“Levitating Diamonds Reach Impossible Speed”: Spinning at 1.2 Billion RPM, They’re Cracking Open the Secrets of Quantum Gravity

In the cutting-edge world of quantum science, a mesmerizing experiment is unfolding. Researchers at Purdue University have achieved the seemingly impossible by levitating and spinning tiny diamonds at extraordinary speeds. These diamonds, spinning at 1.2 billion revolutions per minute, are not just a spectacle but a gateway to understanding the profound mysteries of the universe. The team’s groundbreaking work is shedding light on quantum physics and its potential connection to gravity, paving the way for scientific advancements that were once thought to be the stuff of science fiction.

Diamonds That Float and Spin in a Vacuum

Within the confines of a vacuum chamber, researchers have managed to levitate nanodiamonds, each just 750 nanometers wide, using an ingeniously designed ion trap. These diamonds are not ordinary; they are crafted through high-pressure, high-temperature processes and then modified with high-energy electrons to create nitrogen-vacancy (NV) centers. These NV centers are the heart of the experiment, housing electron spins that act like tiny compasses to detect magnetic fields.

The setup for this extraordinary feat involves an Ω-shaped stripline and electrodes that apply electric fields, enabling the levitation and control of the diamond spins. Lasers are used to read the spin states, allowing scientists to glean information about the quantum behavior of these levitated particles. As Prof. Tongcang Li articulates, this is the first time optically detected magnetic resonance measurements have been performed on a nanodiamond in high vacuum. Such advancements are crucial as they offer new tools to probe the fundamental laws of physics.

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How Light and Rotation Reveal the Quantum World

The interplay between light and the spinning diamonds reveals fascinating insights into the quantum realm. A green laser illuminates each nanodiamond, causing it to emit a red glow that discloses its spin state. Simultaneously, an infrared laser reflects off the rotating diamond, allowing scientists to monitor its speed and direction. The scattered light resembles rays from a spinning disco ball, vividly displaying the diamond’s motion.

The remarkable speed of 20 megahertz, equivalent to around 1.2 billion revolutions per minute, is unprecedented. This speed is not merely for spectacle but is instrumental in pushing quantum spins into new territories where peculiar behaviors, such as the Berry phase, emerge. Observing these behaviors confirms the significant influence of the diamond’s rotation on the spin qubits, offering a novel way to explore quantum mechanics. The relationship between motion and spin provides a rare opportunity to study the deepest laws of the universe.

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Why This Work Matters for Science and Technology

Levitated particles in a vacuum offer a pristine environment, free from external disturbances, enabling precise measurements. The isolation achieved in these experiments makes levitated systems ideal for testing fundamental theories and creating precision measurement tools like gyroscopes and field sensors. The combination of floating particles and quantum spins in levitated nanodiamonds holds tremendous potential for technological advancements.

Previous attempts to levitate diamonds under high vacuum often failed due to pressure and spin signal challenges. However, the Purdue team overcame these obstacles by refining their trap and minimizing heat from detection lasers. This breakthrough allows stable levitation at pressures below 10⁻⁵ Torr, with controlled spin states, while maintaining a manageable internal temperature of 350 K. This success opens doors to deeper experiments exploring the connection between general relativity and quantum mechanics. Such experiments are pivotal in bridging these two major scientific theories.

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A Platform for Testing Quantum Gravity

The quest to unite Einstein’s general relativity with quantum mechanics has been elusive. However, the experiment with spinning diamonds offers a promising platform for testing theories of quantum gravity. By embedding quantum bits in rotating objects, scientists can observe how gravity affects these spins, potentially building large-scale quantum superpositions. These states, where particles exist in multiple configurations simultaneously, could provide crucial insights into whether gravity adheres to quantum rules.

Beyond theoretical implications, spinning diamonds have practical applications. The U.S. Air Force already employs optically levitated nanoparticles to enhance navigation and communication systems. As techniques improve, more industries stand to benefit from these advancements. These experiments underscore the potential of spinning diamonds as bridges between two major scientific paradigms, offering a glimpse into the future of science and technology.

Built by Hand and Optimized with Software

Creating the sophisticated trap for levitating diamonds required a blend of advanced tools and creative ingenuity. Using software simulations, the team tested various designs to optimize the trapping and microwave transmission capabilities. The final design, built on a sapphire wafer with a 300-nanometer-thick gold layer, includes additional electrodes for steering and spinning the diamonds.

PhD student Kunhong Shen highlights the ability to change the spinning direction by adjusting the voltage, likening the random spinning of the diamond to a tangled ball of yarn when the drive is off. The collaborative efforts of students, postdocs, and external collaborators were instrumental in the success of this groundbreaking experiment. The study, published in Nature Communications, represents a milestone in levitated optomechanics, bringing physics closer to answering some of its most profound questions.

The remarkable achievements in levitating and spinning diamonds at Purdue University are pushing the boundaries of quantum science. As researchers continue to delve into the mysteries of quantum gravity, the potential for scientific breakthroughs and technological innovations is enormous. What exciting discoveries and applications will the future hold as we further explore the intersections of quantum mechanics and gravity?

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