Energy and climate

Reducing the companyʼs greenhouse gas emissions to net zero by 2040 is one of Zurich Airport Groupʼs top priorities.

Relevance

As far back as 1991, Zurich Airport Ltd. began taking steps to reduce CO₂ emissions at the Zurich site. And despite expanding the infrastructure and doubling passenger numbers in the same period, it has succeeded in cutting annual emissions at Zurich Airport by around 50%. To play its part in limiting the global temperature rise to well below two degrees in line with the Paris climate agreement, the Zurich Airport Group is aiming to cut its own greenhouse gas emissions (Scopes 1 and 2) to net zero by 2040.

Of the known greenhouse gases, only carbon dioxide (CO₂) is emitted in any significant quantity at airports. Each year, therefore, Zurich Airport Ltd. records the CO₂ emitted by each of its airports in an emissions inventory in accordance with the Greenhouse Gas Protocol. Other greenhouse gases, such as those emitted by refrigerants for example, are recorded as CO₂ equivalents. All greenhouse gas sources are allocated to different spheres of influence known as “scopes”. Scope 1 comprises sources within the company. At the Zurich site these mainly include heating systems, in-house electricity generation and the vehicle fleet. Scope 2 relates to emissions resulting from generation of the energy purchased from external suppliers. Finally, Scope 3 covers all other airport-related sources (e. g. ground handling and aircraft, including flights to the final destination) plus sources from upstream and downstream processes, for example in connection with landside access traffic, energy production or waste disposal. At over 99%, by far the majority of emissions arising at Zurich Airport as a whole fall into Scope 3.

Besides reducing its own greenhouse gas emissions, the company is also facing the challenge of adapting to climate change that is already happening as this affects airport operations in numerous ways. Changing precipitation and wind patterns are just one example of the effect of rising average temperatures that require the company to take infrastructural and operational measures. An analysis of the impact on the company and resulting risks was carried out during the year under review. The measures that consequently need to be taken will be determined during the present year.

Approach and progress

Net zero by 2040

The Zurich Airport Group is endeavouring to reduce its energy demand and fossil fuel consumption as much as possible in order to lower associated greenhouse gas emissions. It has set itself the goal of reducing its Scope 1 and 2 greenhouse gas emissions at all its airports to net zero by 2040. This means that any remaining anthropogenic greenhouse gas emissions must be offset by removal of carbon from the atmosphere so that the balance is zero. In other words: those who continue emitting greenhouse gases must also ensure that they remove an equivalent amount from the atmosphere for a given period. As an interim target, the company is aiming to reduce its annual greenhouse gas emissions at the Zurich site to just 20,000 tonnes by 2030. To help it meet these targets, the company has drawn up a gradual reduction roadmap.

Greenhouse gas emissions of Zurich Airport Ltd. at the Zurich site since 1991 and planned reduction roadmap to 2040

The biggest contributor to greenhouse gas emissions in Scope 1 at Zurich Airport is the airportʼs own combined heat and power generation plant which both produces electricity for the airport and distributes heat over a district heating grid. Although the plant is operated efficiently with natural gas or fuel oil, it nevertheless emits a considerable amount of greenhouse gases. A priority for Zurich Airport Ltd. is therefore to reduce energy demand in its buildings. Each building renovation leads to lower energy demand thanks to better insulation, more efficient systems and new heating and cooling concepts. To tackle the increasing demands and accelerate progress, during the reporting year a new Energy & Decarbonisation department was created in the Real Estate division and was tasked with cutting greenhouse gas emissions linked to the companyʼs buildings. One of its first acts was to begin drawing up a new future energy supply masterplan.

Alongside energy demand, the second focal point is generating renewable energy. The use of geothermal technology offers the greatest potential here. A significant proportion of the infrastructure is already supplied with heating and cooling in this way, for instance in Pier E, the Circle and parts of the maintenance area. The project begun in 2022 to use an aquifer to supply heating and cooling to a large part of the airport made further progress during the reporting year. Exploratory boreholes delivered promising results regarding the position and physical properties of the 300-metre deep geological channel. Further investigations are now necessary. If successful, Zurich Airport will be able to use the channel from 2027. The year under review also saw project planning commence for the central energy center that will house the heat pumps and cooling units required to use the underground storage.

