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3D mapping is an evolving art form that merges technology, data, and creativity to visualise space in dynamic ways. Through artistic data visualisation, 3D mapping can showcase energy consumption and model climate-responsive designs. Additionally, it enhances public engagement by making complex environmental data more accessible and inspiring action toward sustainability through immersive storytelling and digital projections.

The energy used for 3D mapping can be made sustainable by relying on renewable sources like solar, wind, or hydroelectric power to run the mapping equipment. Additionally, energy-efficient hardware, cloud computing with green-certified data centres, and AI-driven optimisation reduce power consumption. Sustainable practices, such as offsetting emissions and designing low-energy rendering techniques, further ensure that 3D mapping contributes to net-zero goals without excessive energy waste.

An analogue or digital data wall is a large-scale display that visualises information through a structured, artistic composition of data.

• Analogue Data Wall: Uses physical elements like charts, hand-drawn graphics, or installations to represent data in a tactile way, often incorporating materials like paper, string, or LED lights.

• Digital Data Wall: Uses screens, projections, or interactive displays to dynamically visualize real-time or historical data, often integrating AI, sensors, and 3D mapping.

Both approaches create a visual language by transforming raw data into an engaging, interpretable form, making complex information more accessible and aesthetically compelling.

The production of analogue or digital data walls can align with net-zero goals by using sustainable materials (e.g., recycled metals, biodegradable composites, or non-toxic paints), energy-efficient technology (LED screens, e-ink displays, and solar-powered electronics), and low-carbon manufacturing processes (3D printing with eco-friendly filaments or modular, reusable components). Additionally, cloud-based data processing can be optimized for minimal energy use, and lifecycle assessments ensure that materials are recyclable or reusable, reducing waste and environmental impact.

A sculpture of a protein fold can benefit audiences by making complex biological concepts more tangible and visually engaging. It can serve as an educational tool, helping people understand how proteins function and their role in medicine, genetics, and disease research. For artists and scientists, it bridges the gap between disciplines, fostering discussions on bioethics, artificial intelligence in healthcare, and molecular design. Additionally, such sculptures can inspire curiosity, creativity and a deeper appreciation of the intricate structures that sustain life.

Using materials such as Resysta and eco-friendly filaments for 3D printing is a great additional talking point for the artworks as well as reaching towards net zero goals.