Geological Survey of Denmark and Greenland Bulletin 31, 2014, 95-98


95

To what extent is Denmark vulnerable to mineral supply 
shortage?

Per Kalvig, Rune J. Clausen, Niels Fold and Karen Hanghøj

Mineral resources are building blocks of modern society and 
essential for progress and prosperity. Mankind has always de-
pended on access to mineral raw materials, which have been 
a key factor for wealth, culture and development. Modern 
societies are characterised by a rapidly increasing demand 
for specialised mineral raw materials, determined by their 
stage of technological development, the number of consum-
ers, and their standard of living. Generally, the availability 
of mineral raw materials has not, until recently, been consid-
ered an issue by the average consumer or by companies in the 
downstream end of the value chains, and mineral resources 
have not been part of the political agenda. In this context 
China’s control over rare-earth elements (REE) has been 
an eye opener to both industry and politicians worldwide, 
and has subsequently led to discussions about the possible 
exhaustion of finite resources and potential threats to the 
availability of raw materials caused by geopolitical tension 
and market restrictions.

The increased concern has lead to several attempts to assess 
the risk of supply shortage which are however still at a rather 
qualitative stage. Inadequate knowledge about the current 
and future demand for mineral raw materials prevents politi-
cal and industrial decision-makers from taking the necessary 
actions to predict and mitigate the national and industrial 
vulnerability to supply shortage. Thus, most modern socie-
ties, including Denmark, are vulnerable to mineral raw ma-
terials scarcity, but unaware of where and how it may appear, 
and how to prevent and address the problem. 

Scarcity issues
Scarcity issues have been discussed since Thomas Malthus 
in 1798 initially predicted problems of food shortage due to 
increasing population and later also in relation to mineral 
resources. A number of organisations and individuals (e.g. 
Club of Rome, Gro Harlem Bruntland) have taken the lead 
in these discussions and emphasised that natural resources 
are finite and limited and that the global economy is growing 
disproportionately.

At the summit meeting in Rio de Janeiro in 1992, all na-
tions were encouraraged to adopt the so-called Bruntland 

principles to ensure sufficient resources for future genera-
tions. The term sustainability was introduced to the mining 
industry. However, no clear effects can be identified neither 
in the policies nor in the overall mineral consumption, and 
global and national concern on how to secure raw material 
supply is increasing. Terms such as critical minerals were in-
troduced, reflecting the risk of scarcity of some raw materials. 
The US National Research Council quantitatively addressed 
scarcity issues related to minerals in 2008 (National Re-
search Council 2008), and since then a substantial number 
of reports have focused on the topic (e.g. Rosenou-Tornow 
et al. 2009; European Commission 2010; UNDP 2010; 
Graedel et al. 2012). The decoupling of wealth and mineral 
resource consumption remains to be seen.

Why are minerals important?
Mineral-based materials are present everywhere in our daily 
life – in houses, cars, computers, cooking utensils, paint, 
tiles, paper, plastic, batteries, wind turbines, roads, pipes 
etc. For each and all of these ‘end products’ the choice of raw 
materials – and thus the minerals that need to be mined – 
depends on the required physical and chemical properties 
of the products. In some cases more than one material may 
fulfil the product requirements and the choice will then be 
based on price and availability.

All societies need mineral resources for their develop-
ment, but exactly which minerals and metals are in demand 
and how they are used depend on the stage of development 
of the particular society. During historic time the trend has 
been very clear; innovation and new technologies require an 
increasing number of specialised raw materials. Consequent-
ly, we need to explore for new types of minerals to meet new 
demands.

The demand for minerals is fueled by 
a number of drivers
Demographics – The United Nations has estimated that the 
world population will increase from currently 7 billion to 
9 billion by 2050 and that about 6.5 billion people will 

© 2014 GEUS. Geological Survey of Denmark and Greenland Bulletin 31, 95–98. Open access: www.geus.dk/publications/bull



9696

live in cities in 2050. This trend creates a need to develop 
new infrastructure to support the fast-growing urbanisation, 
which in turn creates an increased demand for minerals, in 
particular sand, gravel, iron and copper. Numerous other raw 
materials are also needed for basic infrastructure. 

Wealth – The economic growth in some of the emerging 
markets – e.g. Brazil, Russia, India, Indonesia, China, the 
Republic of Korea, South Africa – creates millions of new 
customers for products like houses, household machines, bi-
cycles, cars, computers, etc. These are all manufactured from 
raw materials which have to be mined and processed. An ex-
ample of this is China that has the world’s largest population 
and is globally the largest consumer of copper, aluminium 
and iron. However, the consumption of copper in China 
is still only 3 kg/person/year, much lower than in Europe 
where the consumption is 16 kg/person/year (Bogner 2012). 
However, it is expected that China’s copper consumption 
will increase substantially mainly as a result of growing 
wealth, rather than just the growing population.

