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Research, innovation and renewal in the chemical industry
170
RESEARCH, INNOVATION AND RENEWAL IN THE CHEMICAL INDUSTRY Umberto
Colombo
This article appraises the prospective for the European chemical industry at a time of economic crisis when forecast rates of economic growth for the next two decades are continuing to decline. Through an examination of key issues in the chemical industry-its changing geography, industrial redeployment, the change from a product chemistry to a function chemistry, and the role of microelectronicsattention is drawn to the problems of scientific and technological innovation and its consequences for industry and society. future studies;Europe;chemical
Keywords:
industry.
within the context of the work of an expert group of the OECD asked to the Technical and Politico-Economic Change report,’ I presented my
IN 1976, prepare
perspectives
on the evolution
industry-which
of a highly
in the 20th century,
innovative
and more
industry-the
specifically
chemical
immediately
after
World War II, was considered to be one of the pace-setters in industry. The group of experts was worried about the potential link between the economic recession of the 197Os, heightened by the 1973 energy crisis, and the noticeable drop in innovation rates in various industrial sectors which, in the previous decades, had been the main economic drivers of modern industrial societies. Indeed, for a wide range of related reasons, sectors such as the steel industry, the shipbuilding industry, the automobile industry, the petrochemical industry and the textile industry, which in the past had created a considerable number ofjobs, were in a state of crisis which was threatening to lead to large job losses. Moreover, the industrial sector which could contribute, more than any other, to overall technological innovation in the next lo-20 years, ie microUmberto
Colombo
Research
and
Energy
and
Development Nazionale
is former
Strategic New
Energies
Committee Idrocarburr
Director
Planning
of the
(ENEA). (CERD)
(ENI).
0016-3287/86/020170-08$03.000
Donegani
at Montedison.
The
Mr and F rench
He Colombo
was
Research
is now is
appointed
version
of this
Institute,
President also
by
President the
article
became
of the
Italian appeared
1986 Butterworth & Co(Publishers)
Italian
of
the
Government
General Commission
European as
Manager for Research
President
in ZG~‘ulurtbles, November
Ltd
of
Nuclear and of
Enti
1982.
FUTURES April 1988
Rcwarch,
electronic
information
of industrial
processes,
technology, which
innovation
was enabling
could
worsen
and renewal tn the chemical industy
automation
the already
171
(even robotization)
serious
unemployment
problem. These concerns were justified. However, the link between microeconomic effects (stagnation, inflation, unemployment) the
innovative
capacity
of industry,
together
innovation (from job-creating innovation unconvincing and too superficial. I worked
for a long period
and then as a research and strategic
planning
the
research
chemical
company
character
innovation),
field,
I was also lucky enough
of a major
changed
to job-destroying
in the industrial
manager.
with
the most obvious and the drop in of
seemed
first as a researcher
to manage
for several
the research years.
All this
convinced me that the innovation potential of chemical research was still very high and that we were about to witness technological changes so drastic that structural transformations would were thought to be mature, and major surprises. As my contribution
to the report
be required in the industrial sectors which which therefore promised a future with no prepared
by the OECD
group
of experts,
I
was encouraged to prepare a text initially distributed in 1976-77 within the OECD, and subsequently published in Research Policy’ with some minor amendments. In this survey, by using the chemical industry as an example, I wanted to illustrate the extreme its continuous interdependency
complexity of the innovation process as well as with economic, technological and social
constraints, and with those constraints linked to the environment that industry has to accept and which it has sometimes been able to transform into more favourable
situations.
The article in Research Policy aroused the interest of European researchers in some of the ideas put forward, and was mentioned several times in the Beta Report on Prospectives for the Chemical Industry in Europe.” When reading it, one should keep in mind why it was written in the first place and by reference to the context of my previous work. In a study jointly carried out with Giuseppe
Lanzavecchia,4
I mentioned
the
limitations of economies of scale as regards the selection of optimum dimensions for chemical plants, and rejected the then unquestioned conventional wisdom that bigger and bigger plants had to be built. This was in the early time, many people were full of admiration for the ‘ultimate plant’
1970s. At the concept, ie a
plant designed to manufacture a given chemical product-for instance, an intermediate petrochemical product such as terephthalic acid. This plant would be so big and the unit cost of production so low that it would deter any competitor from entering the market controlled by whoever had the strength, technology, means and courage to build this ‘ultimate plant’ (in the above mentioned example of terephthalic acid, the duPont Company). In another survey, 5 I studied the position of the chemical industry in the context of the energy crisis. I also advised the petrochemical industry to carry on using oil as a raw material for a long time; I also underlined the fact that, conversely, it was not very logical to use this raw material in applications less important than transportation and petrochemicals. This was not only because of economic reasons but also because of the complex molecular structure of oil. Finally, in a survey presented to the Society of Chemical Industry in 1975,6 I
FUTURES April 1986
172
Research,
spoke
innouatum and renewal in the chemical industry
about
the geographical
decentralization
of large
petrochemical
plants
to
the oil-producing countries and also indicated the terms, types of products and objectives which, somehow, would make this decentralization not only acceptable but also desirable from the European chemical industry viewpoint, within the framework of an ever increasing geopolitical areasin this case, between
interdependence Europe
and
North African hydrocarbon-producing countries. The second oil shock, which culminated in the removal of Iran,
and in events
the chemical
which brought
industry
the factor
upheavals
which
the
between
the main
Middle
East
and
from office of the Shah
in Iran and then in Iraq,
had the most obvious
was for
and outstanding
impact in the past few years. Oil prices had slightly decreased in real terms after the large rise of 1973-74, but they once more suddenly increased provoking an economic
recession
from that of 1975. Western industrial
which was both hard to solve and structurally Indeed, the economic difficulties countries but also the industrial
very different
have not only affected countries of Comecon
most and
most developing countries, including a large number of OPEC members (deeply affected by the reduction in international demand for crude oil, at a time when ambitious and very costly programmes for economic development and accelerated
industrialization
were
underway).
