copy the linklink copied!Chapter 3. Towards green growth

Taxes on energy products

The tax burden resulting from energy taxes varies widely across fuels, users and purposes. As in most OECD countries, transport fuels are taxed at the highest effective rate (Figure 3.2). Yet Denmark also has one of the OECD’s highest effective tax rates on energy use in non-road sectors (OECD, 2018[13]). This is explained by relatively high tax rates on electricity and other energy use in the residential and commercial sectors. Industry and agriculture face a considerably lower tax burden due to reductions and exemptions. The electricity tax for industry (i.e. production processes), for example, was set at DKK 4 (EUR 0.54) per MWh in 2019, just above the EU minimum and about 200 times below the ordinary electricity tax applicable to households (DKK 884 or EUR 119/MWh). The large disparity in energy tax rates creates unequal incentives for energy savings, and is not justified from an environmental perspective. The energy tax burden on industry (e.g. energy tax revenue as a share of industry’s gross value added) declined from 1.5% in 2004 to 0.8% in 2016 (MIBFA, 2018[14]), increasing the scope for adjustment.

Electricity taxes for households are the highest in the EU (EC, 2018[15]). While historically high taxes have encouraged power savings, their justification diminishes as power generation becomes cleaner. They also interfere with the cap in the EU ETS2 and discourage switching towards efficient solutions for electric heating (e.g. heat pumps and electric boilers) or electric vehicles, and create incentives for self-generation of power (e.g. with individual rooftop photovoltaic systems), even where socio-economically inefficient (IEA, 2017[16]). The government has taken steps to address this issue. It has reduced the electricity tax for heating (both for households and businesses) to DKK 259 (EUR 35) per MWh and plans to differentiate the tax on electricity used for electric vehicles. The phase-out of the PSO levy will reduce overall electricity prices and the 2018 Energy Agreement announced a gradual reduction in the standard electricity tax to DKK 774/MWh (EUR 104/MWh) by 2025. This will help increase the attractiveness of electric heating and mobility vis-à-vis fossil fuel- and biomass-based solutions. Unfortunately, the Energy Agreement also lowers the rate for some businesses to the minimum set for industrial processes, contributing to disparity among users. The change aims to equalise rates among businesses.

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Figure 3.2. Effective energy tax rates are highest in the road sector

Effective tax rates on energy use, by sector and by energy category

Note: Tax rates applicable on 1 July 2018. Energy use data are for 2016 and adapted from IEA (2018), World Energy Statistics and Balances. Excludes the PSO tax.

Source: OECD (2019), Taxing Energy Use 2019.

An open question is how to finance the reforms. Energy taxes are an important source of budget revenue, accounting for 5% of total tax revenue in 2016. Energy-related tax revenue has fallen by 11% since 2005 in real terms. The decline was driven by reductions in revenue from the CO₂ tax and the energy duty on petrol and natural gas, which in turn reflected declining consumption of fossil fuels and associated CO₂ emissions. Revenue will likely continue to fall with the projected decline in fossil fuel consumption, the phase-out of the PSO tax and reductions in the electricity tax. The government is considering temporarily increasing energy taxes or establishing a new temporary energy tax to finance the shortfall. Reducing the gap between industrial processes, heating purposes and other uses and/or taxing biomass could help in this respect.

Solid biomass, which is exempt from the energy duty and CO₂ tax, has gained in importance as a source for domestic and district heating. It use has more than doubled since 2005 and it accounted for 58% of renewables in 2017 (IEA, 2019[17]). While the use of biomass helps in meeting renewables targets, the assumption that it is carbon neutral from a lifecycle perspective has increasingly been challenged in the scientific literature (OECD, 2018[18]). In Denmark, 43% of consumed biomass is imported, primarily from Estonia and Latvia, making it even more difficult trace the fuel’s sustainability and carbon neutrality. The burning of biomass also creates significant air pollution (Chapter 1). The favourable tax treatment for biomass should therefore be reconsidered. Energy utilities have put in place a voluntary programme to ensure sustainable use of biomass, which includes sustainable management of the forests from which the biomass is derived.