Technology – The introduction of new materials, for exam-
ple in houses and vehicles, in new electronic communication 
equipment and in new ‘green’ energy technology, changes 
the desired physical and chemical properties of materials, 

which in turn creates demand for new mineral raw materials. 
Emerging technologies and new materials have created a rap-
idly growing demand for certain commodities such as indi-
um and gallium used in light-emiting diode lamps; lithium, 
copper, neodymium and dysprosium used in electric cars; 
indium, cadmium and tellurium in photovoltaic thin-film 
and dysprosium and neodymium in magnets. Concurrently, 
the need for some traditional materials has been reduced. For 
example, light, strong materials such as aluminium and mag-
nesium have reduced the amount of steel required to build 
car frames.

Critical minerals and vulnerability to 
supply restrictions
During the past decade mineral resource shortage has made 
headlines in the media, especially with regard to the REE. 
In response, a number of institutions have developed lists of 
mineral criticality on regional and national levels. For ex-
ample, the European Union has defined 14 raw materials as 
critical to the EU (European Commission 2010). Typically, 
the studies have used a two-fold approach: (1) assessment of 
the supply risk and (2) assessment of the impact of an actual 
shortage. The term critical minerals is frequently used in this 
context. Critical minerals are those which are important to 

Su
pp

ly
 r

isk
 

Geological,
technological,
and economic

Social
and

regulatory

Geopolitical

National vulnerability to supply restriction

ImportanceSubstitutabilitySusceptibility

1 3

2 4

Fig. 1. Diagram of vulnerability to the supply 
risk and restriction (modified from Graedel et al. 
2012). In the diagram element 1 has a low supply 
risk and even if a supply shortage occurs, this will 
not have a great impact on society; element 4 has 
a high supply risk and society is vulnerable to sup-
ply restictions; element 2 possesses a high supply 
risk but low vulnerability to supply restrictions; 
and for element 3 the opposite situation occurs, 
the supply risk is low, but in the event of a supply 
risk the national vulnerability is high.



97

society and subject to a specific availability or supply risk, e.g. 
at the corporate, national, regional or global industry level.

Scarcity is the potential outcome of criticality if a supply 
risk is not effectively mitigated. Scarcity can be a result of 
several factors such as political conflicts, embargos, cartels, 
natural disasters, sudden increases in demand, inadequate 
investment in new mines and processing facilities or resource 
depletion. Resource depletion causing significant shortages 
of mineral commodities has not yet been documented except 
in the case of cryolite, but it may pose a long-term threat.

Based on long- and medium-term supply risk Graedel et 
al. (2012) assessed the vulnerability to supply shortage and 
identified three general components, namely (1) geology, 
technology and economy; (2) social and regulatory factors 
and (3) geopolitical factors. Each of these were specified by 
six indicators, forming the ‘supply risk axis’. The ‘vulner-
ability to supply restrictions axis’ is composed of another 
set of factors such as (1) importance, (2) substitutability and 
(3) susceptibility specified in eight indicators (see Figs 1, 2). 
Graedel et al. (2012) suggested that vulnerability should also 
include the environmental impact.

Forecasting and creating possibilities for 
adequate policies
The value chains for mineral raw materials include all stag-
es of mineral exploration, mining and the processes trans-
forming the minerals into intermediate goods applicable 

for manufacturing by industrial end users. However, most 
of the companies in the chain may be unaware of short- or 
long-term market constraints or opportunities. This pre-
vents the industry itself from responding to sudden changes 
in demand. The exploration that targets new raw materi-
als is therefore driven by commodity prices. Globally, 2556 
companies spent 20.5 billion US$ on mineral exploration in 
2012, of which 49% was spent on gold, 32% on base metals 
and the remaining 19% on all other commodities (Wilburn 
& Stanley 2013). This illustrates that the exploration sector 
is decoupled from the end user demand. Furthermore, there 
is a mismatch between the time scales of action in different 
parts of the value chain. Industrial demand for new raw ma-
terials and markets for raw materials fluctuate on short-time 
scales, whereas the time needed to adjust the supply is much 
longer; it typically takes more than ten years to open a new 
mine, and sometimes even substantially longer. Scrap sup-
plies for recycling, secondary raw materials, are insufficient 
and usually too expensive to handle in order to bridge the gap 
between short-term demand and supply.