We
try
here
to
appraise
prospectives for the European chemical industry in this crisis period where the rates of economic growth forecasted by experts for the next ten or 20 years have dropped scientific
to lower and lower levels. We pav due attention and technological innovation and’its consequences
to the problem of for industry and
society.
A changing
geography
should first be noted that the ‘delocalization’ process of productive investments in the petrochemical industry, in favour of oil-producing countries, is occurring, even if it is slower than the more optimistic forecasts of a few years
It
ago. For instance, in 1982, some petrochemical companies began building, in conjunction with the Saudi government, petrochemical plants in Saudi Arabia. These plants have an overall capacity of 1.6 million tons/year for ethylene and approximately 3.5 million tons/year of basic petrochemical products including some
I million
tons per annum
of polyolefine-based
plastics.
In a recent survey, ’ Robert Stobaugh identified a link between the degree of maturity of various products and the variable production technologies, and the tendency towards locating ‘commodity-type’ petrochemical products in oilproducing countries. According to Stobaugh, this delocalization of production will occur through the building of large plants at economic production costs, as well as by a strategy of the worldwide marketing of products obtained through joint ventures (in countries such as Saudi Arabia); however, this delocalization also implies that the oil producer will be the sole owner of these plants and that the industrial countries will have to offer their technology-in design, plant construction and cooperation contracts-for the sale overseas of selected products. However, the delocalization of production processes to the oilexporting countries is a slow process, and follows, in terms of the timescale involved, what occurred in the Comecon area, Canada and other regions.
FUTURES April 1986
Research, innovation
The about
turnover 30%
of the European
chemical
of total world turnover)
and renewal m the chemical industry
industry
is forecast
(which
to decrease
173
in 1980 represented
in percentage
terms
to
about 26% by 1990; a similar variation is forecast for Japanese industry (from 13.5 % to 12.5 %). The North American chemical industry should be able to contain the decrease in its share from 29% in 1980 to 28% in 1990.8 Indeed, although the Canadian contribution will increase, the USA will still retain a residual advantage over Europe, materials, crude oil and gas.
because
In the USA, even more than in Europe, of chemical companies is still occurring CONOCO $8 billion, industry
of lower
than
average
costs
for raw
the vertical upstream concentration (on this subject, the purchase of
by duPont is a good example-this resulted in a transaction of about which is probably the largest repurchase of all time). The metals (eg US Steel,
Kaiser
Aluminium,
Alcoa)
is also gradually
moving
into
the petrochemical industry, in particular into plastics; this strategy is linked in some way to the idea that the industry is moving from a product industry to a function industry. in the automobile
For instance, and building
forecasts industries
ofa large increase in the use ofplastics did certainly force the traditional steel
and non-ferrous metal suppliers to move into these market sectors in order to supply also synthetic products, based on petrochemical materials, which could but with a decrease in weight and with carry out the same functions, considerable
energy
savings.
Japan is directing its production (for instance, foodstuffs pharmaceuticals, biotechnologies). of investment
chemical
Simultaneously in chemicals
industry
towards
it is about to become and in chemical industry overseas
the Japanese
companies
in order both to reduce
which has created excessive bottlenecks and serious increase interdependency links with oil-producing supplying other raw materials, as well as with sophisticated Industrial
Japanese
industrial
more
sophisticated
very powerful branches related are enforcing domestic
in to
a policy
production
pollution problems, and to countries and countries potential buyers of more
products.
redeployment
The European chemical producers, a production
industry has, in the petrochemicals sector, too many overcapacity estimated at between 25% and 30% of the
overall market, and an unfavourable cost profile (raw materials, manpower) with respect to the major competitive regions. Some large European companies are especially strong in the field of fine and specialized chemistry and have already initiated a rationalization and reorganization process for petrochemical production in order to reduce costs (including measures for substantially increasing energy efficiency) and to improve the quality of their products (thanks to improved research), but other companies are still facing serious difficulties. In particular, in France and Italy, a massive rationalization is beginning in the mainstream chemical industry-most of it is now owned by the state. The outcome of this process is employment implications at a time and more mobility are required in various geopolitical regions is bound
FUTURES April 1986
unclear: considerable constraints exist, eg when brave decisions, a long-term vision a world where interdependence between to increase.
174
Research, znnouation and renewal in the chmical
industry
In ten years, the oil price has risen by a factor of almost ten on the international market (if we take into account the inflation rate, we can say that the crude oil price has risen by a factor of five or six), but this does not seem noticeably to have encouraged people to abandon crude oil in favour of other raw materials in mainstream organic chemistry. This phenomenon can only be understood by realizing that the major intermediate petrochemical products contain carbon and hydrogen in a ratio not far from that found in fractionated oil used as a raw material. Further, oil can be transformed into basic intermediate products (eg ethylene, propylene), through a reduced number of operations which have become economically very profitable. This is why, out of a total world production about
of some
95 % have been obtained
120 million
through
tons/year
fractionated
of organic
compounds,
oil and natural
gas.