Petrol is taxed significantly more heavily than diesel, at DKK 4.561 (EUR 0.61) per litre compared to DKK 3.104 (EUR 0.42) per litre of diesel. The tax gap between the two fuels is one of the largest in the OECD and increased over 2012-15. This is regrettable from an environmental perspective, as diesel combustion emits more CO₂ and local air pollutants than an equivalent volume of petrol. In addition, a litre of diesel normally allows more kilometres to be driven, meaning the tax on it should be higher to internalise driving-related externalities (Harding, 2014[19]). Road transport fuels are taxed at an effective rate (i.e. when considering both energy taxes and the carbon tax) that is comparable to average OECD levels but lower than in other Scandinavian countries and neighbouring Germany (OECD, 2018[13]).

To address the diesel-petrol gap, Denmark levies an annual countervailing charge on diesel cars (Section 3.3.3). The rationale is that a direct increase in diesel tax rates might encourage fuel tourism to neighbouring countries. However, as an annual tax that is not linked to vehicle use, it is less efficient way of addressing externalities. In addition, end-user prices for diesel are lower than in Sweden and Norway, although indeed higher than in Germany (IEA, 2018[20]). In any case, the countervailing charge failed to balance the lower diesel tax: both the sale of diesel vehicles and diesel consumption increased, with the share of diesel cars in the passenger fleet jumping from 10% to 31% over 2005-17 (DRD, 2018[21]). Denmark would benefit from phasing out the reduced energy duty for diesel, especially if it co-ordinated with similar moves in neighbouring countries.

Pricing carbon emissions from energy use

The carbon tax was introduced in 1992 for households and space heating in industry and has since been increased and extended to other uses. In 2008, Denmark raised the tax from DKK 25 to DKK 150 (which was the expected price of allowances in the EU ETS) and later indexed it to inflation. In 2018, the rate was DKK 173.2/tCO₂ (EUR 23/tCO₂), lower than in neighbouring Sweden, Norway and Finland. It should be noted, however, that Denmark levies higher excise taxes on some energy uses, such as transport fuels and residential energy use, which raises the implicit price of carbon. As explained above, energy excise duties – and thus the implicit price of carbon – vary significantly by user group, creating unequal incentives for CO₂ emission reductions. In addition, industrial processes benefit from a reduction of the CO₂ tax (IEA, 2017[16]).

In addition to putting a price on carbon via taxes, Denmark participates in the EU ETS. In 2017, 34% of Danish GHG emissions were subject to carbon pricing through this system. EU ETS installations are exempt from the carbon tax, or receive a full refund, to avoid double taxation; the exceptions are incinerators (Chapter 4) and heat inputs for district heating plants. The OECD estimates that, accounting for energy taxes and the EU ETS, 78% of CO₂ emissions from energy use in Denmark faced a price signal in 2015, albeit at a relatively low level (the remaining emissions largely stem from combustion of biomass, which is not taxed). Only 32% of CO₂ emissions faced a price above EUR 30/tCO₂ in 2015, which is a low-end estimate of climate damage. In contrast to a generally rising price signal in the OECD, the share of CO₂ emissions priced at or above EUR 30 in Denmark has dropped from 52% in 2012 (OECD, 2018[18]). This is likely due to higher (untaxed) biomass consumption and lower energy tax rates for industry. As a result, the economy-wide carbon pricing gap increased from 40% in 2012 to 52% in 2015 (Figure 3.3).

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Figure 3.3. Denmark ranks about average in pricing of carbon emissions from energy use

 StatLink https://doi.org/10.1787/888934002072

Vehicle taxes

Vehicle taxes consist of a one-off duty on purchase (the registration tax), an annual ownership duty (commonly called the green owner tax)3 and the countervailing charge for diesel vehicles. Added to this is a tax on car insurance premiums. While taxes for passenger cars have been reduced several times in recent years, they remain high by international comparison, mostly due to a high registration tax. They also appear high with respect to transport-related externalities (DEC, 2018[8]). Taxation of lorries, buses and trucks, by contrast, is relatively light.

High vehicle taxes discourage car purchases, resulting in a relatively low vehicle ownership rate and slow fleet renewal. The average passenger car is 8.9 years old, above the EU average of 7.4 years (EEA, 2018[22]). At the same time, the high registration tax (which is based on vehicle value) has encouraged purchases of cheaper vehicles, which tend to be small and more fuel efficient. In addition, both the registration tax and the green owner tax are linked to fuel efficiency.4 This combination had a significant impact on consumer choice, with higher sales of smaller and more energy-efficient cars that emit less CO₂ per kilometre. Average emissions from new cars have been below the EU average in the past decade (IEA, 2018[23]). The exemption of lorries from the registration tax and reduced annual tax rates on cars and vans used for commercial purposes are not justified from an environmental perspective and should be reconsidered.

