Swaminathan N., Bray K.N.C. (eds.) Turbulent Premixed Flames

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References 353

of the Council of 21 May 2008 on ambient air quality and cleaner air for

Europe.

[29] COM 446, Final Communication From The Commission To The Council And

The European Parliament: Thematic Strategy on Air Pollution (2005).

[30] Health aspects of air pollution results from the project “Systematic review

of health aspects of air pollution in Europe”. Publications, WHO Regional

Ofﬁce for Europe, Scherﬁgsvej 8, DK-2100 Copenhagen O, Denmark (2004).

Available at http://www.euro.who.int/document/e83080.pdf.

[31] SEC 1745, Commission Staff Working Document. Annex to the proposal for

a regulation of the European Parliament and of the Council on type approval

of motor vehicles with respect to emissions and on access to vehicle repair in-

formation, amending Directive 72/306/EEC and Directive ../../EC [sic]. Impact

Assessment (2005).

[32] Scientiﬁc Committee on Health and Environmental Risks (SCHER): Opin-

ion on “New evidence of air pollution effects on human health and

the environment”, 18 March 2005. European Commission Health & Con-

sumer Protection Directorate-General Directorate C – Public Health and

Risk Assessment C7 – Risk assessment. Available at http://ec.europa.eu/

health/ph

risk/committees/04 scher/docs/scher o 009.pdf.

[33] SEC 1133, Commission Staff Working Paper. Annex to The Communication

on Thematic Strategy on Air Pollution and The Directive on “Ambient Air

Quality and Cleaner Air for Europe”. Impact Assessment (2005).

[34] SEC 1718, Commission Staff Working Document. Annex to the proposal for a

regulation of the European Parliament and of the Council on the approxima-

tion of the laws of the Member States with respect to emissions from on-road

heavy duty vehicles and on access to vehicle repair information. Impact As-

sessment (2007).

[35] COM 447, ﬁnal Proposal for a Directive of the European Parliment and of the

Council on ambient air quality and cleaner air for Europe (2005).

[36] Nitrogen dioxide in the United Kingdom – Chapter 2. NOx emissions and emis-

sion inventories, The Air Quality Expert Group, Defra Publications, Admail

6000, London SW1A 2XX. This document is also available on the AQEG web-

site: http://www.defra.gov.uk/environment/airquality/aqeg. Published by the

Department for Environment, Food and Rural Affairs (2004).

[37] W. W. Pulkrabek, Engineering Fundamentals of the Internal Combustion En-

gine, 2nd ed. (Pearson Education International, Upper Saddle River, NJ, 2004).

[38] K.-H. Dietsche and M. Klingebiel (eds.), Bosch Automotive Handbook, 7th ed.

Robert Bosch GmbH Plochingen, Wiley, Chichester (2007).

[39] C. D. Rakopoulos and E. G. Giakoumis, Diesel Engine Transient Operation –

Principles of Operation and Simulation Analysis (Springer-Verlag, London,

2009).

[40] U. Spicher, Exhaust emissions and pollutant reduction, in R. van Basshuysen

(ed.), Gasoline Engine with Direct Injection (Vieweg+Teubner GWV Fachver-

lag GmbH, Wiesebaden, Germany, 2009).

[41] P. Eastwood, Exhaust gas aftertreatment for light-duty diesel engines, in

H. Zhao (ed.), Advanced Direct Injection Combustion Engine Technologies

and Development,Vol.2,Diesel Engines (Woodhead, Oxford, 2010).

[42] A. Cairns, H. Blaxhill, and N. Fraser, Exhaust gas recirculation boosted di-

rect injection gasoline engines, in H. Zhao (ed.), Advanced Direct Injection

Combustion Engine Technologies and Development,Vol.1,Gasoline and Gas

Engines (Woodhead, Oxford, 2009).

[43] J. W. G. Turner and R. J. Pearson, The turbocharged direct injection spark-

ignition engine, in H. Zhao (ed.), Advanced Direct Injection Combustion En-

gine Technologies and Development,Vol.1,Gasoline and Gas Engines (Wood-

head, Oxford, 2009).

354 Lean Flames in Practice

[44] J. D. Pagliuso and M. E. S. Martins, Biofuels for spark ignition engines, in

H. Zhao (ed.), Advanced Direct Injection Combustion Engine Technologies and

Development,Vol.1,Gasoline and Gas Engines (Woodhead, Oxford, 2009).

[45] P. Eastwood, Particulate Emissions from Vehicles (Wiley-Professional Engi-

neering, New York, 2008); also SAE book R-389.

[46] Commission Regulation (EC) 692/2008 of 18 July 2008 implementing and

amending Regulation ( EC) 715/2007 of the European Parliament and of the

Council on type-approval of motor vehicles with respect to emissions from

light passenger and commercial vehicles (Euro 5 and Euro 6) and on access to

vehicle repair and maintenance information.

[47] COM 683 ﬁnal. Proposal for a Regulation of the European Parliament and of

the Council on type-approval of motor vehicles with respect to emissions and

on access to vehicle repair information, amending Directive 72/306/EEC and

Directive (ibid.).

[48] M. Adachi, Advanced systems and trends for powertrain emission measure-

ments, presented at the 7th International Conference on Modelling and Di-

agnostics for Advanced Engine Systems (COMODIA 2008), Sapporo, Japan,

2008.

[49] Commission Staff Working Document. Impact Assessment for Euro 6 emission

limits for light duty vehicles (2006).