Oil or coal? The eventual replacement of oil by coal requires enormous investment and implies an important loss of raw materials to produce the basic intermediate products
(synthetic
oil or Synfuel)
required
to obtain
petrochemical
However, I am sure that the use of coal as a petrochemical raw material become profitable when the liquefaction and gasification processes themselves intended
become
profitable,
for the synfuel
ie complestely
and gas thus obtained.
independent
products. will only for coal
from the types of use
In other words,
its use in petro-
chemicals will not make coal profitable in this regard, but the price differential between oil and coal will, at a given point, be such that coal could profitably be converted
into gasified
products
and synfuel,
which,
in turn,
will find applica-
tions in the petrochemical sector. In this way it is possible to understand why the major petrochemical companies have been trying hard in the past few years to improve the energy content of actual technological processes, by introducing, wherever possible, modifications to their plants, provided those modifications can offer short payback periods; these modifications are always based on oil, but use all kinds of tricks to optimize the energy content. The energy consumption of basic processes
such as vapour
cracking,
A trend is beginning chemistry. This compound
for instance
has been reduced
by 40 % -50 % .
to be noticeable: the development of methanol can be derived from gas or coal and is interesting
more for its general energy vector than for its specific petrochemical potential. It is well known that methanol can be turned into acetic acid by carbonylation. Acetic acid is a major intermediate compound in the production of vinylic resins and other products. This process was developed a few years ago by the Monsanto company, and is likely to become obsolete because two other methods designed by the Eastman and Halcon companies can produce vinyl acetate from methanol via catalytic reactions, without having to produce the intermediate compound, ie acetic acid. Further, methanol can be selectively changed into ethylene by cracking with zeolitic catalysts or into approved methanol; the latter product can be changed into ethylene by catalytic dehydration and could then be a substitute for natural gas and for ‘virgin’ naphta, as a raw material in ethylene chemistry. We are slowly and carefully moving to a methanol chemistry which could become, in the medium term, one of the most important sources of future organic chemistry. FUTURES April 1966
Research, innovation and renewal in the chemical tnduslry
Function In
my
17.5
chemistry
article
in Research
Policy I emphasized
certain
trends
that
I found
significant. One of them was a transfer in innovation evolution from a ‘product chemistry’ to a ‘function chemistry’. As M. Bohy” correctly stated, this evolution is not really new. In the 19th century, once the sense of wonder born of the realization that man could synthesize an increasing number of new chemical compounds for an ever-increasing number of applications, finally disappeared, the emphasis gradually moved to the function that one product or another could fulfil. Today, for instance, to speak of dyes in broad terms is meaningless if the fabric,
the
cloth
or material
technological process The major plastic characterized characteristics,
to be dyed
is not
mentioned
applied for this dye is not specified. materials which have become actual
by composition and physical, adequately standardized-have
mechanical increasingly
and
even
if the
‘commodities’and miscellaneous diversified within
and thanks to this evolution, today there are the major polymer families, plastics which are designed and manufactured for specific purposes (packaging, tubes, laminates, etc); there are also composite greenhouses, crop covers, materials properties fibres,
in which plastics provide such as tensile strength
metal
fibres
or carbon
the support and in which specific mechanical and shock absorption are provided by glass
fibres,
and
from those of the matrix compound. Clearly we are currently in the middle
even
polymer
of ‘function
compounds chemistry’:
different if this was
then what is new in the tendency I describe to draw to the already known, attention of experts and futurists? We can give numerous examples of this chemistry, such as nitrogen-based fertilizers
replaced
by a direct
nitrogen
fixation
in the roots of plants
and cereals
(wherever possible through DNA rearrangement processes); or biological warfare against noxious insects instead of using chemical insecticides. Such examples show that the transfer from product chemistry to a function chemistry can even lead to a complete extinction of one product. This ‘dematerializing’ innovation requires, in order to be used effectively, a deep transformation in the structure of economic activities in which this innovation is based (in this case, agricultural production) as well as new industries and related services. It is true that biotechnologies completely industry; upstream extremely
will play a part in the deep-seated
innovations
which
will
transform one of the most traditional sectors of the chemical it is also clear that the development of biotechnologies requires chemical research which is properly subdivided, thorough and dedicated. For instance, fixation of atmospheric nitrogen could be
achieved in the roots of one cereal through genetic engineering techniques capable of achieving a symbiosis between the plant roots and their nitrogensettling micro-organism (for instance Rhizobium) as is now the case with leguminous plants. This objective is not easy to attain, a whole series of problems will have to be solved, and a whole range of biochemical, chemical and physical research carried out. One of the problems concerns energy. To obtain a chemical transformation of atmospheric nitrogen into a nitrogen molecule useful to the plant, this plant will have to supply the energy required for this reaction through processes related to chlorophyllian photosynthesis. This energy
FUTURES April 1966
176
Research, innooatm and renewal in the chemical industry
absorption
through
nitrogen
fixation
would be obtained
to the detriment
of the
plant’s growth rate and would therefore reduce agricultural yield unless photosynthesis efficiency could somehow be improved. In other words, the energy we consume today as methylene or petrol to produce ammonia (and from this nitrogen-based fertilizers, in large chemical plants) could be obtained by using solar power available at the field without interfering with provided that the combined objectives of fixation of atmospheric increased
efficiency
Microelectronics
of plant
photosynthesis
could
plant growth, nitrogen and
be met.
