011) Accounting for carbon dioxide emissions from international shipping: burden sharing under different UNFCCC allocation options and regime scenarios. Marine Policy 35(5):682–691
IPCC (2013) http://www.ipcc.ch/report/graphics/index.php?t=Assessment%20Reports&r=AR5%20-%20WG1&f=Chapter%2006
Kamal WA (1997) Improving energy efficiency – the cost-effective way to mitigate global warming. Energy Convers Manag 38(1):39–59
Kukla G, Gavin J (2004) Milankovitch climate reinforcements. Global Planet Change 40(1–2):27–48
Lee JJ (2010) Can we accelerate the improvement of energy efficiency in aircraft systems? Energy Convers Manag 51(1):189–196
Lee JJ, Lukachko SP, Waitz IA (2004) Aircraft and energy use. In: Encyclopedia of energy. Academic, Amsterdam/Boston, pp 29–38
Liao L, Pasternak I (2009) A review of airship structural research and development. Prog Aerosp Sci 45(4–5):83–96
Lipscy PY, Schipper L (2013) Energy efficiency in the Japanese transport sector. Energy Policy 56:248–258
Litman T (2005) Efficient vehicles versus efficient transportation. Comparing transportation energy conservation strategies. Transp Policy 12(2):121–129
Lund H (2007) Renewable energy strategies for sustainable development. Energy 32(6):912–919
Mallapragada DS, Duan G, Agrawal R (2014) From shale gas to renewable energy based transportation solutions. Energy Policy 67:499–507
Martin S, Wörner A (2011) On-board reforming of biodiesel and bioethanol for high temperature PEM fuel cells: comparison of autothermal reforming and steam reforming. J Power Source 196(6):3163–3171
Miller AR (2009) Applications – transportation, rail vehicles: fuel cells. In: Encyclopedia of electrochemical power sources. Academic, Amsterdam/Boston, pp 313–322
Miller FP, Vandome AF, McBrewster J (2010) Compressed-air energy storage: compressed-air vehicle. Compressed-air engine, compressed air car, air compressor, load profile, compressed air, … gas, fireless locomotive, vehicle-to- grid. Alphascript Publishing. ISBN: 978–6130271428, Saarbrücken/Germany
Morrell P (2009) The potential for European aviation CO2 emissions reduction through the use of larger jet aircraft. J Air Transp Manag 15(4):151–157
Muratori M, Moran MJ, Serra E, Rizzoni G (2013) Highly-resolved modeling of personal transportation energy consumption in the United States. Energy 58(1):168–177
National Snow & Ice Data Center (2015) http://nsidc.org/
Obert EF (1973) Internal combustion engines and air pollution, vol 3. Addison Wesley, New York. ISBN 9780700221837
Parry IWH, Evans D, Oates WE (2014) Are energy efficiency standards justified? J Environ Econ Manag 67(2):104–125
Paschen J-A, Ison R (2014) Narrative research in climate change adaptation – exploring a complementary paradigm for research and governance. Res Policy 43(6):1083–1092
Petersen AM, Melamu R, Knoetze JH, Görgens JF (2015) Comparison of second-generation processes for the conversion of sugarcane bagasse to liquid biofuels in terms of energy efficiency, pinch point analysis and Life Cycle Analysis. Energy Convers Manag 91:292–301
Qin N, Vavalle A, Le Moigne A, Laban M, Hackett K, Weinerfelt P (2004) Aerodynamic considerations of blended wing body aircraft. Prog Aerosp Sci 40(6):321–343
Romm J (2006) The car and fuel of the future. Energy Policy 34(17):2609–2614
Schrooten L, De Vlieger I, Panis L, Chiffi C, Pastori E (2009) Emissions of maritime transport: a European reference system. Sci Total Environ 408(2):318–323
Schulz W (2007) The costs of biofuels. Chem Eng News 85(51):12–16, http://pubs.acs.org/cen/coverstory/85/8551cover.html
