Zero carbon buildings and nZEB (nearly zero energy) buildings are crucial to meet ambitious national, EU and global climate targets that target the reduction of fossil fuel use in society, including in architecture. This is necessary to reduce CO2 emissions associated with the burning of fossil fuels. Every fraction of a degree of CO2 reduction matters.

To ensure a just and fair carbon neutral transition, carbon reduction measures such as nZEB must go hand-in-hand with other sustainability approaches such as inclusive and democratic processes with people and communities (see all other themes). At the heart of creating nZEBs are:

• Fabric and energy efficiency principles first (high insulation, airtightness standards, appropriate solar design etc. – see passive resilience theme).

• Ensure you undertake inclusive and democratic process and make sure no-one is left behind (see people & communities theme).

• Post-competition, return to check if things work as intended (i.e. achieving actual performance – see performance theme)

• After all, carbon emissions are not saved on paper but must be achieved in reality.

You as an architects play a vital role in achieving a carbon neutral society: early inclusion of nZEB strategies helps to integrate passive resilience approaches that reduce the need for energy in the first place. The goal is to make buildings that use less energy, thereby reducing carbon emissions

The essence of a building's success lies in its performance and the building envelope contributes significantly to the overall building’s performance. For the energy performance and occupant satisfaction and wellbeing, particularly crucial are the performance of airtightness, thermal bridging, the design of openings for ventilation and daylight and solar gain while minimising glare and overheating. It is paramount that user experience and human factors are included from the start because it is vital for health and well-being. While regulations exist, enforcing continuous envelope performance remains a challenge. Standards tend to overlook the nuances of real-world application. Feedback from various projects reveals critical issues such as insulation gaps and poor airtightness, calling for improved validation and rigorous construction. In buildings, many stakeholders need to be involved at different stages of the process (i.e., during planning, design, execution and the in-use stage and later feedback from it.

Finding out about users’ needs and expectations and responding to this in your project, means that your project is more likely to meet their expectations and your design intentions in reality. This is why we need to ask people about their needs and expectations and involve them at the beginning of the design process in the first place. So, map who the key users and stakeholders are in your own project. User engagement early on should not be neglected in favour of post-completion feedback or quantitative building monitoring only. Placing user-centric and feedback processes at the heart of design processes will require a culture change in most architectural practices (and in architecture education). During different stages you can include feedback processes, but even where a full integration or post-competition evaluation is not possible, collecting less extensive feedback is still of value. For example, it can be focused on specific issues that you want to understand. Knowledge gained from these processes must be used to respond to in your project, and to fix things if they do not work to ensure design intentions and values are met. Open sharing and publishing of lessons learned is crucial: the urgency of the climate and biodiversity crises require us to not waste time and instead to share and collaborate to ensure we all create truly sustainable buldings that perform in reality

Understanding and evaluating the risks to building performance is essential for designing in the climate emergency. One crucial tool in this process is monitoring the performance of your project combined with the use of benchmarks. This is because collecting feedback (i.e. monitoring) is one of the best ways to reduce risk to performance as it will reveal issues that can then be fixed; it also requires design processes to be altered throughout all stages with attention to performance, which further minimises risks. Benchmarks can be used as part of the design process and are a standard or performance target against which real-world feedback can be measured. It can also be used as a goal for one’s own project’s performance. Benchmarks, are vital tools for all built environment professionals to define scope, compare, collect data, develop and implement strategies, monitor, evaluate, learn and develop. Often they are quantifiable and relate to technical performance, though occupant satisfaction surveys are increasingly valued. When benchmarking energy consumption, it's crucial that you use recent data from similar projects, age and construction standards. Ideally, these benchmarks should rely on measured performance data.

Buildings are not static; they interact with changing environments, users, and evolving climate conditions. However, they often don't perform as expected, leading to higher energy consumption, user dissatisfaction, and increased carbon emissions. These underperformance issues often go unnoticed because we don't actively collect feedback from users and building systems, which can be done through Building Performance Evaluation (BPE) and Post Occupancy Evaluation (POE) processes. To ensure that what you design work as intended, you need to work with people at different stages: i.e., you need to gather ’feedback’ from a range of stakeholders before, during and after the design to understand their needs and expectations and refine your project accordingly. This reduces the risk to the project’s performance once finished, which is fundamental to ensure that the climate emergency is tackled in reality and not just on paper. Remember: including a diversity of stakeholders enables us to understand and respond to different needs and expectations in our projects.

Designing for the climate emergency cannot be achieved on paper only. It must work in reality for the users, in terms of energy and other sustainability targets set out. With the growing urgency of the climate emergency, these underperforming buildings need to be rethought. Some solutions that you should consider in your design project to reduce the performance gap and that help you achieve your design goals in reality are:

• Integrated design, where sustainability and performance aspects are not added on, but integrated from the early stages of the design process through to in-use stages

• Use performance aspects to help define your project

• The more contextual information you gather early on, the more likely that you select suitable sustainable approaches and that the project will perform as intended.

