This graphic represents a new experiment where levitating a nanodiamond with a laser in a vacuum chamber

Levitating nanoparticle improves 'torque sensing,' might bring new research into fundamentals of quantum theory

This graphic represents a new experiment where levitating a nanodiamond with a laser in a vacuum chamber

This graphic represents a new experiment where levitating a nanodiamond with a laser in a vacuum chamber for the first time was used to detect and measure its "torsional vibration," an advance that could bring new types of sensors and studies in quantum mechanics. (Purdue University image/ Thai M. Hoang)

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September 15, 2016

WEST LAFAYETTE, Ind. – Researchers have levitated a tiny nanodiamond particle with a laser in a vacuum chamber, using the technique for the first time to detect and measure its "torsional vibration," an advance that could bring new types of sensors and studies in quantum mechanics.

The experiment represents a nanoscale version of the torsion balance used in the classic Cavendish experiment, performed in 1798 by British scientist Henry Cavendish, which determined Newton's gravitational constant. A bar balancing two lead spheres at either end was suspended on a thin metal wire. Gravity acting on the two weights caused the wire and bar to twist, and this twisting – or torsion - was measured to calculate the gravitational force.

In the new experiment, an oblong-shaped nanodiamond levitated by a laser beam in a vacuum chamber served the same role as the bar, and the laser beam served the same role as the wire in Cavendish's experiment. 

"A change of the orientation of the nanodiamond caused the polarization of the laser beam to twist," said Tongcang Li, an assistant professor of physics and astronomy and electrical and computer engineering at Purdue University. "Torsion balances have played historic roles in the development of modern physics. Now, an optically levitated ellipsoidal nanodiamond in a vacuum provides a new nanoscale torsion balance that will be many times more sensitive."

Findings are detailed in a paper that appeared on Thursday (Sept. 15) in the journal Physical Review Letters.

"This is the first experimental observation of torsional motion of a nanoparticle levitated in a vacuum and represents a very sensitive torque detector," Li said. "In principle, we could detect the torque on a single electron or a single proton."

The paper was authored by Purdue postdoctoral research associate Thai M. Hoang; student Yue Ma from Tsinghua University in China; Purdue graduate students Jonghoon Ahn and Jaehoon Bang; Francis Robicheaux, a Purdue professor of physics and astronomy; Zhang-Qi Yin, an assistant research fellow at Tsinghua University; and Li.

The paper details the detection of torsional vibration, a proposal to use the technique for torque sensing and also to achieve torsional "ground state cooling," which could aid efforts to study quantum theory and realize potential applications in quantum information processing and high-precision measurement for sensors.

This cooling reduces "noise" caused by vibrating molecules and atoms, making it possible to precisely measure torque and probe the relationships between motion and electron "spin." Electrons can be thought of as having two distinct spin states, "up" or "down," and this phenomenon might be used in future quantum simulations.

The paper includes experimental and theoretical portions.

"Experimentally, we observed torsional motion, and the theoretical part is a proposal of how to cool down the motion to achieve quantum ground state," Li said.

The nanodiamonds are about 100 nanometers in diameter, or roughly the size of a virus. Future research will include efforts to achieve ground state cooling.

The research was supported by the National Science Foundation and by the National Natural Science Foundation of China.

Paper: 

http://journals.aps.org/prl/abstract/10.1103/PhysRevLett.117.123604

ABSTRACT

Torsional optomechanics of a levitated nonspherical nanoparticle    

Thai M. Hoang,1 Yue Ma,2,3 Jonghoon Ahn,4 Jaehoon Bang,4 F. Robicheaux,1, 5 Zhang-Qi Yin,2,  and Tongcang Li 1, 4, 5, 6,

1Department of Physics and Astronomy, Purdue University, West Lafayette, IN 47907, USA 2Center for Quantum Information, Institute of Interdisciplinary Information Sciences, Tsinghua University, Beijing, 100084, China 3Department of Physics, Tsinghua University, Beijing 100084, China, 4School of Electrical and Computer Engineering, Purdue University, West Lafayette, IN 47907, USA, 5Purdue Quantum Center, Purdue University, West Lafayette, IN 47907, USA 6Birck Nanotechnology Center, Purdue University, West Lafayette, IN 47907, USA

An optically levitated nanoparticle in vacuum is a paradigm optomechanical system for sensing and studying macroscopic quantum mechanics. While its center-of-mass motion has been investigated intensively, its torsional vibration has only been studied theoretically in limited cases. Here we report the first experimental observation of the torsional vibration of an optically levitated nonspherical nanoparticle in vacuum. We achieve this by utilizing the coupling between the spin angular momentum of photons and the torsional vibration of a nonspherical nanoparticle whose polarizability is a tensor. The torsional vibration frequency can be one order of magnitude higher than its center-of-mass motion frequency, which is promising for ground state cooling. We propose a simple yet novel scheme to achieve ground state cooling of its torsional vibration with a linearly-polarized Gaussian cavity mode. A levitated nonspherical nanoparticle in vacuum will also be an ultrasensitive nanoscale torsion balance with a torque detection sensitivity on the order of 10−29 N • m/√Hz under realistic conditions.

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