Shifting the tax burden from car ownership to the use of vehicles and roads would enhance transport taxation efficiency (OECD, 2019[24]). Some progress has been made in this direction. In 2017, the registration tax was reduced to 85% of vehicle list price for the first DKK 185 000 (about EUR 25 000) from 105% of list price for the first DKK 106 000 (about EUR 14 000), while the annual vehicle tax was increased. The remainder is taxed at 150%, still high by international comparison. As the reductions were not compensated by measures targeting the externalities of car use, care must be taken to avoid cutting average car prices to the point of stimulating car sales and outweighing emission reduction benefits. The number of cars on the streets has grown continuously since 2010 (Chapter 1).

The countervailing charge that diesel car owners must pay aims to offset the difference in energy duty between diesel and petrol (MT, 2015[25]) but has not slowed the increase in diesel car sales. For normal diesel cars, the countervailing charge is calculated as the estimated tax saving from using diesel instead of petrol for 22 000 km annually. In addition, since 2010, a surcharge of DKK 1 000 (EUR 134) has been applied to diesel cars and new commercial vehicles (registered after March 2009) not fitted with particulate filters. Diesel buses pay a fixed countervailing charge of DKK 1 230 (EUR 165) per year and trucks and tractors are exempt. This exemption is not justified from an environmental perspective and should be reconsidered. Overall, taxation of trucks fails to internalise their external environmental costs.

To promote sales of electric and hydrogen vehicles, they were exempt from the registration and green owner taxes until 2015. The government aimed to phase in a registration tax for such cars (20% in 2016, 40% in 2017, 65% in 2018, 90% in 2019 and 100% in 2020), but this, coinciding with a general decrease in the registration tax, paralysed electric car sales (IEA, 2018[23]). The government thus decided to maintain the registration tax for electric vehicles at 20% for two additional years or until a threshold of 5 000 new registrations was reached. More recently, as part of the climate and air proposal, the government suggested imposing a registration tax for electric vehicles and hybrids with a list price of less than DKK 400 000 (EUR 54 000) in 2019 and 2020. This measure was adopted in late 2018 (see also Section 3.5.3).

Road and congestion pricing

Heavy vehicles and trucks with a permissible total weight of over 12 tonnes have to pay a road tax (Eurovignette) on motorways.5 Coaches are exempt. In addition, tolls apply on two major bridges: the Great Belt and Øresund. As part of the political agreement on lowering the registration tax, the government agreed to examine possibilities of introducing period-based tolls for passenger and vans from 2020 (MOT, 2017[26]). No details on implementation of such tolls have been released to date. Previous attempts to better internalise external environmental costs (e.g. through tolls per kilometre driven on certain roads) have been abandoned because they were considered very costly.

Congestion pricing is not applied. Introducing dynamic congestion pricing, where tolls can be adjusted according to traffic conditions, in the most affected cities would reduce pollution, enhance infrastructure use and generate revenue. Plans to introduce a congestion tax in the capital, the city most affected by congestion, were replaced by an air quality protection plan to reduce PM₁₀ and NO₂ pollution. In February 2019, the government set up a consultative commission to study ways to reduce CO₂ emissions from transport, giving it a mandate to consider road pricing and road tolls, among other measures, as alternative sources of revenue (MOF, 2019[27]).

Company cars and commuting expenses

As in most OECD countries, the employee benefit of being able to use a company-owned car (including for private purposes) is taxed less than cash wages. Harding (2014[28]) estimated that this favourable tax treatment created an annual subsidy of EUR 1 800 per company car, causing a tax revenue shortfall of about EUR 300 million in 2012 (compared to EUR 3 billion in revenue from vehicle-related taxes that year). Denmark’s system of company car taxation provides no incentive to choose efficient or less polluting vehicles. Company cars increase an employee’s annual taxable income by 25% of the vehicle’s listed value, irrespective of car type (unlike in Belgium, for example, which differentiates rates by CO₂ emissions and fuel type). In a positive step, the government’s climate and air proposal would make it cheaper to choose electric cars for use as company cars.