in chemistry
Microelectronics
is another
research and the latest information technology,
example
technology, with the
of the
interaction
between
mechanical
with synergistic effects. Developments in arrival of new generations of computers,
require extensive research in solid-state chemistry and physics to produce the basic materials (silicon, semi-conductors, gallium arsenide compounds, magnetic bubbles, etc) as well as miniaturization technologies. This dependence of microelectronics on research in chemistry and materials science is counterbalanced by the increasing use of computers in chemical research. Indeed, in pharmaceuticals, phytopharmacy, dyes, aromas, etc, the traditional ‘random synthesis and screening’ system of new active organic products (which is becoming increasingly costly because of the enormous number of molecules that have to be synthesized before finding one with the required properties, without negative side-effects) will necessarily be replaced, for the most part, by synthesis theoretical chemical,
methods
with specific objectives. Thanks to computations in the correlation between molecular structure and chemistry, biochemical, etc properties, will be understood in the physical,
minutest detail. The discovery of new organic products various sectors of relined chemistry, through optimization through computer-guided synthesis (‘lead These examples of complex interactions chemistry and research in other scientific
could thus occur in processes and even
optimization’ and ‘lead generation’). between research and innovation in sectors and industrial activities, only
give a vague idea of the type of structural change which will occur in this industry. In other words, the tendency is to break up the chemical industry, to split it up into sub-sectors which are increasingly closely linked to the solution of specific problems (or to the answer to given demands) and to rearrange it into new industries born from an interdisciplinary conception of the contribution of integrated either horizontally (eg US companies in the mnovation, metallurgical sector) or vertically (eg the integration between energy and raw materials-petrochemical and synthetic derivatives). This massive innovation process-which affects science and technology as well as industrial structures and services-should create many jobs, but certainly not traditional ones. It is forecast that research centres will be dedicated to finding solutions to increasingly important problems (here, for instance, I am thinking about the shortage in soft water foreseeable in only a few decades, and the need to purify and desalinate recycled and sea water). New services will have to be created to offer technological assistance to agriculture, to fight corrosion and to prevent
illnesses.
All these
activities,
and others
related
to the design
of
FUTURES April 1966
Kesrarch, mnoua!ion and renewal in the chenncal industry
new software
and to the computing
wider basis for research, will most probably
requirements
of chemistry
as well as for computer-aided
employ
technicians
and specialists
design
on a wider
177
and
and manufacture,
in greater
numbers
than
the number of jobs lost through increasing automation and robotization. In conclusion, it can be stated that the evolutionary prospective in chemistry rich in deep-rooted
and significant
innovations.
The
chemical
industry,
is
as we
have been used to saying from its birth until today, now opens up fields which are so wide that no common denominator with a strong enough base can bc found. Literally, the ‘chemical’ industry is no longer required. It will tend to dissolve markets
and and
to rebuild itself around fields of activities, problems, explicit societal demands. During this process, it will combine with
industries which, traditionally, were buying its products or, conversely, were supplying it with raw materials. This does not necessarily mean that the major chemical companies-which are now some of the largest companies in the world-will disappear. They will continue to exist, but they will increasingly resemble f‘actors,
industrial
conglomerates
and will no longer
intersectoral
held together
be uni-strategy
by financial
companies.
They
and organizational will manifest
strong
synergy.
Chemical research has still to reap a rich harvest in innovations that will be fertilized by research carried out in disciplines such as physics, biology and new information technologies. All this is bound to happen; however, this statement applies process
in a thermodynamic sense, if I can use that term. However the kinetic If the positive aspects of deep is nonetheless extremely uncertain.
structural innovation receive some understanding, and ifthis process is assisted, the transition will be shorter and less arduous than if, on the contrary, the flexibility requirements encounter mistrust and if the unavoidable changes were to have traumatic effects on an excessively rigid and sclerotic industrial and sociopolitical system.
Notes and references 1. B. Delapalme et al, Changement Noour cau Contexfe Economiqur
Technique
OECD, on innovation
the nrw Econorntc and Social Context),
2.
U. Colombo, 1980,
3.
[‘“$yS
P. Cohendet
“A viewpoint X14-23
et Politique Economique:
et Social ( i’khnical
and Politro-economic
1980. and the chemical
la Science et la Technologie dam le Change. Science and 7 bchnolo,/y in
industry”,
h’esearrh Po/ic_y, 9 (t?).
1.
et al, Les Perspectives de la Chimie en Europe (Perspectiues for the European Chemical of’ European Report prrparcd fbr thtt FAST P.10bTrLunrrre of thr Commission
Indu.\r~y) BETA
4. 5
Communities. U. Colombo and G. Lanzavecchia, “Criteri di scelta della potenzialitk degli impianti chimici”, Iq chim Ital, 9 (2) 1973 pages 22-30. U. Colombo, “Is oil too valuable to burn”, paper presented at the World Petrochemicals Conference organized by the Financial 7’imo and 011 Da+, in Lu Chlmita P I’lndurtrin, 6, 197.5, pages 395-401. ChrG/ry (2nd Indn~/rp, u. Cololnbo. “Geopolitical inllurnce on invrstmcnt strategy”. December 1975, pages 994-998. R. Stobaugh, “11 ciclo di vita del prodotto, i flussi tecnologi internationali e il settore pctrolchimico”, industria Chimica, Supplement0 de1 No 1, 1982, pages 20-28. Estimatr from the Stanford Research Institutr (SRI International), 1981. (“Pcrsprctives on Europcarr “10 pvrspcctivcs dr la chimiv cn Europe” M. Bohy, chemistry”). Scrims FAST-EEC. No. 2, 1982.
