Heinz Heinemann.  The Berkeley Years  (1978-1993)



Lawrence Berkeley National Laboratory
Lawrence Berkeley National Laboratory

Title
Heinz Heinemann.  The Berkeley Years  (1978-1993)

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Coble, Inger M.

Publication Date
2009-09-23
 
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Heinz Heinemann.  The Berkeley Years  (1978-1993) 
 
 

Gabor A. Somorjai  

 
1Department of Chemistry, University of California, Berkeley, CA 94720 

2Materials Sciences Division and Chemical Sciences Division, Lawrence Berkeley 

National Laboratory, Berkeley, CA 94720 

 
* To whom correspondence should be addressed. E-mail: somorjai@berkeley.edu. 

 
 

 

Heinz Heineman came to Berkeley in 1978 and stayed there for 15 years.   This was the 

time of the energy crisis and we did not have anybody like him who had such a 

tremendous industrial experience with oil and coal conversion technology and science.  

He was interested in the conversion of coal to gaseous molecules and our studies with 

model catalysts appealed to him and attracted him.  In a way, Heinz Heineman was 

bigger than life, since he played such a seminal role in the history of American catalysis 

science. 

 

 

 

Running title:  Heinemann.  The Berkeley Years 

Keywords:  Heinemann, catalysis



 

 

I. Introduction 

 

Catalysis sciences dates back to the 1930ies with Vladimir Ipatieff, Herman Pines, 

Eugene Houdry, Paul Emmett, Keith Hall and Hugh Taylor, who had established the 

fundamental phenomena by focusing on motor fuel production by catalytic means, the 

CO hydrogenation reactions, ammonia synthesis and some of the fundamental 

phenomena that led to the definition of active sites in heterogeneous catalysis. This 

period was followed by the industrial might of the petroleum industry, Vladimir Haensel 

of Universal Oil Products Co, Jules Rabo of Union Carbide, Otto Beeck at Shell, Paul 

Weiss at Mobile, John Sinfelt at Exxon, Tom Hughes at Chevron, and others, who 

focused on catalytic conversion of fuels to high-octane gasoline and diesel fuels.  The 

presence of a Dutch component in American catalysis science was caused by the 

relocation of much of Shell’s research from the Netherlands because of the German 

occupation, to the United States.   

 

 

II. Catalytic research of Heinemann in Berkeley 

 

Heinemann (Figure 1) was an industrial scientist in this very period.  After a long 

period of industrial research with Kellogg he moved to Mobil and retired from the 

company just before coming to Berkeley.  During this period, catalysis science performed 



so excellently in industry declined and the field moved to centers in academia, and 

Berkeley was one of them.  He employed and worked with 12 postdoctoral fellows over a 

15 year period who are maintaining their activity even at present.   

He started to work with graphite as a model carbon solid to study the catalytic 

gasification using potassium hydroxide as a catalyst[1, 2].  He found at relatively low 

temperature at 800K hydrocarbons from C1 to C6 could be formed with high efficiency as 

shown in Fig.2.  He worked on the mechanism and found that the carbon bond next to the 

OH bond of potassium hydroxide had to be broken as the rate limiting step to produce 

products of CO and hydrocarbons.  

 He found other catalysts also worked for carbon gasification at 900K using 

mixtures of potassium hydroxide and oxides of transition metals as catalysts[3].  Out of 

these transition metal mixtures, iron oxide and nickel oxide were the most efficient and 

had the highest activity.  Electron microscopy studies revealed that potassium hydroxide 

alone as a catalyst channeled into the graphite and at the end of the channel the potassium 

hydroxide dissolved the carbon, which then gasified.  When a transition metal was used, 

both edge recession and channeling into the graphite was observable.  Following the 

work with graphite as a model catalyst the steam gasification with chars was studied at 

temperatures below 1000K using a potassium oxide - calcium oxide catalyst, which 

shows superior resistance to deactivation by sulfur [4 , 5].   