Employees who commute more than 24 km a day can deduct expenses related to commuting from their taxable income. The amount of deduction is calculated by applying a set rate to the distance travelled between home and workplace; the farther the employee lives from the workplace, the lower the deduction per kilometre travelled. There is no differentiation between forms of transport (unlike in Switzerland, for example, which allows deductions for private car use only in limited cases, a lump sum deduction for biking, and full deduction of public transport costs, providing an incentive to favour public transport and biking). Public transport costs paid by the employer are not treated as taxable income to the employee, increasing the attractiveness of public transport relative to other forms of commuting (including private car use), yet comparatively penalising lower-cost forms such as walking, biking and carpooling (Harding, 2014[28]).

Air pollutants

A tax on SO_X emissions for products containing more than 0.05% sulphur was introduced in the mid-1990s. A tax on NO_X emissions was introduced at DKK 5/kg in 2010. In 2012, the NO_X tax was raised to DKK 25/kg (and the limit value for mandatory measurement reduced from 30 MW to 10 MW to cover more producers), but it was reduced back to DKK 5/kg in 2015. Both the SO_X and NO_X tax rates are below the respective external costs of these pollutants as acknowledged in the guideline values for cost-benefit analysis published by the Ministry of Environment and Food (MEF) (Andersen, 2018[29]). There is no specific tax rate for particulate matter or volatile organic compounds.

Waste

Denmark applies taxes on waste landfilling and incineration. The landfill tax, introduced in 1987, was increased in 2015 to DKK 475 per tonne from DKK 160/tonne in 2012-14 (MT, 2015[25]). The tax has helped reduce landfilling but had only limited effect on recycling rates. The incineration tax was converted in 2009 from a weight-based tax to one based on energy and CO2 content. The new system aims at providing a stronger incentive to recycle the most energy-intensive waste, such as plastics (Chapter 4). The tax is a combined input-output tax, charged at DKK 26.5 per GJ according to the energy content in the input waste and DKK 19.8 per GJ for heat output. Waste from biomass and processing of meat waste are exempted. An exemption for hazardous waste was abolished in 2010. Waste incineration for power and heat generation represents a large share of waste treatment in Denmark. Denmark also applies a volume-based packaging waste tax on several types of beverage containers that are not part of the deposit-return system, and on bags and disposable tableware (Chapter 4). A weight-based packaging tax was removed in 2014.

Agricultural products

Denmark is one of the few countries taxing pesticides. In 2013, the pesticide tax, which was introduced in 1996, was redesigned from a value-based tax to a quantity-based tax that varies depending on human health hazard classification and the environmental impact of the pesticide: products with higher persistence, bioaccumulation or leaching to groundwater face higher rates. The generally higher tax rates and revenue were reimbursed to the agricultural sector (which accounts for more than 90% of pesticide use) through a reduction in the land value tax (GBE, 2014[30]). The change was made in a bid to reduce the pesticide load (a risk indicator) by 40% by 2015 from the 2011 level. Pesticide sales dropped significantly following the reform, partly because farmers stockpiled pesticides ahead of the reform (Chapter 5) (Eurostat, 2018[31]).

A tax on mineral phosphorus added to animal feed was introduced in 2005 at a rate of DKK 4 per kg of phosphorus to encourage a switch to phytase so as to reduce the saturation of soil with phosphorus. Mineral phosphate use in animal feed has fallen by about 15% since the introduction of the tax, and phytase use has increased. The tax is thus believed to have improved overall efficiency in the use of animal feed (Andersen, 2016[32]). A new phosphorus regulation introduced in 2017 allows efficient feeding, for example using high doses of phytase, to meet requirements on phosphorous reductions. It has resulted in a stronger incentive to increase phytase and reduce mineral phosphorus use than the tax. To prevent double regulation, the tax was to be withdrawn in July 2019.

Denmark pioneered construction of nutrient accounts at farm level. Agricultural nitrogen use has been partly regulated by a quota system, with allowable nitrogen consumption based on crop selection and soil type, among other criteria. Denmark recently adopted a new political agreement on more targeted regulation for agricultural nitrogen emissions, with targets based on geographical differences in watershed vulnerability and the soil’s ability to retain nitrogen (Chapter 1). The nutrient accounting system facilitates this new regulation paradigm. Since 2018, the nutrient accounting system has also been used to administer maximum allowable levels of phosphorus consumption at farm level.

Water

Denmark does not tax water resource abstraction but applies a tax on piped water at a rate of DKK 6.5 (EUR 0.9) per cubic metre. Most companies are exempt from the water tax (EEC, 2017[33]), implying that industry is in some sense cross-subsidised by households, which indeed face very high end-user prices (Section 3.5). Water supply plants must pay the tax on a minimum of 90% of water pumped, so if the plant has losses of more than 10%, it still pays on the balance of water lost. This rule, referred to as the water loss tax, creates an incentive for water companies to reduce leakage.