[50] COM 851 ﬁnal. Proposal for a regulation of the European Parliament and of

the Council on type-approval of motor vehicles and engines with respect to

emissions from heavy duty vehicles (Euro VI) and on access to vehicle repair

and maintenance information (2007).

[51] Nitrogen dioxide in the United Kingdom – Summary. Product code PB

9144. The Air Quality Expert Group, Defra Publications, Admail 6000, Lon-

don SW1A 2XX. This document is also available on the AQEG website:

http://www.defra.gov.uk/environment/airquality/aqeg. Published by the De-

partment for Environment, Food and Rural Affairs (2004). Available at

http://www.defra.gov.uk/environment/airquality/aqeg.

[52] J. B. Heywood, Internal Combustion Engine Fundamentals (McGraw-Hill, New

York, 1989).

[53] R. Stone, Introduction to Internal Combustion Engines, 3rd ed. (Palgrave,

Basingstoke, UK 1999).

[54] J. F. Grifﬁths and J. A. Barnard, Flame and Combustion, 3rd ed. (Blackie

Academic and Professional, London, 1995).

[55] W. Hentschel, Optical diagnostics for combustion process development of

direct-injection gasoline engines, Proc. Combust. Inst. 28, 1119–1135 (2000).

[56] C. D. Rakopoulos and E. G. Giakoumis, Second-law analyses applied to internal

combustion engines operation, Prog. Energy Combust. Sci. 32, 2–47 (2006).

[57] U. Spicher, Fuel consumption, in R. van Basshuysen (ed.), Gasoline Engine

with Direct Injection (Vieweg+Teubner GWV Fachverlag GmbH, Wiesebaden,

Germany, 2009).

[58] J. T. Farrell, J. G. Stevens, and W. Weissman, A second law analysis of high

efﬁciency low emission gasoline engine concepts, SAE paper 2006-01-0491

(2006).

[59] M. C. Drake and D. C. Haworth, Advanced gasoline engine development using

optical diagnostics and numerical modelling, Proc. Combust. Inst. 31, 99–124

(2007).

[60] A. C. Alkidas and S. H. El Tahry, Contributors to the fuel economy advantage

of DISI engines over PFI engines, SAE paper 2003-01-3101 (2003).

[61] T. H. Lake, J. Stokes, P. A. Whitaker, and J. V. Crump, Comparison of direct

injection gasoline combustion systems, SAE paper 980154 (1998).

[62] C. Schwarz, E. Sch

unemann, B. Durst, J. Fischer, and A. Witt, Potentials of the

spray-guided BMW DI combustion system, SAE paper 2006-01-1265 (2006).

References 355

[63] A. Waltner, P. Lueckert, U. Schaupp, E. Rau, R. Kemmler, and R. Weller,

Future technology of the spark-ignition engine: Spray-guided direct injection

with piezo injector, presented at the 27th International Vienna Motor Sympo-

sium (2006). See also P. Lueckert, A. Waltner, E. Rau, G. Vent, U. Schaupp,

The new V6 gasoline engine with direct injection by Mercedes-Benz. MTZ

(Motortechnische Zeitschrift) 11, 1–6 (2006).

[64] P. Langen, T. Melcher, S. Missy, C. Schwarz, E. Sch

unemann, New BMW six-

and four-cylinder petrol engines with high precision injection and stratiﬁed

combustion, 28, presented at the Internationales Wiener Motorensymposium

(2007) (Fortschritt-Berichten VDI, Austrian Society of Automotive Engineers,

Vienna 2007).

[65] Y. Takagi, A new era in spark-ignition engines featuring high-pressure direct

injection, Proc. Combust. Inst. 27, 2055–2068 (1998).

[66] F. Zhao, M.-C. Lai, and D. L. Harrington, Automotive spark-ignited direct-

injection gasoline engines, Prog. Energy Combust. Sci. 25, 437–562 (1999).

[67] U. Spicher, J. P. Haentsche, and T. Heidenreich, Injection systems and sys-

tem overview, in R. van Basshuysen (ed.), Gasoline Engine With Direct In-

jection (Vieweg+Teubner GWV Fachverlag GmbH, Wiesebaden, Germany,

2009).

[68] T. Date and S. Yagi, Research and development of the Honda CVCC engine,

SAE paper 740605 (1974).

[69] A. K. Oppenheim, Combustion in Piston Engines: Technology, Evolution, Di-

agnosis and Control (Springer-Verlag, Berlin, 2004).

[70] K. Horie, K. Nishizawa, T. Ogawa, S. Akazaki, and K. Miura, The development

of a high fuel economy and high performance four-valve lean burn engine, SAE

paper 920455 (1992).

[71] P. G. Aleiferis, I. Prassas, and A. M. K. P. Taylor, Novel optical instrumentation

meeting the challenges for energy and the environment, in Y. H. Mori and

K. Ohnishi (eds.), Energy and Environment: technological Challenges for the

Future (Springer-Verlag, Tokyo, 2001).

[72] J. L. Lumley, Engines: An Introduction (Cambridge University Press, Cam-

bridge, 1999).

[73] Y. Hardalupas, A. M. K. P. Taylor, J. H. Whitelaw, K. Ishii, H. Miyano, and

Y. Urata, Inﬂuence of injection timing on in-cylinder fuel distribution in a

Honda VTEC-E engine, SAE paper 950507 (1995).