 

Heinz Heinemann in the 1989-90 period turned then to the conversion of methane 

by oxydehydrogenation using catalysts such a calcium, nickel or potassium oxides at low 

temperatures, below 600 °C [5].  We found catalytic oxidative coupling of methane to 



produce C3 and C4 paraffins and olefins under these circumstances.  Oxydehydrogenation 

was the focus of his work for these remaining years in Berkeley [6-10].  He pursued that 

with mechanistic studies using oxygen isotopes to study isotope exchange to reveal the 

mechanism of oxydehydrogenation and utilized other catalysts such as ZSM-5 zeolites 

and magnesium lithium oxide catalysts, and the effect of steam [10]. 

 

Heinz Heinemann left with us a tradition of curiosity, the interest in technology and 

energy conversion, close scrutiny of experimental data and carrying out seminal studies of 

kinetics and catalyst structures to understand the fundamental ingredients of catalyst 

activity and selectivity.  He had important influence on the next generation of researchers 

and he played a significant role in the history of catalysis science. 

 

Acknowledgement  

 

This work was supported by the Director, Office of Science, Office of Advanced 

Scientific Computing Research, Office of Basic Energy Sciences, Materials Sciences and 

Engineering Division, Chemical Sciences, Geosciences, and Biosciences Division, of the 

U.S. Department of Energy under Contract No. DE-AC02-05CH11231. 

 



 
References 
 
 
[1] F. Delannay, W. T. Tysoe, H. Heinemann and G. A. Somorjai, Carbon 1984, 22, 401-
407. 
[2] F. Delannay, W. T. Tysoe, H. Heinemann and G. A. Somorjai, Applied Catalysis 
1984, 10, 111-123. 
[3] J. Carrazza, W. T. Tysoe, H. Heinemann and G. A. Somorjai, Journal of Catalysis 
1985, 96, 234-241. 
[4] P. Pereira, R. Csencsits, G. A. Somorjai and H. Heinemann, Journal of Catalysis 1990, 
123, 463-476. 
[5] P. Pereira, S. H. Lee, G. A. Somorjai and H. Heinemann, Catalysis Letters 1990, 6, 
255-262. 
 [6] J. Rasko, G. A. Somorjai and H. Heinemann, Applied Catalysis a-General 1992, 84, 
57-75. 
[7] Y. F. Chang, G. A. Somorjai and H. Heinemann, Journal of Catalysis 1993, 142, 697-
707. 
[8] Y. F. Chang, G. A. Somorjai and H. Heinemann, Journal of Catalysis 1993, 141, 713-
720. 
[9] Y. F. Chang, G. A. Somorjai and H. Heinemann, Applied Catalysis a-General 1993, 
96, 305-318. 
[10] Y. F. Chang, G. A. Somorjai and H. Heinemann, Journal of Catalysis 1995, 154, 24-
32. 
 
 



 

 
 
 

Figure 1. Heinz Heinemann 



 

 

 
 

Figure 2 Plot of dependence on reaction time of the proportion of 
hydrocarbons for a KOH/C loading equal to 0.043 (mol).  


	I. Introduction
	II. Catalytic research of Heinemann in Berkeley
	Acknowledgement
	
	[2] F. Delannay, W. T. Tysoe, H. Heinemann and G. A. Somorjai, Applied Catalysis 1984, 10, 111-123.
	[4] P. Pereira, R. Csencsits, G. A. Somorjai and H. Heinemann, Journal of Catalysis 1990, 123, 463-476.
	[6] J. Rasko, G. A. Somorjai and H. Heinemann, Applied Catalysis a-General 1992, 84, 57-75.
	[8] Y. F. Chang, G. A. Somorjai and H. Heinemann, Journal of Catalysis 1993, 141, 713-720.


	[10] Y. F. Chang, G. A. Somorjai and H. Heinemann, Journal of Catalysis 1995, 154, 24-32.