Haren Gandhi 1941–2010: Contributions to the Development and Implementation of Catalytic Emissions Control Systems

By Martyn V. Twigg

doi:10.1595/147106711X540652

ISSN: 0032-1400

oa Haren Gandhi 1941–2010: Contributions to the Development and Implementation of Catalytic Emissions Control Systems
By By Martyn V. Twigg¹
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Affiliations: ¹ Johnson Matthey PLC, Orchard LaboratoriesOrchard Road, Royston, Hertfordshire SG8 5HEUK
Source: Platinum Metals Review, Volume 55, Issue 1, Jan 2011, p. 43 - 53
DOI: https://doi.org/10.1595/147106711X540652
- Published online: 01 Jan 2011

Abstract

Throughout his long and distinguished career with the Ford Motor Company Haren Gandhi was concerned with controlling tailpipe pollutants from cars, and through his work this article reviews the huge amount of progress made during his four-decade career. His early work with gasoline engines embraced all of the major developments ranging from the first platinum-based oxidation catalysts through nitrogen oxides (NOx) reduction using platinum-rhodium catalysts and the later introduction of palladium into three-way catalysts (TWCs) via ‘trimetal’, palladium-rhodium and palladium-only formulations. Gandhi’s other work included the interactions of poisons with catalysts as part of maintaining their in-use performance, the potential for using ruthenium in NOx control in gasoline TWCs and NOx adsorbing catalysts (NACs) for lean-burn engines, and the use of zeolite-based selective catalytic reduction (SCR) catalysts for effective diesel engine NOx control. Gandhi received many awards and honours in recognition of his technical achievements and a selection is mentioned here. Haren Gandhi is remembered with tremendous fondness and respect throughout the automotive industry concerned with exhaust gas emissions control and his technical contributions towards improving the quality of the air we breathe will continue to benefit us all.