Individual governments and their institutions need up-
dated assessment data on the national vulnerability to sup-
ply restrictions of mineral raw materials in order to develop 
and implement policies to avoid scarcity of particular criti-
cal minerals. For example, the general conditions for Europe 
may not necessarily be accurate and relevant for the Danish 
industrial and agricultural sectors. So far, only very limited 
data on vulnerability to supply restrictions are available for 

Substitutability SusceptibilityImportanceComponent

Indicator

87.5
(75–100)

62.5
(50–75)

37.5
(25–50)

12.5
(0–25)

National
economic

importance

Net
import
reliance

ratio

Net
import
reliance

Global
inno-
vation
index

Substitute
performance

Substitute
availability

Environmental
impact ratio

See equation
in SI

Score for
percentage

of
population

utilising

Percentage
of

population
utilising

Supply
risk score

of
substitute

See equation
in SI

See
equation

in SI

See
equation

in SI

See
equation

in SI

Poor

Adequate

Good

Exemplary

Sc
or

e

Fig. 2. Components of the valuation methodolog y for the vulnerability to supply restriction, detailing the X-axis in Fig. 1 (from Graedel et al. 2012). Sup-
porting Information (SI) is detailed in: http://pubs.acs.org/doi/suppl/10.1021/es203534z/suppl_ file/es203534z_ si_001.pdf



9898

public and private stakeholders in Denmark. In 2013, the 
Geological Survey of Denmark and Greenland (GEUS) es-
tablished the Center for Minerals and Materials (MiMa) to 
identify and study the most important raw material value 
chains. The Danish government subsequently decided to 
strengthen the knowledge about criticality, vulnerability and 
scarcity of raw materials and have requested MiMa to carry 
out a three-year research programme to complete a vulner-
ability analysis for Denmark. MiMa is currently identifying 
an adequate approach for this programme. Danish industry 
is characterised by an advanced downstream sector that de-
pends on many imported components in end-product as-
semblages, while manufacturing of upstream products based 
on primary raw materials is of lesser importance. However, 
regardless of where the Danish manufacturing activities be-
long in the value chains, they are all based on mineral raw 
materials, some of which may be classified as critical miner-
als.

It is important to examine and map the extent to which 
Denmark is subject to supply restrictions and to understand 
the implications of such vulnerability. Danish consumers 
may not be aware of a product’s requirements with regard to 
raw materials, and thus remain unaware of a potential sup-
ply problem attached to the product. Statistically, Denmark 
monitors export and import of all goods in compliance with 
international categories for goods and industries, but there 
is a need for more knowledge about the amount and types 
of processed raw materials in these goods and components 
used by Danish industry. MiMa and its partners will inves-
tigate these issues further and disseminate results, analyses 
and forecasts.

Conclusions
Denmark, like all other countries, depends on mineral raw 
materials – domestic and imported – to sustain and develop 
society and is thus vulnerable to mineral raw materials scar-
city. However, most consumers and companies in the down-
stream parts of the value chains as well as decision makers 
in the administration and industry are relatively unaware of 
this. It is the aim of the Center for Minerals and Materials, 
MiMa, to build knowledge and disseminate information for 
the Danish society about mineral resource supply risks and 
vulnerability to supply restrictions. 

References
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sourceinvestor.com/2012/05/09/the-commodity-megatrend).
European Commission 2010: Critical raw materials for the EU. Report 

of the ad-hoc working group on defining critical raw materials, 84 pp. 
Brussels: European Commission.

Graedel, T.E. et al. 2012: Methodolog y of metal criticallity determination. 
Environmental Science & Technolog y 46, 1063–1070. 

Malthus, T.R. 1798: An Essay on the Principle of Population, 388 pp. Lon-
don: J. Johnson. 

National Research Council 2008: Minerals, critical minerals, and the U.S. 
economy. Washington, DC: The National Academies Press.

Rosenau-Tornow, D., Buchholz, P., Riemann, A. & Wagner, M. 2009: 
Assessing the long-term supply risks for mineral raw materials – a 
combined evaluation of past and future trends. Resources Policy 34, 
161–175.

UNDP 2010: Human development report 2010 – 20th anniversary edi-
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ingstoke: Palgrave MacMillan.

Wilburn, D.R. & Stanley, K.A. 2013: Exploration review. Annual review 
2012. Mining engineering, May 2013, 22–42.

Authors’ addresses
P.K., R.J.C. & K.H., Geological Survey of Denmark and Greenland, Øster Voldgade 10, DK-1350 Copenhagen K, Denmark; E-mail: pka@geus.dk
N.F., Department of Geosciences and Natural Resource Management, Øster Voldgade 10, DK-1350 Copenhagen, K, Denmark.

http://www.resourceinvestor.com/2012/05/09
http://www.resourceinvestor.com/2012/05/09
mailto:pka@geus.dk