[74] M. Berckmueller, N. P. Tait, R. D. Lockett, and D. A. Greenhalgh, In cylinder

crank angle resolved imaging of fuel concentration in a ﬁring spark ignition

engine using planar LIFS, Proc. Combust. Inst. 25, 151–156 (1994).

[75] N. E. Carabateas, A. M. K. P. Taylor, J. H. Whitelaw, K. Ishii, K. Yoshida, and

M. Matsuki, The effect of injector and intake port design on in-cylinder fuel

droplet distribution, airﬂow and lean burn performance for a Honda VTEC-E

engine, SAE paper 961923 (1996).

[76] P. G. Aleiferis, A. M. K. P. Taylor, J. H. Whitelaw, K. Ishii, and Y. Urata,

Cyclic variations of initial ﬂame kernel growth in a Honda VTEC-E lean-burn

spark-ignition engine, SAE paper 2000-01-1207 (2000).

[77] P. G. Aleiferis, A. M. K. P. Taylor, K. Ishii, and Y. Urata, The nature of early

ﬂame development in a lean burn stratiﬁed-charge spark-ignition engine, Com-

bust. Flame 136, 283–302 (2004).

[78] P. G. Aleiferis, A. M. K. P. Taylor, K. Ishii, and Y. Urata, The relative ef-

fects of fuel concentration, residual-gas fraction, gas motion, spark energy

and heat losses to the electrodes on ﬂame kernel development in a lean-burn

spark-ignition engine. Proc. Inst. Mech. Eng. D J. Auto. Eng. 218, 411–425

(2004).

[79] P. G. Aleiferis, Y. Hardalupas, A. M. K. P. Taylor, K. Ishii, and Y. Urata, Flame

chemiluminescence studies of cyclic combustion variations and air-to-fuel ratio

356 Lean Flames in Practice

of the reacting mixture in a lean-burn stratiﬁed-charge spark-ignition engine,

Combust. Flame 136, 72–90 (2004).

[80] P. G. Aleiferis, Y. Hardalupas, A. M. K. P. Taylor, K. Ishii, and Y. Urata,

Cyclic variations of fuel-droplet distribution during the early intake stroke of

a lean-burn stratiﬁed-charge spark-ignition engine, Exp. Fluids 39, 789–798

(2005).

[81] K. Kuwahara and H. Ando, Diagnostics of in-cylinder ﬂow, mixing and com-

bustion in gasoline engines, Meas. Sci. Technol. 11, R95–R111 (2000).

[82] K. Horie, Y. Kohda, K. Ogawa, and H. Goto, Development of a high fuel

economy and low emission four-valve direct injection engine with a center-

injection system, SAE paper 2004-01-2941 (2004).

[83] T. D. Fansler, M. C. Drake, B. E. Stojkovic, and M. E. Rosalik, Local fuel con-

centration, ignition and combustion in a stratiﬁed charge spark ignited direct

injection engine: Spectroscopic, imaging and pressure-based measurements.

Int. J. Eng. Res. 4, 61–86 (2003).

[84] B. D. Stojkovic, F. D. Fansler, M. C. Drake, and V. Sick, High-speed imaging

of OH* and soot temperature and concentration in a stratiﬁed-charge direct-

injection gasoline engine, Proc. Combust. Inst. 30, 2657–2665 (2005).

[85] E. Achleitner, H. B

acker, and A. Funaioli, Direct injection systems for Otto

engines, SAE paper 2007-01-1416 (2007).

[86] U. Spicher, T. Heidenreich, and B. Xander, Mixture formation and combus-

tion processes, in R. van Basshuysen (ed.), Gasoline Engine with Direct In-

jection (Vieweg+Teubner GWV Fachverlag GmbH, Wiesebaden, Germany,

2009).

[87] M. C. Drake, T. D. Fansler, and A. M. Lippert, Stratiﬁed-charge combustion:

modelling and imaging of a spray-guided direct-injection spark-ignition engine,

Proc. Combust. Inst. 30, 2683–2691 (2005).

[88] T. Honda, M. Kawamoto, H. Katashiba, M. Sumida, N. Fukutomi, and K.

Kawajiri, A study of mixture formation and combustion for spray-guided DISI,

SAE paper 2004-01-0046 (2004).

[89] P. Dahlander, M. Skogsberg, and I. G. Denbratt, Effects of injector parameters

on mixture formation for multi-hole nozzles in a spray-guided gasoline DI

engine, SAE paper 2005-01-0097 (2005).

[90] G. Rottenkolber, J. Gindele, J. Raposo, K. Dullenkopf, W. Hentschel, S. Wittig,

U. Spicher, and W. Merzkirch, Spray analysis of a gasoline direct injector by

means of two-phase PIV, Exp. Fluids 32, 710–721 (2002).

[91] K. D. Driscoll, V. Sick, and C. Gray, Simultaneous air/fuel-phase PIV measure-

ments in a dense fuel spray, Exp. Fluids 35, 112–115 (2003).

[92] W. Sauter, J. Pfeil, A. Velji, U. Spicher, N. Laudenbach, F. Altenschmidt, and

U. Schaupp, Application of particle image velocimetry for investigation of spray

characteristics of an outward opening nozzle for gasoline direct injection, SAE

paper 2006-01-3377 (2006).

[93] T. Li, K. Nishida, and H. Hiroyasu, Effect of split injection on stratiﬁed charge

formation of direct injection spark ignition engines, Int J. Engine Res. 8, 205–218

(2007).

[94] M. Skogsberg, P. Dahlander, and I. G. Denbratt, Spray shape and atomization

quality of an outward-opening piezo gasoline DI injector, SAE paper 2007-01-

1409 (2007).