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References

M. Shelef, K. Otto, H. Gandhi, J. Catal., 1968, 12, (4), 361 [Google Scholar]
M. Shelef, K. Otto, H. Gandhi, Atmos. Environ., 1969, 3, (2), 107 [Google Scholar]
H. S. Gandhi, M. Shelef, J. Catal., 1973, 28, (1), 1 [Google Scholar]
G. J. K. Acres, B. J. Cooper, Platinum Metals Rev., 1972, 16, (3), 74 [Google Scholar]
M. Shelef, H. S. Gandhi, Ind. Eng. Chem. Prod. Res. Dev., 1972, 11, (1), 2 [Google Scholar]
M. Shelef, H. S. Gandhi, Ind. Eng. Chem. Prod. Res. Dev., 1972, 11, (4), 393 [Google Scholar]
M. Shelef, H. S. Gandhi, Ind. Eng. Chem. Prod. Res. Dev., 1974, 13, (1), 80 [Google Scholar]
H. S. Gandhi, A. G. Piken, M. Shelef, R. G. Delosh, ‘Laboratory Evaluation of Three-Way Catalysts’, SAE Technical Paper 760201, 1976 [Google Scholar]
H. S. Gandhi, A. G. Piken, H. K. Stepien, M. Shelef, R. G. Delosh, M. E. Heyde, ‘Evaluation of Three-Way Catalysts. Part II’, SAE Technical Paper 770196, 1977 [Google Scholar]
W. T. Wotring, G. H. Meguerian, H. S. Gandhi, F. D. McCuiston, A. G. Piken, ‘50,000 Mile Vehicle Road Test of Three-Way and NOx Reduction Catalyst Systems’, SAE Technical Paper 780608, 1978 [Google Scholar]
M. V. Twigg, Catal. Today, 2006, 117, (4), 407 [Google Scholar]
R. A. Dalla Betta, H. S. Gandhi, J. T. Kummer, M. Shelef, Ford Motor Co,, ‘Process for Preparing a Catalyst Based on Ruthenium’, US Patent 3,819,536; 1974 [Google Scholar]
H. S. Gandhi, J. T. Kummer, M. Shelef, Ford Motor Co,, ‘Ruthenium Catalyst System’, US Patent 3,835,069; 1974 [Google Scholar]
H. S. Gandhi, M. Shelef, H. K. Stepien, H. C. Yao, Ford Motor Co,, ‘Stabilized Rhenium Catalyst’, US Patent 4,006,102; 1977 [Google Scholar]
H. S. Gandhi, M. Shelef, H. K. Stepien, H. C. Yao, Ford Motor Co,, ‘Stabilized Rhenium Catalyst’, US Patent 4,062,808; 1977 [Google Scholar]
H. S. Gandhi, M. Shelef, Ford Motor Co,, ‘Ruthenium Catalyst System and Method of Stabilizing a Ruthenium Catalyst System’, US Patent 4,152,299; 1979 [Google Scholar]
M. Shelef, H. S. Gandhi, Platinum Metals Rev., 1974, 18, (1), 2 [Google Scholar]
H. S. Gandhi, H. K. Stepien, M. Shelef, Mater. Res. Bull., 1975, 10, (8), 837 [Google Scholar]
H. S. Gandhi, H. K. Stepien, M. Shelef, ‘Durability Testing of Stabilized Ru-Containing Catalysts’, SAE Technical Paper 750177, 1975 [Google Scholar]
N. Collins, M. Twigg, Top. Catal., 2007, 42, (1–4), 323 [Google Scholar]
J. S. Hepburn, K. S. Patel, M. G. Meneghel, H. S. Gandhi, Engelhard 3-Way Catalyst Development Team and Johnson Matthey 3-Way Catalyst Development Team,, ‘Development of Pd-only Three Way Catalyst Technology’, SAE Technical Paper 941058, 1994 [Google Scholar]
H. S. Gandhi, G. W. Graham, R. W. McCabe, J. Catal., 2003, 216, (1–2), 433 [Google Scholar]
M. V. Twigg, N. R. Collins, D. Morris, J. A. Cooper, D. R. Marvell, N. S. Will, D. Gregory, P. Tancell, ‘High Temperature Durable Three-Way Catalysts to Meet European Stage IV Emission Requirements’, SAE Technical Paper 2002-01-0351 [Google Scholar]
H. S. Gandhi, W. B. Williamson, E. M. Logothetis, J. Tabock, C. Peters, M. D. Hurley, M. Shelef, Surf. Interface Anal., 1984, 6, (4), 149 [Google Scholar]
H. S. Gandhi, K. Otto, A. G. Piken, M. Shelef, Environ. Sci. Technol., 1977, 11, (2), 170 [Google Scholar]
W. B. Williamson, J. Perry, R. L. Goss, H. S. Gandhi, R. E. Beason, ‘Catalyst Deactivation Due to Glaze Formation from Oil-Derived Phosphorus and Zinc’, SAE Technical Paper 841406, 1984 [Google Scholar]
W. B. Williamson, H. K. Stepien, W. L. H. Watkins, H. S. Gandhi, Environ. Sci. Technol., 1979, 13, (9), 1109 [Google Scholar]
K. R. Carduner, M. S. Chattha, H. S. Gandhi, J. Catal., 1988, 109, (1), 37 [Google Scholar]
D. Uy, A. E. O’Neill, L. Xu, W. H. Weber, R. W. McCabe, Appl. Catal. B: Environ., 2003, 41, (3), 269 [Google Scholar]
R. W. McCabe, D. M. DiCicco, G. Guo, C. P. Hubbard, ‘Effects of MMT^® Fuel Additive on Emission System Components: Comparison of Clear- and MMT^®-fueled Escort Vehicles from the Alliance Study’, SAE Technical Paper 2004-01-1084 [Google Scholar]
C. P. Hubbard, J. S. Hepburn, H. S. Gandhi, ‘The Effect of MMT on the OBD-II Catalyst Efficiency Monitor’, SAE Technical Paper 932855, 1993 [Google Scholar]
R. H. Hammerle, T. J. Korniski, J. E. Weir, E. Chladek, C. A. Gierczak, R. E. Chase, R. G. Hurley, ‘Effect of Mileage Accumulation on Particulate Emissions from Vehicles Using Gasoline with Methylcyclopentadienyl Manganese Tricarbonyl’, SAE Technical Paper 920731, 1992 [Google Scholar]
R. G. Hurley, L. A. Hansen, D. L. Guttridge, H. S. Gandhi, R. H. Hammerle, A. D. Matzo, ‘The Effect of Mileage on Emissions and Emission Component Durability by the Fuel Additive Methylcyclopentadienyl Manganese Tricarbonyl (MMT)’, SAE Technical Paper 920730, 1992 [Google Scholar]