FUTURES April 1966
RESEARCH, INNOVATION AND RENEWAL IN THE CHEMICAL INDUSTRY Umberto
Colombo
This article appraises the prospective for the European chemical industry at a time of economic crisis when forecast rates of economic growth for the next two decades are continuing to decline. Through an examination of key issues in the chemical industry-its changing geography, industrial redeployment, the change from a product chemistry to a function chemistry, and the role of microelectronicsattention is drawn to the problems of scientific and technological innovation and its consequences for industry and society. future studies;Europe;chemical
Keywords:
industry.
within the context of the work of an expert group of the OECD asked to the Technical and Politico-Economic Change report,’ I presented my
IN 1976, prepare
perspectives
on the evolution
industry-which
of a highly
in the 20th century,
innovative
and more
industry-the
specifically
chemical
immediately
after
World War II, was considered to be one of the pace-setters in industry. The group of experts was worried about the potential link between the economic recession of the 197Os, heightened by the 1973 energy crisis, and the noticeable drop in innovation rates in various industrial sectors which, in the previous decades, had been the main economic drivers of modern industrial societies. Indeed, for a wide range of related reasons, sectors such as the steel industry, the shipbuilding industry, the automobile industry, the petrochemical industry and the textile industry, which in the past had created a considerable number ofjobs, were in a state of crisis which was threatening to lead to large job losses. Moreover, the industrial sector which could contribute, more than any other, to overall technological innovation in the next lo-20 years, ie microUmberto
Colombo
Research
and
Energy
and
Development Nazionale
is former
Strategic New
Energies
Committee Idrocarburr
Director
Planning
of the
(ENEA). (CERD)
(ENI).
0016-3287/86/020170-08$03.000
Donegani
at Montedison.
The
Mr and F rench
He Colombo
was
Research
is now is
appointed
version
of this
Institute,
President also
by
President the
article
became
of the
Italian appeared
1986 Butterworth & Co(Publishers)
Italian
of
the
Government
General Commission
European as
Manager for Research
President
in ZG~‘ulurtbles, November
Ltd
of
Nuclear and of
Enti
1982.
FUTURES April 1988
Rcwarch,
electronic
information
of industrial
processes,
technology, which
innovation
was enabling
could
worsen
and renewal tn the chemical industy
automation
the already
171
(even robotization)
serious
unemployment
problem. These concerns were justified. However, the link between microeconomic effects (stagnation, inflation, unemployment) the
innovative
capacity
of industry,
together
innovation (from job-creating innovation unconvincing and too superficial. I worked
for a long period
and then as a research and strategic
planning
the
research
chemical
company
character
innovation),
field,
I was also lucky enough
of a major
changed
to job-destroying
in the industrial
manager.
with
the most obvious and the drop in of
seemed
first as a researcher
to manage
for several
the research years.
All this
convinced me that the innovation potential of chemical research was still very high and that we were about to witness technological changes so drastic that structural transformations would were thought to be mature, and major surprises. As my contribution
to the report
be required in the industrial sectors which which therefore promised a future with no prepared
by the OECD
group
of experts,
I
was encouraged to prepare a text initially distributed in 1976-77 within the OECD, and subsequently published in Research Policy’ with some minor amendments. In this survey, by using the chemical industry as an example, I wanted to illustrate the extreme its continuous interdependency
complexity of the innovation process as well as with economic, technological and social
constraints, and with those constraints linked to the environment that industry has to accept and which it has sometimes been able to transform into more favourable
situations.
The article in Research Policy aroused the interest of European researchers in some of the ideas put forward, and was mentioned several times in the Beta Report on Prospectives for the Chemical Industry in Europe.” When reading it, one should keep in mind why it was written in the first place and by reference to the context of my previous work. In a study jointly carried out with Giuseppe
Lanzavecchia,4
I mentioned
the
limitations of economies of scale as regards the selection of optimum dimensions for chemical plants, and rejected the then unquestioned conventional wisdom that bigger and bigger plants had to be built. This was in the early time, many people were full of admiration for the ‘ultimate plant’
1970s. At the concept, ie a
plant designed to manufacture a given chemical product-for instance, an intermediate petrochemical product such as terephthalic acid. This plant would be so big and the unit cost of production so low that it would deter any competitor from entering the market controlled by whoever had the strength, technology, means and courage to build this ‘ultimate plant’ (in the above mentioned example of terephthalic acid, the duPont Company). In another survey, 5 I studied the position of the chemical industry in the context of the energy crisis. I also advised the petrochemical industry to carry on using oil as a raw material for a long time; I also underlined the fact that, conversely, it was not very logical to use this raw material in applications less important than transportation and petrochemicals. This was not only because of economic reasons but also because of the complex molecular structure of oil. Finally, in a survey presented to the Society of Chemical Industry in 1975,6 I
FUTURES April 1986
172
Research,
spoke
innouatum and renewal in the chemical industry
about
the geographical
decentralization
of large
petrochemical
plants
to
the oil-producing countries and also indicated the terms, types of products and objectives which, somehow, would make this decentralization not only acceptable but also desirable from the European chemical industry viewpoint, within the framework of an ever increasing geopolitical areasin this case, between
interdependence Europe
and
North African hydrocarbon-producing countries. The second oil shock, which culminated in the removal of Iran,
and in events
the chemical
which brought
industry
the factor
upheavals
which
the
between
the main
Middle
East
and
from office of the Shah
in Iran and then in Iraq,
had the most obvious
was for
and outstanding
impact in the past few years. Oil prices had slightly decreased in real terms after the large rise of 1973-74, but they once more suddenly increased provoking an economic
recession
from that of 1975. Western industrial
which was both hard to solve and structurally Indeed, the economic difficulties countries but also the industrial
very different
have not only affected countries of Comecon
most and
most developing countries, including a large number of OPEC members (deeply affected by the reduction in international demand for crude oil, at a time when ambitious and very costly programmes for economic development and accelerated
industrialization
were
underway).