[95] M. Skogsberg, P. Dahlander, R. Lindgren, and I. Denbratt, Effects of injector

parameters on mixture formation for multi-hole nozzles in a spray-guided

gasoline DI engine, SAE paper 2005-01-0097 (2005).

[96] B. Peterson and V. Sick, Simultaneous ﬂow ﬁeld and fuel concentration imaging

at 4.8 kHz in an operating engine, Appl. Phys B. 97, 887–895 (2009).

[97] R. Zhang and V. Sick, Multi-component fuel imaging in a spray-guided spark-

ignition direct-injection engine, SAE paper 2007-01-1826 (2007).

References 357

[98] J. D. Smith and V. Sick, Crank-angle resolved imaging of fuel distribution,

ignition and combustion in a direct-injection spark-ignition engine, SAE paper

2005-01-3753 (2005).

[99] J. D. Smith and V. Sick, A multi-variable high-speed imaging study of ignition

instabilities in a spray-guided direct-injected spark-ignition engine, SAE paper

2006-01-1264 (2006).

[100] J. D. Smith and V. Sick, Real-time imaging of fuel injection, evaporation and ig-

nition in a direct-injected spark-ignition engine, presented at ILASS Americas,

19th Annual Conference on Liquid Atomisation and Spray Systems, Toronto,

Canada, 2006.

[101] J D. Smith and V. Sick, Factors inﬂuencing spark behavior in a spray-guided

direct-injected engine, SAE paper 2006-01-3376 (2006).

[102] H. Zhao, Motivation, deﬁnition and history of HCCI/CAI engines, in H. Zhao

(ed.), HCCI and CAI Engines for the Automotive Industry (Woodhead, Cam-

bridge, 2007).

[103] S. Kimura, Low temperature and premixed combustion concept with late in-

jection, in H. Zhao (ed.), HCCI and CAI Engines for the Automotive Industry

(Woodhead, Cambridge, 2007).

[104] I. Denbratt, Advanced concepts for future light-duty diesel engines, in H. Zhao

(ed.), Advanced Direct Injection Combustion Engine Technologies and Devel-

opment,Vol.2,Diesel Engines (Woodhead, Oxford, 2010).

[105] F. Zhao, T. W. Asmus, D. N. Assanis, J. E. Dec, J. A. Eng, and P. M. Najt (eds.),

Homogeneous charge compression ignition (HCCI) engines: Key research and

development issues, SAE PT-94 (2003).

[106] W. Steiger and C. Kohnen, New combustion systems based on a new fuel spec-

iﬁcation, 27th International Vienna Motor Symposium 2006, VDI Research

Reports, Series 12, No. 622, Vols. 1 and 2 (2006).

[107] N. Iida, Natural gas HCCI engines, in H. Zhao (ed.), HCCI and CAI Engines

for the Automotive Industry (Woodhead, Cambridge, 2007).

[108] N. Iida, HCCI engines with other fuels, in H. Zhao (ed.), HCCI and CAI

Engines for the Automotive Industry (Woodhead, Cambridge, 2007).

[109] P G. Aleiferis, A. G. Charalambides, Y. Hardalupas, and Y. Urata, Modelling

and experiments of HCCI engine combustion with charge stratiﬁcation and

internal EGR, SAE paper 2005-01-3725 (2005).

[110] H. Zhao, Four-stroke CAI engines with residual gas trapping, in H. Zhao (ed.),

HCCI and CAI Engines for the Automotive Industry (Woodhead, Cambridge,

2007).

[111] A. Fuerhapter, Four-stroke CAI engines with internal exhaust gas recirculation

(EGR), in H. Zhao (ed.), HCCI and CAI Engines for the Automotive Industry

(Woodhead, Cambridge, 2007).

[112] S. M. Begg, D. J. Mason, and M. R. Heikal, Spark ignition and spark-assisted

controlled auto-ignition in an optical gasoline engine, SAE paper 2009-32-0072

(2009).

[113] H. Persson, B. Johansson, A. Remaon, The effect of swirl on spark-assisted

compression ignition (SACI), SAE paper 2007-01-1856 (2007).

[114] P. G. Aleiferis, A. G. Charalambides, Y. Hardalupas, A. M. K. P. Taylor, and

Y. Urata, Autoignition initiation and development of n-heptane HCCI combus-

tion assisted by inlet air heating, internal EGR or spark discharge: an optical

investigation, SAE paper 2006-01-3273 (2006).

[115] H. Yun, N. Wermuth, and P. Najt, Extending the high load operating limit of

a naturally-aspirated gasoline HCCI combustion engine, SAE paper 2010-01-

0847 (2010).

[116] D. K. Srivastava, M. Weinrotter, H. Koﬂer, A. K. Agarwal, and E. Wintner,

Laser-assisted homogeneous charge ignition in a constant volume combustion

chamber, Opt. Lasers Eng. 47, 680–685 (2009).

358 Lean Flames in Practice

[117] J. E. Dec, Advanced compression-ignition engines – understanding the in-

cylinder processes, Proc. Combust. Inst. 32, 2727–2742 (2009).

[118] J. E. Dec, W. Hwang, and M. Sj

oeberg, An investigation of thermal stratiﬁcation

in HCCI engines using chemiluminescence imaging, SAE paper 2006-01-1518

(2006).