R. G. Hurley, L. A. Hansen, D. L. Guttridge, H. S. Gandhi, R. H. Hammerle, A. D. Matzo, ‘The Effect on Emissions and Emission Component Durability by the Fuel Additive Methylcyclopentadienyl Manganese Tricarbonyl (MMT)’, SAE Technical Paper 912437, 1991 [Google Scholar]
R. H. Hammerle, T. J. Korniski, J. E. Weir, E. Chladek, C. A. Gierczak, R. G. Hurley, ‘Particulate Emissions from Current Model Vehicles Using Gasoline with Methylcyclopentadienyl Manganese Tricarbonyl’, SAE Technical Paper 912436, 1991 [Google Scholar]
R. G. Hurley, W. L. H. Watkins, R. C. Griffis, ‘Characterisation of Automotive Catalysts Exposed to the Fuel Additive MMT’, SAE Technical Paper 890582, 1989 [Google Scholar]
W. B. Williamson, H. S. Gandhi, E. E. Weaver, ‘Effects of Fuel Additive MMT on Contaminant Retention and Catalyst Performance’, SAE Technical Paper 821193, 1982 [Google Scholar]
J. T. Gidney, N. Sutton, M. V. Twigg, D. B. Kittelson, ‘Exhaust Inorganic Nanoparticle Emissions from Internal Combustion Engines’, in “Internal Combustion Engines: Performance, Fuel Economy and Emissions”, Proceedings of the Institution of Mechanical Engineers (IMechE) Conference, London, UK, 8th–9th December, 2009, Woodhead Publishing Ltd, Cambridge, UK, 2009, pp. 133–146 [Google Scholar]
J. T. Gidney, M. V. Twigg, D. B. Kittelson, Environ. Sci. Technol., 2010, 44, (7), 2562 [Google Scholar]
A. Elder, R. Gerlein, V. Silva, T. Feikert, L. Opanashuk, J. Carter, R. Potter, A. Maynard, Y. Ito, J. Finkelstein, G. Oberdörster, Environ. Health Perspect., 2006, 114, (8), 1172 [Google Scholar]
D. Gregory, R. A. Marshall, B. Eves, M. Dearth, J. Hepburn, M. Brogan, D. Swallow, ‘Evolution of Lean-NOx Traps on PFI and DISI Lean Burn Vehicles’, SAE Technical Paper 1999-01-3498 [Google Scholar]
Johnson Matthey Catalysts, Emission Control Technologies,, “Catalyst Handbook: The right chemistry for Tier 4”, Johnson Matthey PLC, Royston, UK, 2007, p. 8 [Google Scholar]
C. Montreuil, H. S. Gandhi, M. S. Chattha, Ford Motor Co,, ‘Catalyst for Purification of Lean-Burn Engine Exhaust Gas’, US Patent 5,155,077; 1992 [Google Scholar]
J. S. Hepburn, E. Thanasiu, W. L. H. Watkins, C. P. Hubbard, D. A. Dobson, H. S. Gandhi, Ford Global Technologies Inc,, ‘Potassium/Manganese Nitrogen Oxide Traps for Lean-burn Engine Operation’, US Patent 5,837,212; 1998 [Google Scholar]
J. S. Hepburn, E. Thanasiu, W. L. H. Watkins, C. P. Hubbard, D. A. Dobson, H. S. Gandhi, Ford Global Technologies Inc,, ‘NOx Trap with Improved Performance’, US Patent 5,750,082; 1998 [Google Scholar]
J. Li, C. Goralski Jr, W. Watkins, G. Graham, H. S. Gandhi, Ford Global Technologies LLC,, ‘Catalyst Composition for Use in a Lean NOx Trap and Method of Using’, US Patent 7,622,095; 2009 [Google Scholar]
H. S. Gandhi, J. V. Cavataio, R. H. Hammerle, Y. Cheng, Ford Global Technologies LLC,, ‘Method for the Reduction of NO_x and NH₃ Emissions’, US Patent 7,485,273; 2009 [Google Scholar]
D. Chatterjee, P. Koci, V. Schmeisser, M. Marek, M. Weibel, SAE Int. J. Fuels Lubr., 2010, 3, (1), 500 [Google Scholar]
H.-Y. Chen, E. Weigert, J. Fedeyko, J. Cox, P. Andersen, ‘Advanced Catalysts for Combined (NAC + SCR) Emission Control Systems’, SAE Technical Paper 2010-01-0302 [Google Scholar]
L. Xu, R. McCabe, M. Dearth, W. Ruona, ‘Laboratory and Vehicle Demonstration of “2nd-Generation” LNT + In-Situ SCR Diesel NOx Emission Control Systems’, SAE Technical Paper 2010-01-0305 [Google Scholar]
J. R. Theis, J. Ura, R. McCabe, ‘The Effects of Sulfur Poisoning and Desulfation Temperature on the NOx Conversion of LNT+SCR Systems for Diesel Applications’, SAE Technical Paper 2010-01-0300 [Google Scholar]
P. G. Blakeman, A. F. Chiffey, P. R. Phillips, M. V. Twigg, A. P. Walker, ‘Developments in Diesel Emission Aftertreatment Technology’, SAE Technical Paper 2003-01-3753 [Google Scholar]
M. V. Twigg, P. R. Phillips, Platinum Metals Rev., 2009, 53, (1), 27 [Google Scholar]
M. V. Twigg, ‘Controlling Diesel Exhaust Particulate Emissions’, The Chemical Engineer, March 2007, No. 789, pp. 28–31 [Google Scholar]
M. V. Twigg, ‘Compact Diesel Filters’, Ingenia, March 2009, (38), pp. 35–39 [Google Scholar]
L. J. Gill, P. G. Blakeman, M. V. Twigg, A. P. Walker, Top. Catal., 2004, 28, (1–4), 157 [Google Scholar]
H. S. Gandhi, C. Lambert, R. W. McCabe, B. Carberry, ‘Recent Advances in Diesel Emission Control Technology’, Symposium on International Automotive Technology (SIAT), Pune, India, 21st–23rd January, 2009 [Google Scholar]

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Haren Gandhi 1941–2010: Contributions to the Development and Implementation of Catalytic Emissions Control Systems

Platinum Metals Review 55, 43 (2011); https://doi.org/10.1595/147106711X540652

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Article Type: Research Article

oa Haren Gandhi 1941–2010: Contributions to the Development and Implementation of Catalytic Emissions Control Systems

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