• Validation of your design proposal (e.g. daylight studies, energy use studies, solar and wind studies, spatial studies but remember they are still predictions)

• Mapping performance risks; for example create a performance risk plan

• Work with users and key stakeholders, for example create a democratic design plan

• Evaluating if intended performance is met in reality

This leads to projects that do not meet energy or carbon targets and may affect occupant satisfaction and their well-being. Performance must be met in reality, not on paper, and to achieve this, user-centric and interdisciplinary collaboration, are necessary with the architects' involvement in understanding how buildings function in reality (i.e. their performance). When monitoring performance we need to ensure we go back and fix things. This way we not only ensure intended performance is met in reality, but we also learn for future projects, creating a positive feedback loop and ensuring design targets and legislation are met. These lessons should also be shared publicly so we all leap forward as a profession and industry, learning together. Post-occupancy evaluations (POE) and building performance evaluations (BPE) and Soft Landing processes are essential for understanding performance aspects, and reducing the performance gap. As a student you should use a Performance Risk Plan as if it was to be a real intervention, where you identify potential risks (threats) to your project’s performance, and how you can mitigate this.

The Margretheholm islet located in Copenhagen served as the residence of the Danish Navy for several centuries. The constable school building, originating from 1939, had remained deserted for many years, displaying significant signs of deterioration. With a relatively small budget, the project was to work with adaptive reuse with the listed structure, transforming it to function as cost-effective student apartments. The adopted approach involved preserving the building’s original and weathered characteristics, with a deliberate emphasis on accentuating the dichotomy between the new additions and the historical elements. The subsequent apartments in the Constable School are an award-winning transformation project prolonging the existing building’s life, embedding the cultural heritage and ensuring carbon stays within the buildings while reducing the need for new materials, resources and waste production from demolition.

The GC Prostho Museum Research Centre is a research facility for a renowned dental health company, GC, that develops dental prostheses. The building functions as a laboratory and office space for 40 personnel but also has an exhibition space on the ground floor for the public. The project is known for its unique wooden structure that originates from the system of Cidori, an old Japanese toy.

In the context of health and well-being, outdoor environment quality encompasses the design, planning, and management of exterior spaces and landscapes surrounding built structures. The goal is to create environments that optimise the physical and mental health of individuals. This approach includes various factors such as green spaces, landscaping, air quality, access to nature, and outdoor amenities that enhance overall well-being. Ac-cess to well-designed outdoor spaces encourages physical health through opportunities for physical activity, relaxation, and a connection with nature. Green areas, parks, and recreational facilities promote exercise and leisure, contributing to a healthier lifestyle. Moreover, these outdoor spaces play a vital role in mental and emotional well-being by providing opportunities for stress reduction, relaxation, and social interaction, which ultimately lead to improved mental health and reduced feelings of isolation.

Understanding Soil explores into the intricate composition and properties of soil, emphasising its significance in architecture. Soil, a complex blend of minerals, organic matter, water, and air, undergoes formation through rock weathering and organic material accumulation. The composition, influenced by factors like climate and topography, includes mineral particles and organic matter, determining soil texture, structure, and fertility. Physical properties such as texture, porosity, and permeability, along with chemical properties like pH and nutrient content, are crucial considerations.

Architectural concerns regarding soil encompass contamination risks, erosion, compaction, poor quality, settlement, and subsidence. Sustainable soil practices, remediation techniques, and innovative approaches like bioremediation, mycoremediation and phytoremediation are explored.

The talk underscores the role of soil in ecological restoration and brownfield redevelopment, presenting opportunities for architecture projects that integrate bioremediation for soil improvement and landscape revitalisation.

The Vindmøllebakken project is an innovative response to the need for socially sustainable living spaces that reduce the carbon footprint and enhance residents' quality of life. It is constructed entirely from wood and features privately owned apartments (40 co-living homes, 10 apartments and 4 townhouses) surrounding a shared 500m2 space with various amenities, including a spacious indoor courtyard. The project is designed to promote a sense of community and encourage social interactions among residents.

A community led housing project to create affordable homes through a regeneration of an existing, largely vacant neighbourhood. Renovation, public realm, street improvement, public involvement and engagement are key topics. The Granby Four Streets encompass a group of terraced houses in Toxteth, Liverpool, constructed around 1900 to provide housing for skilled labourers. Following the 1981 Toxteth riots, the local council acquired many of these houses to demolish and redevelop the area. This led to the relocation of numerous residents and the subsequent deterioration of the houses. Nevertheless, there remained a strong sense of community both before and after the riots. This community's origins can be traced back to the 1960s and 1970s, but challenging circumstances affected Liverpool, particularly Toxteth, due to a significant decline in the city, notably following the riots in the 1980s, which prompted many residents to leave. Today, the community members themselves are taking the initiative to revitalize their area. A dedicated group of organized residents has spearheaded initiatives that are starting to yield positive results, breathing new life into their streets.

The ‘Zero-carbon Cultural Centre’ in Pakistan, designed by architect Yasmeen Lari, represents an exemplary fusion of sustainability and cultural preservation. This visionary project combines traditional techniques with modern innovation, creating a carbon-neutral cultural hub. It exemplifies the harmonious blend of sustainability and cultural heritage and carries profound social impact. By revitalizing traditional craftsmanship and promoting eco-awareness, Lari’s creation fosters community engagement, empowerment, and a renewed sense of cultural pride, transcending architectural boundaries.

Powerhouse Telemark is an office building that aims to be carbon positive by using whole life carbon calculations to estimate the carbon that the building’s construction and lifetime use will amount to and measuring that against the energy that the building will produce over its life from renewal solar energy.

Carbon positive house is a prefabricated micro-house that is available in Australia designed by ArchiBlox and claims to be ‘Carbon Positive’ by generating more energy than it takes to build it over its predicted lifespan.

Enghaveparken has transformed remarkably into one of Copenhagen's most expansive climate-oriented redevelopments. Central to this transformation is a considerable water reservoir encompassing 22,600 cubic meters; it is welldesigned to address the considerable challenges of flooding in the city's present and anticipated future.