[119] A. Hultqvist, M. Christensen, B. Johansson, M. Richter, J. Nygren, H. Hult, and

M. Ald

en, The HCCI combustion process in a single cycle – High-speed fuel

tracer LIF and chemiluminescence imaging, SAE paper 2002-01-0424 (2002).

[120] P. G. Aleiferis, A. G. Charalambides, Y. Hardalupas, A. M. K. P. Taylor, and

Y. Urata, Axial fuel stratiﬁcation of a homogeneous charge compression igni-

tion (HCCI) engine, Int. J. Vehicle Des. 44, 41–61 (2007).

[121] P. G. Aleiferis, A. G. Charalambides, Y. Hardalupas, A. M. K. P. Taylor, and

Y. Urata, The effect of axial charge stratiﬁcation and exhaust gases on com-

bustion ‘development’ in a homogeneous charge compression ignition engine,

Proc. Inst. Mech. Eng. D J. Auto. Eng. 222, 2171–2183 (2008).

[122] A. Hultqvist, M. Christensen, B. Johansson, M. Richter, J. Nygren, J. Hult, and

M. Ald

en, The HCCI combustion process in a single cycle – high-speed fuel

tracer LIF and chemiluminescence Imaging, SAE paper 2002-01-0424 (2002).

[123] D. J. Cook, H. Pitsch, J. H. Chen, and E. R. Hawkes, Flamelet-based modeling

of auto-ignition with thermal inhomogeneities for application to HCCI engines,

Proc. Combust. Inst. 31, 2903–2911 (2007).

[124] M. Sj

oberg and J. E. Dec, Effects of engine speed, fueling rate, and combustion

phasing on the thermal stratiﬁcation required to limit HCCI knocking intensity,

SAE paper 2005-01-2125 (2005).

[125] M. Sj

oberg, J. E. Dec, and N. P. Cernansky, Potential of thermal stratiﬁcation

and combustion retard for reducing pressure-rise rates in HCCI engines based

on multi-zone modelling and experiments, SAE paper 2005-01-0113 (2005).

[126] M. Sj

oberg and J. E. Dec, Inﬂuence of fuel autoignition reactivity on the high-

load limits of HCCI engines, SAE paper 2008-01-0054 (2008).

[127] M. Sj

oberg and J. E. Dec, A. Babajimopoulos, and D. Assanis, Comparing

enhanced natural thermal stratiﬁcation against retarded combustion phasing

for smoothing of HCCI heat-release rates, SAE paper 2004-01-2994 (2004)

[128] M. Sj

oberg and J. E. Dec, An investigation into lowest acceptable combustion

temperatures for hydrocarbon fuels in HCCI engines, Proc. Combust. Inst. 30,

2719–2726 (2005).

[129] W. Hwang, J. E. Dec, and M. Sj

oeberg, Fuel stratiﬁcation for low-load HCCI

combustion: Performance & fuel-PLIF measurements, SAE paper 2007-01-

4130.

[130] S. Tanaka, F. Ayala, and J. C. Keck, A reduced chemical kinetic model for

HCCI combustion of primary reference fuels in a rapid compression machine,

Combust. Flame 133, 467–481 (2003).

[131] S. Tanaka, F. Ayala, J. C. Keck, J. B. Heywood, Two-stage ignition in HCCI

combustion and HCCI control by fuels and additives, Combust. Flame 132,

219–239 (2003).

[132] C. K. Westbrook, Chemical kinetics of hydrocarbon ignition in practical com-

bustion systems, Proc. Combust. Inst. 28, 1563–1577 (2000).

[133] N. Peters, G. Paczko, R. Seiser, and K. Seshadri, Temperature cross-over and

non-thermal runaway at two-stage ignition of n-heptane, Combust. Flame 128,

38–59 (2002).

[134] W. Hwang, J. E. Dec, and M. Sj

oberg, Spectroscopic and chemical-kinetic

analysis of the phases of HCCI autoignition and combustion for single- and

two-stage ignition fuels, Combust. Flame 154, 387–409 (2008).

[135] M. Sj

oberg and J. E. Dec, Comparing late-cycle autoignition stability for single-

and two-stage ignition fuels in HCCI engines, Proc. Combust. Inst. 31, 2895–

2902 (2007).

References 359

[136] M. Sj

oberg and J. E. Dec, Inﬂuence of fuel autoignition reactivity on the high-

load limits of HCCI engines, SAE paper 2008-01-0054 (2008).

[137] J. E. Dec and M. Sj

oberg, Isolating the effects of fuel chemistry on combustion

phasing in an HCCI engine and the potential of fuel stratiﬁcation for ignition

control, SAE paper 2004-01-0557 (2004).

[138] J. E. Dec and Y. Yang, Boosted HCCI for high power without engine knock

and with ultra-low NO

emissions – Using conventional gasoline, SAE paper

2010-01-1086 (2010) (also, Int. J. Engines, 3, 750–767, 2010).

[139] H. Zhao, Z. Peng, and N. Ladommatos, Understanding of controlled autoigni-

tion combustion in a four-stroke gasoline engine, Proc. Inst. Mech. Eng. D J.

Auto. Eng. 215, 1297–1310 (2001).

[140] M. Sj

oberg, J. E. Dec, and W. Hwang, Thermodynamic and chemical effects

of EGR and its constituents on HCCI autoignition, SAE paper 2007-01-0207

(2007).

[141] J. E. Dec, M. Sj

oberg, and W. Hwang, Isolating the effects of EGR on HCCI

heat-release rates and NO

emissions, SAE paper 2009-01-2665 (2009).