We
try
here
to
appraise
prospectives for the European chemical industry in this crisis period where the rates of economic growth forecasted by experts for the next ten or 20 years have dropped scientific
to lower and lower levels. We pav due attention and technological innovation and’its consequences
to the problem of for industry and
society.
A changing
geography
should first be noted that the ‘delocalization’ process of productive investments in the petrochemical industry, in favour of oil-producing countries, is occurring, even if it is slower than the more optimistic forecasts of a few years
It
ago. For instance, in 1982, some petrochemical companies began building, in conjunction with the Saudi government, petrochemical plants in Saudi Arabia. These plants have an overall capacity of 1.6 million tons/year for ethylene and approximately 3.5 million tons/year of basic petrochemical products including some
I million
tons per annum
of polyolefine-based
plastics.
In a recent survey, ’ Robert Stobaugh identified a link between the degree of maturity of various products and the variable production technologies, and the tendency towards locating ‘commodity-type’ petrochemical products in oilproducing countries. According to Stobaugh, this delocalization of production will occur through the building of large plants at economic production costs, as well as by a strategy of the worldwide marketing of products obtained through joint ventures (in countries such as Saudi Arabia); however, this delocalization also implies that the oil producer will be the sole owner of these plants and that the industrial countries will have to offer their technology-in design, plant construction and cooperation contracts-for the sale overseas of selected products. However, the delocalization of production processes to the oilexporting countries is a slow process, and follows, in terms of the timescale involved, what occurred in the Comecon area, Canada and other regions.
FUTURES April 1986
Research, innovation
The about
turnover 30%
of the European
chemical
of total world turnover)
and renewal m the chemical industry
industry
is forecast
(which
to decrease
173
in 1980 represented
in percentage
terms
to
about 26% by 1990; a similar variation is forecast for Japanese industry (from 13.5 % to 12.5 %). The North American chemical industry should be able to contain the decrease in its share from 29% in 1980 to 28% in 1990.8 Indeed, although the Canadian contribution will increase, the USA will still retain a residual advantage over Europe, materials, crude oil and gas.
because
In the USA, even more than in Europe, of chemical companies is still occurring CONOCO $8 billion, industry
of lower
than
average
costs
for raw
the vertical upstream concentration (on this subject, the purchase of
by duPont is a good example-this resulted in a transaction of about which is probably the largest repurchase of all time). The metals (eg US Steel,
Kaiser
Aluminium,
Alcoa)
is also gradually
moving
into
the petrochemical industry, in particular into plastics; this strategy is linked in some way to the idea that the industry is moving from a product industry to a function industry. in the automobile
For instance, and building
forecasts industries
ofa large increase in the use ofplastics did certainly force the traditional steel
and non-ferrous metal suppliers to move into these market sectors in order to supply also synthetic products, based on petrochemical materials, which could but with a decrease in weight and with carry out the same functions, considerable
energy
savings.
Japan is directing its production (for instance, foodstuffs pharmaceuticals, biotechnologies). of investment
chemical
Simultaneously in chemicals
industry
towards
it is about to become and in chemical industry overseas
the Japanese
companies
in order both to reduce
which has created excessive bottlenecks and serious increase interdependency links with oil-producing supplying other raw materials, as well as with sophisticated Industrial
Japanese
industrial
more
sophisticated
very powerful branches related are enforcing domestic
in to
a policy
production
pollution problems, and to countries and countries potential buyers of more
products.
redeployment
The European chemical producers, a production
industry has, in the petrochemicals sector, too many overcapacity estimated at between 25% and 30% of the
overall market, and an unfavourable cost profile (raw materials, manpower) with respect to the major competitive regions. Some large European companies are especially strong in the field of fine and specialized chemistry and have already initiated a rationalization and reorganization process for petrochemical production in order to reduce costs (including measures for substantially increasing energy efficiency) and to improve the quality of their products (thanks to improved research), but other companies are still facing serious difficulties. In particular, in France and Italy, a massive rationalization is beginning in the mainstream chemical industry-most of it is now owned by the state. The outcome of this process is employment implications at a time and more mobility are required in various geopolitical regions is bound
FUTURES April 1986
unclear: considerable constraints exist, eg when brave decisions, a long-term vision a world where interdependence between to increase.
174
Research, znnouation and renewal in the chmical
industry
In ten years, the oil price has risen by a factor of almost ten on the international market (if we take into account the inflation rate, we can say that the crude oil price has risen by a factor of five or six), but this does not seem noticeably to have encouraged people to abandon crude oil in favour of other raw materials in mainstream organic chemistry. This phenomenon can only be understood by realizing that the major intermediate petrochemical products contain carbon and hydrogen in a ratio not far from that found in fractionated oil used as a raw material. Further, oil can be transformed into basic intermediate products (eg ethylene, propylene), through a reduced number of operations which have become economically very profitable. This is why, out of a total world production about
of some
95 % have been obtained
120 million
through
tons/year
fractionated
of organic
compounds,
oil and natural
gas.