A wastewater charge applies to all direct discharges from sources including industry, municipal wastewater treatment plants and individual households in the countryside. The tax is proportional to the pollution load and applies to nitrogen (DKK 30/kg), phosphorus (DKK 165/kg) and organic material (DKK 16.50/kg). The rate is uniform nationwide, whatever the quality objective or the diluting capacity of receiving waters. Utilities pass on the cost to households; direct dischargers pay it directly to authorities. Some industrial sectors, including fish processing, benefit from reductions of between 70% and 80% in this tax liability. A small part (less than 5%) of the revenue raised is earmarked for government mapping of groundwater and municipal action planning.

Subsiding peatland conversion

Conversion of peatland to wetlands or permanent grassland has considerable climate mitigation potential due to lower decomposition of soil carbon, with a potential to reduce agricultural GHG emission by about 15% (Dubgaard and Ståhl, 2018[7]). However, EU policies limit this potential, as farmers lose income support under the CAP when agricultural peatland is converted to nature areas. Moreover, the EU 2030 Climate and Energy Framework caps how much member states can use carbon sequestration to meet their reduction targets for non-EU ETS sectors.

Under the RDP, Denmark subsidises farmers for conversion of peatland into permanent nature areas. DKK 65 million (EUR 9 million) was allocated to this purpose per year for 2016-19 (see “Rewetting of low-lying areas” in Table 3.3). In addition, Denmark set up a Multifunctional Land Redistribution Fund (MLRF) with a budget of EUR 20 million as part of the drought package for agriculture from 2018. The fund’s aim was to acquire and redistribute agricultural land where farming had a significant environmental impact and convert it to natural areas or grassland; examples include peatland and soil close to ammonia-sensitive nature areas or close to drinking water boreholes. In February 2019, Denmark’s two main environmental and agricultural interest groups jointly recommended increasing the MLRF by at least EUR 130 million to buy environmentally valuable agricultural land so as to support the target of achieving net zero emissions by 2050 and deliver co-benefits for biodiversity, water and air quality, and climate adaptation (DN and DFAC, 2019[37]).

As this proposal requires substantial public funding, Denmark should evaluate the pilot phase before scaling up the fund. In the medium term, it should seek opportunities for complementing public funding with private resources to finance peat conversion subsidies or land acquisition under the MLRF. In addition to philanthropic payments, this could be achieved by using peatland as carbon credits that could be purchased by parties that must offset their GHG emissions through voluntary or compliance markets.

Renewable energy resources

Denmark has experienced a boom in renewables over the last decade: they now account for around one-third of primary energy supply and almost two-thirds of electricity generation (Chapter 1). This growth, which was particularly strong for wind and biomass, has been driven by strong and broad political will at the local and national levels, targeted support policies and community-based engagement (IEA, 2017[16]). The main supporting policies include direct subsidies (a feed-in premium system), taxation (including exemptions of biomass from various energy taxes), subsidised grid connection and balancing costs, and reinforcement of the grid to connect plants running on renewables. Denmark also has used several funding pools, including for renewables in district heating (geothermal energy and large heat pumps) in 2012-15, and in processing in 2013-20 (IEA, 2017[16]). The share of renewables in energy demand doubled over the past decade to reach 35% in 2017 (Chapter 1), putting Denmark on track to reach its goal of meeting half of energy demand with renewables by 2030.

Current support policies were set up by the 2012 Energy Agreement and have since been adjusted several times. New post-2020 measures were agreed in the 2018 Energy Agreement. A “frozen policies” scenario modelled by the Danish Energy Agency shows that without new measures such as those in the 2018 Energy Agreement and climate and air proposal, growth in renewables would stagnate and fossil fuel consumption rise after 2020, due in part to planned energy-intensive data centres,11 so GHG emissions would begin increasing again from 2022 (EA, 2018[40]). If the 2018 Energy Agreement is fully implemented, GHG emissions will continue to decrease gradually after 2022 (Chapter 1).