[142] P. Duret, Two-stroke CAI engines, in H. Zhao (ed.), HCCI and CAI Engines

for the Automotive Industry (Woodhead, Cambridge, 2007).

[143] Y. Ishibashi, An application study of the pneumatic direct injection activated

radical combustion two-stroke engine to scooter, SAE paper 2004-01-1870

(2004).

[144] Y. Urata, M. Awasaka, J. Takanashi, Y. Kakinuma, T. Hakozaki, and A. Umem-

oto, A study of gasoline-fuelled HCCI engine equipped with an electromag-

netic valve train, SAE paper 2004-01-1898 (2004).

[145] G. Haraldsson, P. Tunest

al, B. Johansson, and J. Hyvarnen, HCCI combustion

phasing with closed-loop combustion control using variable compression ratio

in a multi-cylinder engine, SAE paper 2003-01-1830 (2003).

[146] T. Urushihara, K. Yamaguchi, K. Yoshizawa, and T. Itoh, A study of a gasoline-

fueled compression ignition engine-expansion of HCCI operation range using

SI combustion as a trigger of compression ignition, SAE paper 2005-01-0180

(2005).

[147] D. Yap, M. Wyszynski, A. Megaritis, and H. Xu, Effect of inlet valve timing on

boosted gasoline HCCI with residual gas trapping, SAE paper 2005-01-2136

(2005).

[148] A. Cairns and H. R. Blaxill, Lean boost and external exhaust gas recirculation

for high load controlled autoignition, SAE paper 2005-01-3744 (2005).

[149] M. Martins and H. Zhao, 4-Stroke, multi-cylinder gasoline engine with con-

trolled auto-ignition (CAI) combustion: A comparison between naturally as-

pirated and turbocharged operation, SAE paper 2008-36-0305.

[150] S. Mamalis, V. Nair, P. Andruskiewicz, D. Assanis, A. Babajimopoulos, N.

Wermuth, and P. Najt, Comparison of different boosting strategies for ho-

mogeneous charge compression ignition engines – A modeling study, SAE

paper 2010-01-0571 (2010).

[151] J. Takanashi, M. Awasaka, T. Kakinuma, M. Takazawa, and Y. Urata, A study

of a gasoline HCCI engine equipped with an electromagnetic VVT mecha-

nism – increasing the higher load operational range with the inter-cylinder

EGR boost system, FISITA paper F2006P360; also JSAE paper no. 20068238

(2006).

[152] T. Kuboyama, Y. Moriyoshi, K. Hatamura, T. Yamada, and J. Takanashi, An

experimental study of a gasoline HCCI engine using the blow-down super

charging system, SAE paper 2009-01-0496 (2009).

[153] T. Kuboyama, Y. Moriyoshi, K. Hatamura, M. Suzuki, J. Takanashi, T. Yamada,

and S. Gotoh, Effect of fuel and thermal stratiﬁcations on the operational range

of an HCCI gasoline engine using the blow-down super charge system, SAE

Paper 2010-01-0845 (2010).

360 Lean Flames in Practice

[154] D. Kim, I. Ekoto, W. F. Colban, P. C. Miles, In-cylinder CO and UHC imaging

in a light-duty diesel engine during PPCI low-temperature combustion, SAE

paper 2008-01-1602 (2008).

[155] M. P. B. Musculus, L. M. Pickett, In-cylinder spray, mixing, combustion and

pollutant-formation processes in conventional and low-temperature combus-

tion diesel engines, in: H. Zhao (ed.), Advanced Direct Injection Combus-

tion Engine Technologies and Development, Vol 2, Diesel Engines (Woodhead,

Oxford, 2010).

[156] A. Helmantel and I. Denbratt, HCCI operation of a passenger car DI diesel

engine with an adjustable valve train, SAE paper 2006-01-0029 (2006).

[157] B. Gatellier, Narrow angle direct injection (NADI) concept for HCCI diesel

combustion, in H. Zhao (ed.), HCCI and CAI Engines for the Automotive

Industry (Woodhead, Cambridge, 2007).

[158] L. Hildingsson, H. Persson, B. Johansson, R. C. Collin, J. Nygren, M. Richter,

M. Ald

en, R. Hasegawa, and H. Yanagihara, Optical diagnostics of HCCI and

UNIBUS using 2-D PLIF of OH and formaldehyde, SAE paper 2005-01-0175

(2005).

[159] S. Singh, R. D. Reitz, M. P. B. Musculus, and T. Lachaux, Simultaneous opti-

cal diagnostic imaging of low-temperature, double-injection combustion in a

heavy- duty DI diesel engine, Combust. Sci. Technol. 179, 2381–2414 (2007).

[160] T. Lachaux, M. P. B. Musculus, S. Singh, and R. D. Reitz, Optical diagnostics

of late-injection low-temperature combustion in a heavy-duty diesel engine, J.

Eng. Gas Turbines Power 130 (2008). pp. 032808-1-9.

[161] J. E. Dec, A conceptual model of D.I. diesel combustion based on laser sheet

imaging. SAE Paper 970873, SAE Trans. 106, 1319–1348 (1997).

[162] C. L. Genzale, R. D. Reitz, and M. P. B. Musculus, Effects of piston bowl geom-

etry on mixture development and late-injection low-temperature combustion

in a heavy-duty diesel engine, SAE paper 2008-01-1330 (2008).