Sim K, Koo B, Kim CH, Kim TH (2013) Development and performance measurement of micro-power pack using micro-gas turbine driven automotive alternators. Appl Energy 102:309–319
Sivak M, Tsimhoni O (2009) Fuel efficiency of vehicles on US roads: 1923–2006. Energy Policy 37(8):3168–3170
Sperling D, Gordon D, Schwarzenegger A (2010) Two billion cars: driving toward sustainability. Oxford University Press, New York. ISBN 9780199737239
The Keeling Curve, Scripps Institution of Oceanography, UC San Diego, USA, https://scripps.ucsd.edu/programs/keelingcurve/. Accessed 1 Jan 2015
Tickell J (2000) From the fryer to the fuel tank: how to make cheap, clean fuel from free vegetable oil: The complete guide to using vegetable oil as an alternative fuel. GreenTeach Publishing, Sarasota. ISBN 9780966461602
Ticker J (2003) From the fryer to the fuel tank. GreenTeach Publishers, Sarasota. ISBN 0970722702
Title 40 (2015), Protection of environment, Sec. 600.113-93, Fuel economy calculations, http://edocket.access.gpo.gov/cfr_2010/julqtr/40cfr600.113-93.htm
Utlu Z, Hepbasli A (2007) A review on analyzing and evaluating the energy utilization efficiency of countries. Renew Sustain Energy Rev 11(1):1–29
van Vliet OPR, van Vliet OPR, Kruithof T, Turkenburg WC, Faaij APC (2010) Techno-economic comparison of series hybrid, plug-in hybrid, fuel cell and regular cars. J Power Source 195(19):6570–6585
Villalba G, Gemechu ED (2011) Estimating GHG emissions of marine ports – the case of Barcelona. Energy Policy 39(3):1363–1368
von Blottnitz H, Ann Curran M (2007) A review of assessments conducted on bio-ethanol as a transportation fuel from a net energy, greenhouse gas, and environmental life cycle perspective. J Clean Prod 15(7):607–619 (Original Research Article)
Walsh JE (2014) Intensified warming of the arctic: causes and impacts on middle latitudes. Global Planet Change 117:52–63
Wu L, Huo H (2014) Energy efficiency achievements in China's industrial and transport sectors: how do they rate? Energy Policy 73:38–46
Zamfirescu C, Dincer I (2009) Ammonia as a green fuel and hydrogen source for vehicular applications. Fuel Process Technol 90(5):729–737 (Original Research Article)
Zarifi F, Mahlia TMI, Motasemi F, Shekarchian M, Moghavvemi M (2013) Current and future energy and exergy efficiencies in the Iran’s transportation sector. Energy Convers Manag 74:24–34
Zhang M, Li H, Zhou M, Mu H (2011a) Decomposition analysis of energy consumption in Chinese transportation sector. Appl Energy 88(6):2279–2285
Zhang M, Li G, Mu HL, Ning YD (2011b) Energy and exergy efficiencies in the Chinese transportation sector, 1980–2009. Energy 36(2):770–776
Zhao H (2007) HCCI and CAI engines for the automotive industry. Woodhead Publishing, Cambridge, UK. ISBN 9781845691288
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2021 Springer Science+Business Media, LLC, part of Springer Nature
About this entry
Cite this entry
Lackner, M., Seiner, J.M., Chen, WY. (2021). Fuel Efficiency in Transportation Systems. In: Chen, WY., Suzuki, T., Lackner, M. (eds) Handbook of Climate Change Mitigation and Adaptation. Springer, New York, NY. https://doi.org/10.1007/978-1-4614-6431-0_18-2
Download citation
DOI: https://doi.org/10.1007/978-1-4614-6431-0_18-2
Received:
Accepted:
Published:
Publisher Name: Springer, New York, NY
Print ISBN: 978-1-4614-6431-0
Online ISBN: 978-1-4614-6431-0
eBook Packages: Living Reference Chemistry and Mat. ScienceReference Module Physical and Materials ScienceReference Module Chemistry, Materials and Physics