Oil or coal? The eventual replacement of oil by coal requires enormous investment and implies an important loss of raw materials to produce the basic intermediate products
(synthetic
oil or Synfuel)
required
to obtain
petrochemical
However, I am sure that the use of coal as a petrochemical raw material become profitable when the liquefaction and gasification processes themselves intended
become
profitable,
for the synfuel
ie complestely
and gas thus obtained.
independent
products. will only for coal
from the types of use
In other words,
its use in petro-
chemicals will not make coal profitable in this regard, but the price differential between oil and coal will, at a given point, be such that coal could profitably be converted
into gasified
products
and synfuel,
which,
in turn,
will find applica-
tions in the petrochemical sector. In this way it is possible to understand why the major petrochemical companies have been trying hard in the past few years to improve the energy content of actual technological processes, by introducing, wherever possible, modifications to their plants, provided those modifications can offer short payback periods; these modifications are always based on oil, but use all kinds of tricks to optimize the energy content. The energy consumption of basic processes
such as vapour
cracking,
A trend is beginning chemistry. This compound
for instance
has been reduced
by 40 % -50 % .
to be noticeable: the development of methanol can be derived from gas or coal and is interesting
more for its general energy vector than for its specific petrochemical potential. It is well known that methanol can be turned into acetic acid by carbonylation. Acetic acid is a major intermediate compound in the production of vinylic resins and other products. This process was developed a few years ago by the Monsanto company, and is likely to become obsolete because two other methods designed by the Eastman and Halcon companies can produce vinyl acetate from methanol via catalytic reactions, without having to produce the intermediate compound, ie acetic acid. Further, methanol can be selectively changed into ethylene by cracking with zeolitic catalysts or into approved methanol; the latter product can be changed into ethylene by catalytic dehydration and could then be a substitute for natural gas and for ‘virgin’ naphta, as a raw material in ethylene chemistry. We are slowly and carefully moving to a methanol chemistry which could become, in the medium term, one of the most important sources of future organic chemistry. FUTURES April 1966
Research, innovation and renewal in the chemical tnduslry
Function In
my
17.5
chemistry
article
in Research
Policy I emphasized
certain
trends
that
I found
significant. One of them was a transfer in innovation evolution from a ‘product chemistry’ to a ‘function chemistry’. As M. Bohy” correctly stated, this evolution is not really new. In the 19th century, once the sense of wonder born of the realization that man could synthesize an increasing number of new chemical compounds for an ever-increasing number of applications, finally disappeared, the emphasis gradually moved to the function that one product or another could fulfil. Today, for instance, to speak of dyes in broad terms is meaningless if the fabric,
the
cloth
or material
technological process The major plastic characterized characteristics,
to be dyed
is not
mentioned
applied for this dye is not specified. materials which have become actual
by composition and physical, adequately standardized-have
mechanical increasingly
and
even
if the
‘commodities’and miscellaneous diversified within
and thanks to this evolution, today there are the major polymer families, plastics which are designed and manufactured for specific purposes (packaging, tubes, laminates, etc); there are also composite greenhouses, crop covers, materials properties fibres,
in which plastics provide such as tensile strength
metal
fibres
or carbon
the support and in which specific mechanical and shock absorption are provided by glass
fibres,
and
from those of the matrix compound. Clearly we are currently in the middle
even
polymer
of ‘function
compounds chemistry’:
different if this was
then what is new in the tendency I describe to draw to the already known, attention of experts and futurists? We can give numerous examples of this chemistry, such as nitrogen-based fertilizers
replaced
by a direct
nitrogen
fixation
in the roots of plants
and cereals
(wherever possible through DNA rearrangement processes); or biological warfare against noxious insects instead of using chemical insecticides. Such examples show that the transfer from product chemistry to a function chemistry can even lead to a complete extinction of one product. This ‘dematerializing’ innovation requires, in order to be used effectively, a deep transformation in the structure of economic activities in which this innovation is based (in this case, agricultural production) as well as new industries and related services. It is true that biotechnologies completely industry; upstream extremely
will play a part in the deep-seated
innovations
which
will
transform one of the most traditional sectors of the chemical it is also clear that the development of biotechnologies requires chemical research which is properly subdivided, thorough and dedicated. For instance, fixation of atmospheric nitrogen could be
achieved in the roots of one cereal through genetic engineering techniques capable of achieving a symbiosis between the plant roots and their nitrogensettling micro-organism (for instance Rhizobium) as is now the case with leguminous plants. This objective is not easy to attain, a whole series of problems will have to be solved, and a whole range of biochemical, chemical and physical research carried out. One of the problems concerns energy. To obtain a chemical transformation of atmospheric nitrogen into a nitrogen molecule useful to the plant, this plant will have to supply the energy required for this reaction through processes related to chlorophyllian photosynthesis. This energy
FUTURES April 1966
176
Research, innooatm and renewal in the chemical industry
absorption
through
nitrogen
fixation
would be obtained
to the detriment
of the
plant’s growth rate and would therefore reduce agricultural yield unless photosynthesis efficiency could somehow be improved. In other words, the energy we consume today as methylene or petrol to produce ammonia (and from this nitrogen-based fertilizers, in large chemical plants) could be obtained by using solar power available at the field without interfering with provided that the combined objectives of fixation of atmospheric increased
efficiency
Microelectronics
of plant
photosynthesis
could
plant growth, nitrogen and
be met.
