Blocks keep falling in Quantris, a quantum twist on the classic game Tetris. A pale yellow square awkwardly lands atop a green block shaped like the letter “Z”. There’s a unique block nearby, bordered in white, seemingly enclosing empty space—a representation of a quantum state of superposition. Observing it changes everything. Confirm your existence: a small black square with an eye symbol falls, flashes into existence, and your block tower perilously approaches the ceiling. Did the block vanish due to observation? No luck here! In Quantris, the quantum version of Tetris, one realization becomes clear: even quantum mechanics can’t save me from my gaming skills.

Though I’m new to quantum video games, their history runs deep. References to quantum physics appeared in video games back in the 1980s. However, the surge in quantum games truly took off when quantum computing became accessible via the cloud in 2016. The rising adoption of tools like IBM’s quantum software development kit has further fueled innovation. Laura Pispanen, a researcher at Aalto University, estimates there are nearly 400 quantum games today, many born from the weekend Quantum Game Jam events since 2014.

Among her favorites is Cubit the Barbarian, reminiscent of classic sword and sorcery themes. This game lets players navigate a maze through tiles that represent different quantum states, enabling them to exploit quantum mechanics and interact with the environment in fascinating ways. By measuring quantum states, players can transform the maze, discovering new paths or erecting barriers.

A dedicated community of researchers and gamers believes in the future of quantum video games. The convergence of untested tech, counterintuitive physics, and the timeless joy of gaming creates a unique landscape. What advancements will we see from quantum computing in gaming? How can games leverage the power of quantum mechanics?

It’s essential to clarify that we’re not discussing games playable directly on quantum computers. While these devices are rapidly advancing, they remain largely experimental. They’ve only recently gained enough computational power and reliability for specific scientific problem-solving. However, they are not all-purpose machines yet—likely suitable for only select tasks, and real-time video game execution remains untested.

Despite this, quantum hardware is making inroads into game development. Released this year, Quantum Backroom is a horror game that utilizes an IBM quantum computer for level generation. This eerie journey through liminal spaces reflects the unsettling nature of its internet phenomenon origins. James Wootton from Moth Quantum notes each room mirrors a quantum state of the computer, creating a visceral link to quantum technology.

Curious if these innovations will become mainstream, Julian Togelius from New York University, who studies creativity in video games and AI, believes that quantum computing could revolutionize game development. Quantum technology could connect in-game worlds more realistically, tackling the challenging mathematical problems that currently limit game design. However, he warns that this remains a complex challenge due to the limitations of quantum hardware.

In Quantum Backroom, the quantum elements impact game development rather than gameplay—it’s after the quantum computer powers off that gameplay is handled by classical systems. While Wootton successfully created a quantum version of rock-paper-scissors in 2017, many quantum games still run on classical simulators due to hardware limitations.

“At present, all my games are running on simulators. The hardware isn’t quite ready,” reflects Chris Cantwell, creator of Quantum Chess and other titles. In 2020, a Google quantum computer tested Quantum Chess, but it required extensive recoding. The essence of adapting games to quantum mechanics involves integrating quantum features into gameplay, essential for benchmarking quantum computer performance. Evert van Nieuwenburg at Leiden University has developed Quantum TiqTaqToe, a quantum version of Tic-Tac-Toe.

Bringing Quantum Concepts to the Living Room

Many quantum games incorporate real quantum phenomena, like superposition and entanglement, into familiar gameplay mechanics. In Quantum Chess, for example, two pieces can coexist on the same square. Van Nieuwenburg emphasizes that players don’t require in-depth knowledge of these concepts; engaging with them naturally builds understanding.

Quantum physics is often counterintuitive, as it usually applies to tiny particles or extreme temperatures. However, games offer a unique opportunity to interact with these principles. “At a recent science night, I observed kids playing Tic-Tac-Toe. They may not have understood the mechanics initially, but one kid excitedly exclaimed, ‘Oh, now you’ve got me involved!'” Van Nieuwenburg reminisces. Children quickly adapt to new concepts, including jargon from quantum physics textbooks. “Quantum Chess” enhances traditional chess, providing players additional pieces, and interestingly, children might not grasp the quantum aspects yet. However, they engage in genuine quantum phenomena, hinting at a future where they could become quantum-native developers.

Reflecting on my younger brother—who found little interest in physics but was absorbed in his console games—I ponder whether he could excel in quantum challenges if the stakes involved gaming. Spiros Michalakis from Caltech, who engages in games like Quantris and Quantum Chess, emphasizes the outreach potential of quantum gaming. His journey began in 2014 with quantum adaptations in Minecraft, leading to a new research field focused on creating games that are not only playable but engaging, where participants leverage new game mechanics for strategic advantages.

The challenge often lies in creating engaging gameplay using quantum features, depending less on the complexity of quantum mechanics and more on the allure of smart mechanics. “Creating a game is easy; making one popular is where the real challenge lies,” Togelius points out, along with skepticism about quantum computing becoming the next gaming revolution.

This dilemma resonates with broader quantum computing challenges, focusing on applying unique quantum operations to achieve previously unattainable outcomes. While daunting, the intersection of gaming and quantum innovation offers promising avenues for exploration.