[163] M. P. B. Musculus, T. Lachaux, L. M. Pickett, and C. A. Idicheria,

End-of-injection over-mixing and unburned hydrocarbon emissions in low-

temperature-combustion diesel engines, SAE paper 2007-01-0907 (2007).

[164] T. Lachaux and M. P. B. Musculus, In-cylinder unburned hydrocarbon visual-

ization during low-temperature compression-ignition engine combustion using

formaldehyde PLIF, Proc. Combust. Inst. 31, 2921–2929 (2007).

[165] G. T. Kalghatgi, P. Risberg, and H-E. A

ngstr

om, Partially pre-mixed auto-

ignition of gasoline to attain low smoke and low NO

at high load in a compres-

sion ignition engine and comparison with a diesel fuel, SAE paper 2007-01-0006

(2007).

[166] G. Kalghatgi, L. Hildingsson, and B. Johansson, Low NO

and low smoke

operation of a diesel engine using gasoline-like fuels in Proceeding of the

ASME Internal Combustion Engine Division (American Society of Mechanical

Engineering, New York,2009), ICES 2009-76034.

[167] V. Sick, Optical diagnstics for direct injection gasoline engine rsearch and

development, in H. Zhao (ed.), Advanced Direct Injection Combustion Engine

Technologies and Development. Vol. 1, Gasoline and Gas Engines (Woodhead,

Oxford, 2009).

[168] C. Schulz, Optical diagnostics in diesel combustion engines, in H. Zhao (ed.),

Advanced Direct Injection Combustion Engine Technologies and Development,

Vol. 2, Diesel Engines (Woodhead, Oxford, 2010).

[169] M. Richter, Overview of advanced optical techniques and their applications to

HCCI/CAI engines, in H. Zhao (ed.), HCCI and CAI engines for the Automo-

tive Industry (Woodhead, Cambridge, 2007).

[170] L. de Francqueville, G. Bruneaux, and B. Thirouard, Soot volume fraction

measurements in a gasoline direct injection engine by combined laser induced

incandescence and laser extinction method, SAE paper 2010-01-0346 (2010).

References 361

[171] M. C. Drake, T. D. Fansler, A. S. Solomon, and A. A. Szekely, Piston fuel

ﬁlms as a source of smoke and hydrocarbon emissions from a wall-controlled

spark-ignited direct-injection engine, SAE paper 2003-01-0547 (2003).

[172] Y. Hardalupas, S. Sahu, A. M. K. P. Taylor, and K. Zarogoulidis, Simultaneous

planar measurement of droplet velocity and size with gas phase velocities in

a spray by combined ILIDS and PIV techniques, Exp. Fluids, 49, 417–434

(2010).

[173] L. Zimmer, R. Domann, Y. Hardalupas, and Y. Ikeda, Simultaneous laser

induced ﬂuorescence and Mie scattering for droplet cluster measurements,

AIAA J. 41, 2170–2178 (2003).

[174] S. Idlahcen, L. Mees, C. Roze, T. Girasole, and J.-B. Blaisot, Time gate, optical

layout, and wavelength effects on ballistic imaging, J. Opt. Soc. Ame. A 26,

1995–2004 (2009).

[175] G. Bruneaux and D. Maligne, Study of the mixing and combustion processes

of consecutive short double diesel injections, SAE paper 2009-01-1352 (2009).

[176] R. Baert, B. Somers, P. Frijters, C. Luijten, W. de Boer, Design and operation

of a high pressure, high temperature bomb for HD diesel spray diagnostics:

guidelines and results, SAE paper 2009-01-0649 (2009).

[177] C. Crua, D. A. Kennaird, and M. R. Heikal, Laser-induced incandescence study

of diesel soot formation in a rapid compression machine at elevated pressures,

Combust. Flame 135, 475–488 (2003).

[178] G. Charalampous, Y. Hardalupas, and A. M. K. P. Taylor, A novel technique

for measurements of the intact liquid jet core in a coaxial air-blast atomizer,

AIAA J. 47, 2605–2615 (2009).

[179] T. D. Fansler, M. C. Drake, B. Gajdeczko, I . D

uewel, W. Koban, F. P. Zimmer-

mann, and C. Schulz, Quantitative liquid and vapor distribution measurements

in evaporating fuel sprays using laser-induced exciplex ﬂuorescence, Meas. Sci.

Technol. 20, 125–401 (2009).

[180] C. Schulz and V. Sick, Tracer-LIF diagnostics: Quantitative measurement of fuel

concentration, temperature and fuel/air ratio in practical combustion systems

Prog. Energy Combust. Sci. 31, 75–121 (2005).

[181] R. Zhang and V. Sick, Multi-component fuel imaging in a spray-guided, spark-

ignition, direct-injection engine, SAE paper 2007-01-1826 (2007).

[182] J. D. Smith and V. Sick, Quantitative, dynamic fuel distribution measurements

in combustion-related devices using laser-induced ﬂuorescence imaging of bi-

acetyl in iso-octane, Proc. Combust. Inst. 31, 747–755 (2007).

[183] J. Nygren, J. Hult, M. Richter, M. Ald

en, M. Christensen, A. Hultqvist, and

B. Johansson, Three-dimensional laser induced ﬂuorescence of fuel distribu-

tions in an HCCI engine, Proc. Combust. Inst. 29, 679–685 (2002).

[184] D. Hoffman, K.-U. Muench, and A. Leipertz, Two-dimensional temperature

determination in sooting ﬂames by ﬁltered Rayleigh scattering, Opt. Lett. 21,

525–527 (1996).