To meet its electricity needs, Zurich Airport Ltd. purchases fossil-free grid electricity. It also generates some electricity in-house in its heating plant and from solar panels. It plans to add more solar panels in the coming years.

Besides buildings, vehicles are also a significant source of greenhouse gases. The transition to electric vehicles, which has been underway for some years already, continued during the reporting year. The reduction roadmap outlines the transition to electric vehicles as far as possible. The increasing number of battery-powered vehicles will necessitate further expansion of the charging infrastructure, both airside for partner companies and landside for the general public. One external airport partner opened a public fast charging station during the year under review.

The Zurich Airport Group actively encourages its airport partners to make significant cuts to their emissions as well. Providing the necessary support by installing the charging infrastructure required for electric-powered vehicles and machines is just one of several measures it is taking at the Zurich site. Installing ground power systems to supply electrical power and air conditioning at stands so aircraft do not need to use their auxiliary power units is another. This will greatly reduce aircraft greenhouse gas emissions as aircraft are obliged to use the ground power systems and are only permitted to use auxiliary power units shortly before starting their engines. As a beneficial side effect, this also helps to significantly reduce noise and pollutant emissions. The same type of fixed ground power systems for supplying electrical power and air conditioning to aircraft are currently also being installed at all terminal parking stands at Florianópolis and Vitória airports in Brazil in order to reduce their Scope 3 emissions.

In addition to the requirement of the Zurich Airport Group that net zero be reached by 2040, the three sites in Florianópolis, Vitória and Macaé in Brazil have set an additional target of achieving climate neutrality by 2030. Carbon offset certificates may also be used for the latter. In India, where Noida Airport is under construction, the intention is to reduce greenhouse gases to net zero already by 2030. Ongoing feasibility studies are being conducted to identify what action needs to be taken.

Airport Carbon Accreditation

Airport Carbon Accreditation (ACA) is a widely recognised worldwide programme run by Airports Council International (ACI) which helps airports effectively reduce their greenhouse gas emissions and grades their progress. Zurich Airport continues to be accredited at ACA level four. As well as reducing greenhouse gases, this involves setting a target for achieving net zero greenhouse gas emissions from Scopes 1 and 2, specifying an appropriate reduction roadmap and documenting the measures taken to motivate its partner companies at the airport to likewise reduce their emissions.

During the reporting year the three majority-owned airports in Brazil at Florianópolis, Vitória and Macaé succeeded in advancing one ACA level and now have level 2 accreditation. This means they are continually reducing their greenhouse gas emissions every year.

Large-scale consumers agreement

As a large-scale energy consumer, Zurich Airport Ltd. has signed an agreement with the Building Department of the Canton of Zurich. This requires the company to make average annual efficiency savings of 2% until 2030, measured on the basis of the heated area of the airport and the number of user units (passengers, freight, other visitors). In return it is exempted from implementing some specific cantonal regulations. The target for specific energy consumption was met in the reporting period.

Energy and climate leader

Participation in the Swiss Confederationʼs Exemplary Energy and Climate initiative further underlines Zurich Airport Ltd.ʼs pioneering role in energy and climate protection. As part of this initiative it is implementing concrete measures to improve energy efficiency, to expand renewable energy sources and to reduce greenhouse gas emissions.

Sustainable fuels

In order to contribute to lowering aviation-related greenhouse gas emissions beyond its airport operations, Zurich Airport Ltd. is committed to the use of sustainable aviation fuel (SAF). SAF is fuel made from biogenic waste or synthetically manufactured fuel, and over the course of its life cycle it produces at least 80% lower carbon emissions than fossil-based kerosene. Zurich Airport Ltd. advocates the use of SAF, both in its role as a center of expertise among its partners at Zurich Airport and the rest of Switzerland as well as at its other locations abroad. It also supports political endeavours aimed at a blend ratio harmonised with the EU.