in chemistry
Microelectronics
is another
research and the latest information technology,
example
technology, with the
of the
interaction
between
mechanical
with synergistic effects. Developments in arrival of new generations of computers,
require extensive research in solid-state chemistry and physics to produce the basic materials (silicon, semi-conductors, gallium arsenide compounds, magnetic bubbles, etc) as well as miniaturization technologies. This dependence of microelectronics on research in chemistry and materials science is counterbalanced by the increasing use of computers in chemical research. Indeed, in pharmaceuticals, phytopharmacy, dyes, aromas, etc, the traditional ‘random synthesis and screening’ system of new active organic products (which is becoming increasingly costly because of the enormous number of molecules that have to be synthesized before finding one with the required properties, without negative side-effects) will necessarily be replaced, for the most part, by synthesis theoretical chemical,
methods
with specific objectives. Thanks to computations in the correlation between molecular structure and chemistry, biochemical, etc properties, will be understood in the physical,
minutest detail. The discovery of new organic products various sectors of relined chemistry, through optimization through computer-guided synthesis (‘lead These examples of complex interactions chemistry and research in other scientific
could thus occur in processes and even
optimization’ and ‘lead generation’). between research and innovation in sectors and industrial activities, only
give a vague idea of the type of structural change which will occur in this industry. In other words, the tendency is to break up the chemical industry, to split it up into sub-sectors which are increasingly closely linked to the solution of specific problems (or to the answer to given demands) and to rearrange it into new industries born from an interdisciplinary conception of the contribution of integrated either horizontally (eg US companies in the mnovation, metallurgical sector) or vertically (eg the integration between energy and raw materials-petrochemical and synthetic derivatives). This massive innovation process-which affects science and technology as well as industrial structures and services-should create many jobs, but certainly not traditional ones. It is forecast that research centres will be dedicated to finding solutions to increasingly important problems (here, for instance, I am thinking about the shortage in soft water foreseeable in only a few decades, and the need to purify and desalinate recycled and sea water). New services will have to be created to offer technological assistance to agriculture, to fight corrosion and to prevent
illnesses.
All these
activities,
and others
related
to the design
of
FUTURES April 1966
Kesrarch, mnoua!ion and renewal in the chenncal industry
new software
and to the computing
wider basis for research, will most probably
requirements
of chemistry
as well as for computer-aided
employ
technicians
and specialists
design
on a wider
177
and
and manufacture,
in greater
numbers
than
the number of jobs lost through increasing automation and robotization. In conclusion, it can be stated that the evolutionary prospective in chemistry rich in deep-rooted
and significant
innovations.
The
chemical
industry,
is
as we
have been used to saying from its birth until today, now opens up fields which are so wide that no common denominator with a strong enough base can bc found. Literally, the ‘chemical’ industry is no longer required. It will tend to dissolve markets
and and
to rebuild itself around fields of activities, problems, explicit societal demands. During this process, it will combine with
industries which, traditionally, were buying its products or, conversely, were supplying it with raw materials. This does not necessarily mean that the major chemical companies-which are now some of the largest companies in the world-will disappear. They will continue to exist, but they will increasingly resemble f‘actors,
industrial
conglomerates
and will no longer
intersectoral
held together
be uni-strategy
by financial
companies.
They
and organizational will manifest
strong
synergy.
Chemical research has still to reap a rich harvest in innovations that will be fertilized by research carried out in disciplines such as physics, biology and new information technologies. All this is bound to happen; however, this statement applies process
in a thermodynamic sense, if I can use that term. However the kinetic If the positive aspects of deep is nonetheless extremely uncertain.
structural innovation receive some understanding, and ifthis process is assisted, the transition will be shorter and less arduous than if, on the contrary, the flexibility requirements encounter mistrust and if the unavoidable changes were to have traumatic effects on an excessively rigid and sclerotic industrial and sociopolitical system.
Notes and references 1. B. Delapalme et al, Changement Noour cau Contexfe Economiqur
Technique
OECD, on innovation
the nrw Econorntc and Social Context),
2.
U. Colombo, 1980,
3.
[‘“$yS
P. Cohendet
“A viewpoint X14-23
et Politique Economique:
et Social ( i’khnical
and Politro-economic
1980. and the chemical
la Science et la Technologie dam le Change. Science and 7 bchnolo,/y in
industry”,
h’esearrh Po/ic_y, 9 (t?).
1.
et al, Les Perspectives de la Chimie en Europe (Perspectiues for the European Chemical of’ European Report prrparcd fbr thtt FAST P.10bTrLunrrre of thr Commission
Indu.\r~y) BETA
4. 5
Communities. U. Colombo and G. Lanzavecchia, “Criteri di scelta della potenzialitk degli impianti chimici”, Iq chim Ital, 9 (2) 1973 pages 22-30. U. Colombo, “Is oil too valuable to burn”, paper presented at the World Petrochemicals Conference organized by the Financial 7’imo and 011 Da+, in Lu Chlmita P I’lndurtrin, 6, 197.5, pages 395-401. ChrG/ry (2nd Indn~/rp, u. Cololnbo. “Geopolitical inllurnce on invrstmcnt strategy”. December 1975, pages 994-998. R. Stobaugh, “11 ciclo di vita del prodotto, i flussi tecnologi internationali e il settore pctrolchimico”, industria Chimica, Supplement0 de1 No 1, 1982, pages 20-28. Estimatr from the Stanford Research Institutr (SRI International), 1981. (“Pcrsprctives on Europcarr “10 pvrspcctivcs dr la chimiv cn Europe” M. Bohy, chemistry”). Scrims FAST-EEC. No. 2, 1982.
FUTURES April 1966