[185] A. P. Yalin and R. B. Miles, Ultraviolet ﬁltered Rayleigh scattering temperature

measurements with a mercury ﬁlter, Opt. Lett. 24, 590–592 (1999).

[186] M. G. Loefﬂer, K. Kroeckel, P. Koch, F. Beyrau, A. Leipertz, S. Grasreiner,

and A. Heinisch, Simultaneous quantitative measurements of temperature

and residual gas ﬁelds inside a ﬁred SI-engine using acetone laser-induced

ﬂuorescence, SAE paper 2009-01-0656 (2009).

[187] M. Luong, R. Zhang, C. Schulz, and V. Sick, Toluene laser-induced ﬂuorescence

for in-cylinder temperature imaging in internal combustion engines, Appl. Phys.

B 91, 669–675 (2008).

[188] M. Yamakawa, D. Takaki, Y. Zhang, K. Nishida, and T. Li, Quantitative mea-

surement of liquid and vapor phase concentration distributions in a D.I. gaso-

line spray by the laser absorption scattering (LAS) technique, SAE paper

2002-01-1644.

362 Lean Flames in Practice

[189] R. Hasegawa, I. Sakata, H. Yanagihara, G. Saerner, M. Richter, M. Ald

en, and

B. Johansson, Two-dimensional temperature measurements in engine combus-

tion using phosphor thermometry, SAE paper 2007-01-1883 (2007).

[190] S. Hildenbrand, S. Staudacher, D. Brueggemann, F. Beyrau, M. C. Weikl,

T. Seeger, and A. Leipertz, Numerical and experimental study of the vapor-

ization cooling in gasoline direct injection sprays, Proc. Combust. Inst. 31,

3067–3073 (2007).

[191] D. A. Rothamer and J. B. Ghandhi, Determination of ﬂame-front equivalence

ratio during stratiﬁed combustion, SAE paper 2003-01-0069 (2003).

[192] J. D. Smith and V. Sick, Crank-angle resolved imaging of fuel distribution,

ignition and combustion in a direct-injection spark-ignition engine, SAE Trans.

J. Eng. 114, 1575–1585 (2005).

[193] J. D. Smith and V. Sick, High-speed fuel tracer ﬂuorescence and OH radical

chemiluminescence imaging in a spark-ignition direct-injection engine, Appl.

Opt. 44, 6682–6691 (2005).

[194] T. D. Fansler, M. C. Drake, and B. Boehm, High-speed Mie-scattering diag-

nostics for spray-guided gasoline engine development, persented at the 8th

International Symposium on Internal Combustion Diagnostics, Baden-Baden,

Germany, 2008.

[195] C. M. Fajardo and V. Sick, Flow ﬁeld assessment in a ﬁred spray-guided spark-

ignition direct-injection engine based on UV particle image velocimetry with

sub crank angle resolution, Proc. Combust. Inst. 31, 3023–3031 (2007).

[196] N. Graf, J. Gronki, C. Schulz, T. Baritaud, J. Cherel, P. Duret, and J. Lavy,

In-cylinder combustion visualization in an auto-igniting gasoline engine using

fuel tracer- and formaldehyde-LIF imaging, SAE paper 2001-01-1924 (2001).

[197] R. Collin, J. Nygren, M. Richter, M. Ald

en, L. Hildingsson, and B. Johansson,

Simultaneous OH- and formaldehyde-LIF measurements in an HCCI engine,

SAE paper 2003-01-3218 (2003).

[198] J. E. Dec, W. Hwang, and M. Sj

oberg, An investigation of thermal stratiﬁcation

in HCCI engines using chemiluminescence imaging, SAE paper 2006-01-1518

(2006).

[199] Y. Hardalupas, C. S. Panoutsos, and A. M. K. P. Taylor, Spatial resolution

of a chemiluminescence sensor for local heat release rate and air-fuel ratio

measurements in a model gas turbine combustor, Exp. Fluids 49, 888–909,

(2010).

[200] N. Kawahara, E. Tomita, K. Hayashi, M. Tabata, K. Iwai, and R. Kagawa,

Cycle-resolved measurements of the fuel concentration near a s park plug in a

rotary engine using an in situ laser absorption method, Proc. Combust. Inst. 31,

3033–3040 (2007).

[201] M. Cundy, T. Schucht, O. Thiele, and V. Sick, High-speed laser-induced ﬂuores-

cence and spark plug absorption sensor diagnostics for mixing and combustion

studies in engines, Appl. Opt. 48, B94–B104 (2009).

[202] Editorial, New York Tribune (May 11, 1899).

[203] E. Iglauer, The Ambient Air, New Yorker (April 13, 1968).

[204] Advisory Council for Aeronautics Research in Europe. Strategic research

agenda. A series of documents, sra-1 October 2002, sra-2 October 2004, the

latest of which is the 2008 addendum, available from acare4europe.org.

[205] ICAO Annex 16 – International standards and recommended practices, envi-

ronmental protection – Vol. II, aircraft engine emissions, 2nd ed. (1993) plus

amendments: Amendment 3, 20 March 1997; and amendment 4, 4 November

1999.

[206] J. E. Penner, D. H. Lister, D. J. Griggs, D. J. Dokken, M. M. (eds.), Aviation

and the global atmosphere ipcc, prepared in collaboration with the Scientiﬁc

Assessment Panel to the Montreal Protocol on Substances that Deplete the

Ozone Layer Part I (Cambridge University Press, Cambridge, 1999), p. 373.