Zurich Airport Ltd. has itself signed an agreement with ETH spin-off Synhelion SA for the future supply of synthetic diesel fuel for vehicles. Synhelion plans to use novel technology to produce synthetic fuel at scale from water, CO₂ and solar energy.

Situation in the reporting year

After proving extremely challenging at the beginning of the reporting year, the provision of energy to users improved noticeably in the spring. The measures taken to reduce demand during the previous year continued into the first months of the reporting year, and some will be continued on a long-term basis. Concepts for dealing with shortages remain ready to be deployed.

During the year under review, the company’s specialists continued to work on reducing energy demand. For example, in Dock E, the heat pump was optimised, and the use of geothermal heat increased. An improvement in waste heat recovery also contributed to reducing fossil-based heat.

Compared to the previous year, in the reporting year the airport’s own heating plant, which can be run on both gas and heating oil, was operated almost exclusively with gas. This is the main reason for the lower greenhouse gas emissions from heat production. Other reasons included the high temperatures in the second-hottest year in Switzerland since measurements began – resulting in lower heating demand, as well as the higher overall efficiency of the heating plant.

The share of renewable energies was increased slightly for electricity (see diagram). By contrast, in terms of fuels, the share of renewables declined markedly. This was because biogas was not used during the reporting year, whereas it accounted for a significant share in the previous year.

Share of renewable energy at Zurich Airport

Key data

Greenhouse gas emissions

GRI 305 – 1; 305 – 2; 305 – 3

Zurich Airport Ltd., Zurich site	Unit	2019	2020	2021	2022	2023
CO 2 e Scope 1 Zurich Airport Ltd.	Tonnes	26,218	26,284	32,372	29,043	23,992
CO 2 e Scope 2 Zurich Airport Ltd.	Tonnes	1,632	1,212	19	24	21
Total Scope 1 and 2	Tonnes	27,850	27,496	32,390	29,067	24,014
CO 2 e Scope 3 at Zurich Airport 1)	Tonnes	4,516,773 2)	1,657,154 2)	1,803,890 2)	3,452,893 2)	4,123,913

Florianópolis Airport, Brazil	Unit	2019	2020	2021	2022	2023
CO 2 e Scope 1	Tonnes	n/a	n/a	91 3)	248 3)	299
CO 2 e Scope 2	Tonnes	n/a	n/a	980 3)	364 3)	387
Total Scope 1 and 2	Tonnes	n/a	n/a	1,071 3)	612 3)	686

Vitória/Macaé Airports, Brazil	Unit	2019	2020	2021	2022	2023
CO 2 e Scope 1	Tonnes	n/a	n/a	82 3)	202 3)	305
CO 2 e Scope 2	Tonnes	n/a	n/a	1,193 3)	390 3)	354
Total Scope 1 and 2	Tonnes	n/a	n/a	1,274 3)	592 3)	659

Natal Airport, Brazil	Unit	2019	2020	2021	2022	2023
CO 2 e Scope 1	Tonnes	n/a	n/a	n/a	n/a	n/a
CO 2 e Scope 2	Tonnes	n/a	n/a	n/a	n/a	n/a
Total Scope 1 and 2	Tonnes	n/a	n/a	n/a	n/a	n/a

Antofagasta Airport, Chile	Unit	2019	2020	2021	2022	2023
CO 2 e Scope 1	Tonnes	n/a	22	10	12	64
CO 2 e Scope 2	Tonnes	n/a	458	452	446	520
Total Scope 1 and 2	Tonnes	n/a	480	462	458	584

Iquique Airport, Chile	Unit	2019	2020	2021	2022	2023
CO 2 e Scope 1	Tonnes	n/a	97	99	57	77
CO 2 e Scope 2	Tonnes	n/a	328	350	541	527
Total Scope 1 and 2	Tonnes	n/a	425	449	598	604

Noida Airport, India	Unit	2019	2020	2021	2022	2023
CO 2 e Scope 1	Tonnes	n/a	n/a	n/a	31	40
CO 2 e Scope 2	Tonnes	n/a	n/a	n/a	41	218
Total Scope 1 and 2	Tonnes	n/a	n/a	n/a	73	258

Scope 1: In accordance with GHG Protocol: Zurich Airport Ltd.’s own sources (vehicles, machinery, heating)

Scope 2: In accordance with GHG Protocol: externally sourced electricity for Zurich Airport Ltd.