Denmark’s incentive structure had varying levels of success across renewable energy sources. Successful offshore wind tenders have resulted in record low prices, which, combined with technological advances, led to a 48% cost reduction in offshore wind between 2010 and 2016 (IEA, 2017[16]). The tenders have many successful characteristics, including guaranteed grid connection and electricity offtake and one primary entry point (one-stop shop) for permitting and licensing – both of which provide certainty to investors and drive costs down. Denmark has become a global leader in wind energy technology throughout the supply chain. Expansion of renewable and alternative fuels in the transport sector is increasing slowly. The support system for solar photovoltaic power has been revised several times over the last five years and the feed-in premium system was withdrawn for new projects in May 2016 because Energinet, the state-owned enterprise that runs the electricity and natural gas transmission systems, was receiving too many applications.

The overall cost of supporting renewables has increased quite sharply since 2010 (Figure 3.5), reaching over DKK 8 billion (EUR 1.1 billion) in 2015. The government estimates that subsidies totalled about DKK 8.5 billion in 2018, the largest share being for offshore wind. The increase was driven by steadily growing generation eligible for support (notably offshore wind) and low electricity prices. Some 62% of gross electricity is produced with renewables support (the average across 26 EU countries is 16%), though the unit support levels (direct cost per MWh of supported electricity) are lower than in some EU peers. The cost of support per unit of renewables generation is highest for solar and biogas (IEA, 2017[16]). Most existing support measures have been financed by the PSO levy, which is added to the electricity price. It is being phased out over 2017-21, after which renewables development will be supported directly from the state budget. The PSO, determined quarterly, rose along with growing subsidy expenditure, reaching DKK 7.3 billion in 2015. It covered nearly all subsidy expenditure that year.

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Figure 3.5. The cost of supporting renewables has increased sharply since 2010

 StatLink https://doi.org/10.1787/888934002110

In 2017, the Energy Commission published recommendations on Danish energy policy after 2020. It estimated that the cost of reaching the target of 50% renewables by 2030 was manageable, provided Denmark could reduce the need for subsidies for renewables deployment and make development market-driven in the long term. The 2018 Energy Agreement aims to ensure a market-driven green transition. Among other things, it allocates DKK 4.2 billion (EUR 564 million) for technology-neutral procurement through tenders, and commits to harmonise and simplify subsidies as far as possible (Box 3.2). The agreement maintains sizeable subsidies to offshore wind and biogas. Both entail a risk of low value for money, but Denmark is willing to bear the high initial cost of being a front runner and exploring renewables options with environmental co-benefits (in the case of biogas).12 The agreement also announced “continued extensive extraction” of North Sea oil and gas to generate funds for the state budget and investment for the green transition.

Energy efficiency

Denmark’s praiseworthy decoupling of GDP growth from energy consumption growth has been achieved through national energy efficiency objectives and various measures to meet them. A comprehensive energy savings strategy was published in 2014.

The main measure on the supply side is the Energy Efficiency Obligation (EEO) for grid and distribution companies in the electricity, natural gas, district heating and oil sectors. Initiated about 20 years ago, it is a market-oriented system in which participants can choose the most cost-effective measures to achieve savings. The system is financed by end-users via energy bills.13 Annual saving targets set by the EEO have mostly been met. However, the additionality of the programme is rather low. There has also been concern about its rising cost to bill payers, in part linked to the lack of incentives for participants to reduce the cost of implementing the obligation (Fawcett, Rosenow and Bertoldi, 2018[42]; IEA, 2017[16]). The rising cost influenced recent reductions in EEO savings targets for 2015-20 (by about 15%). The 2018 Energy Agreement announced that the programme would expire in 2021, to be replaced by a market-based system, based on open tenders, in which bidders would offer energy savings at a given price. Savings are targeted in process energy in industrial and service businesses as well as the building sector. The new system is to be complemented by an information and data initiative to enhance knowledge about savings opportunities.

The Danish Energy Agency has used voluntary energy efficiency agreements with large, energy-intensive businesses since 1996. Businesses that enter into a binding three-year agreement and commit to improve energy efficiency obtain a substantial reduction of the PSO (though that tax will be phased out by 2021). As the International Energy Agency has recommended, an option for continuing such agreements would be to increase the electricity tax (or other energy taxes) in industry from the current DKK 0.004/kWh except for companies committing to efficiency agreements (IEA, 2017[16]).

Standards for new buildings have been strengthened considerably and are quite high. The rate of improvement of existing buildings is still quite low, despite numerous initiatives launched over the last several years, and is a major challenge for the future. One area that may require attention is energy labelling of buildings, which can have an impact on selling prices. The Energy Agreement commits to establishing a long-term building renovation strategy, including milestones for 2030, 2040 and 2050 (IEA, 2017[16]).