1) In accordance with GHG Protocol: aircraft in LTO cycle and full flight (outbound flight only), calculated by Eurocontrol, other emission sources at airport (ground handling, other heating) and all landside traffic from start to destination for all modes of transport

2) Retroactive correction

3) Retroactive adjustment to the calculation method

Energy

GRI 302 – 1; 302 – 2; 302 – 3; 302 – 4

Zurich Airport, Switzerland	Unit	2019	2020	2021	2022	2023
Thermal energy	MWh	88,469	88,302	120ʼ634	106,154	103,689
renewable	MWh	1,508	1,480	1,584	8,886 1)	4,292
non-renewable	MWh	86,961	86,822	119,050 1)	97,268 1)	99,397
Fuels	MWh	6,110	3,662	4,922	4,799	5,393
renewable	MWh	0	0	0	0	0
non-renewable	MWh	6,110	3,662	4,922	4,799	5,393
Electricity	MWh	62,703 1)	44,933 1)	47,315 1)	59,688 1)	64,184
renewable	MWh	15,771	11,839	14,263	16,651	20,370
non-renewable	MWh	46,931 1)	33,093 1)	33,052 1)	43,036 1)	43,815
Total energy consumption (thermal energy, fuel, electricity)	MWh	157,281 1)	136,896 1)	172,871 1)	170,641 1)	173,266
Overall consumption primary energy 1)	MWh	497,595	411,709	456,589 1)	505,205	494,359
Energy intensity ratio according to GVV 2)	%	84.2	94.8	114.3 4)	106.2	90.7

Florianópolis Airport, Brazil	Unit	2019	2020	2021	2022	2023
Total fuel consumption	MWh	n/a	n/a	252	310 1)	301
Electricity consumption	MWh	n/a	9,420	7,716	8,423 1)	10,654
Total energy consumption	MWh	n/a	9,420	7,968	8,733 1)	10,955

Vitória/Macaé Airports, Brazil	Unit	2019	2020	2021	2022	2023
Total fuel consumption	MWh	n/a	n/a	254	345 1)	403
Electricity consumption	MWh	n/a	10,820	9,492	9,147 1)	9,747
Total energy consumption	MWh	n/a	n/a	9,746	9,492 1)	10,150

Natal Airport, Brazil	Unit	2019	2020	2021	2022	2023
Total fuel consumption	MWh	n/a	n/a	n/a	n/a	n/a
Electricity consumption	MWh	n/a	n/a	n/a	n/a	n/a
Total energy consumption	MWh	n/a	n/a	n/a	n/a	n/a

Antofagasta Airport, Chile	Unit	2019	2020	2021	2022	2023
Total fuel consumption	MWh	n/a	89	40	49	46
Electricity consumption	MWh	n/a	1,121	1,107	1,092	1,150
Total energy consumption	MWh	n/a	1,210	1,147	1,141	1,196

Iquique Airport, Chile	Unit	2019	2020	2021	2022	2023
Total fuel consumption	MWh	n/a	393	400	231	420
Electricity consumption	MWh	n/a	802	856	1,323	1,290
Total energy consumption	MWh	n/a	1,195	1,256	1,554	1,710

Noida Airport, India	Unit	2019	2020	2021	2022	2023
Total fuel consumption	MWh	n/a	n/a	n/a	117	152
Electricity consumption	MWh	n/a	n/a	n/a	51	307
Total energy consumption	MWh	n/a	n/a	n/a	168	459

1) Retroactive correction

2) Scope total airport excl. Fuel

3) Energy consumption measured in terms of energy reference area and user units

4) The target was raised to 109.5 owing to newly added buildings; The figure for 2021 was also corrected retroactively.