Tag Archives: quantum gravity

World’s smallest disco party features nanoscale disco ball

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I haven’t featured one of these ‘fun’ (world’s smallest xxx) announcements in a long time. An August 14, 2024 news item on phys.org announces the world’s smallest disco party and a step towards exploring quantum gravity, Note: Links have been removed,

Physicists at Purdue [Purdue University, Indiana, US] are throwing the world’s smallest disco party. The disco ball itself is a fluorescent nanodiamond, which they have levitated and spun at incredibly high speeds. The fluorescent diamond emits and scatters multicolor lights in different directions as it rotates. The party continues as they study the effects of fast rotation on the spin qubits within their system and are able to observe the Berry phase.

The team, led by Tongcang Li, professor of Physics and Astronomy and Electrical and Computer Engineering at Purdue University, published their results in Nature Communications. Reviewers of the publication described this work as “arguably a groundbreaking moment for the study of rotating quantum systems and levitodynamics” and “a new milestone for the levitated optomechanics community.”

This graph illustrates a diamond particle levitated above a surface ion trap. The fluorescent diamond nanoparticle is driven to rotate at a high speed (up to 1.2 billion rpm) by alternating voltages applied to the four corner electrodes. This rapid rotation induces a phase in the nitrogen-vacancy electron spins inside the diamond. The diagram in the top left corner depicts the atomic structure of a nitrogen-vacancy spin defect inside the diamond. Graphic provided by Kunhong Shen.

An August 13, 2024 Purdue University news release (also on EurekAlert but published August 14, 2024) by Cheryl Pierce, which originated the news item, explains what makes this work so exciting (!), Note: Links have been removed,

“Imagine tiny diamonds floating in an empty space or vacuum. Inside these diamonds, there are spin qubits that scientists can use to make precise measurements and explore the mysterious relationship between quantum mechanics and gravity,” explains Li, who is also a member of the Purdue Quantum Science and Engineering Institute.  “In the past, experiments with these floating diamonds had trouble in preventing their loss in vacuum and reading out the spin qubits. However, in our work, we successfully levitated a diamond in a high vacuum using a special ion trap. For the first time, we could observe and control the behavior of the spin qubits inside the levitated diamond in high vacuum.”

The team made the diamonds rotate incredibly fast—up to 1.2 billion times per minute! By doing this, they were able to observe how the rotation affected the spin qubits in a unique way known as the Berry phase.

“This breakthrough helps us better understand and study the fascinating world of quantum physics,” he says.

The fluorescent nanodiamonds, with an average diameter of about 750 nm, were produced through high-pressure, high-temperature synthesis. These diamonds were irradiated with high-energy electrons to create nitrogen-vacancy color centers, which host electron spin qubits. When illuminated by a green laser, they emitted red light, which was used to read out their electron spin states. An additional infrared laser was shone at the levitated nanodiamond to monitor its rotation. Like a disco ball, as the nanodiamond rotated, the direction of the scattered infrared light changed, carrying the rotation information of the nanodiamond.

The authors of this paper were mostly from Purdue University and are members of Li’s research group: Yuanbin Jin (postdoc), Kunhong Shen (PhD student), Xingyu Gao (PhD student) and Peng Ju (recent PhD graduate). Li, Jin, Shen, and Ju conceived and designed the project and Jin and Shen built the setup. Jin subsequently performed measurements and calculations and the team collectively discussed the results. Two non-Purdue authors are Alejandro Grine, principal member of technical staff at Sandia National Laboratories, and Chong Zu, assistant professor at Washington University in St. Louis. Li’s team discussed the experiment results with Grine and Zu who provided suggestions for improvement of the experiment and manuscript.

“For the design of our integrated surface ion trap,” explains Jin, “we used a commercial software, COMSOL Multiphysics, to perform 3D simulations. We calculate the trapping position and the microwave transmittance using different parameters to optimize the design. We added extra electrodes to conveniently control the motion of a levitated diamond. And for fabrication, the surface ion trap is fabricated on a sapphire wafer using photolithography. A 300-nm-thick gold layer is deposited on the sapphire wafer to create the electrodes of the surface ion trap.”

So which way are the diamonds spinning and can they be speed or direction manipulated? Shen says yes, they can adjust the spin direction and levitation.

“We can adjust the driving voltage to change the spinning direction,” he explains. “The levitated diamond can rotate around the z-axis (which is perpendicular to the surface of the ion trap), shown in the schematic, either clockwise or counterclockwise, depending on our driving signal. If we don’t apply the driving signal, the diamond will spin omnidirectionally, like a ball of yarn.”

Levitated nanodiamonds with embedded spin qubits have been proposed for precision measurements and creating large quantum superpositions to test the limit of quantum mechanics and the quantum nature of gravity.

“General relativity and quantum mechanics are two of the most important scientific breakthroughs in the 20th century. However, we still do not know how gravity might be quantized,” says Li. “Achieving the ability to study quantum gravity experimentally would be a tremendous breakthrough. In addition, rotating diamonds with embedded spin qubits provide a platform to study the coupling between mechanical motion and quantum spins.”

This discovery could have a ripple effect in industrial applications. Li says that levitated micro and nano-scale particles in vacuum can serve as excellent accelerometers and electric field sensors. For example, the US Air Force Research Laboratory (AFRL) are using optically-levitated nanoparticles to develop solutions for critical problems in navigation and communication.

“At Purdue University, we have state-of-the-art facilities for our research in levitated optomechanics,” says Li. “We have two specialized, home-built systems dedicated to this area of study. Additionally, we have access to the shared facilities at the Birck Nanotechnology Center, which enables us to fabricate and characterize the integrated surface ion trap on campus. We are also fortunate to have talented students and postdocs capable of conducting cutting-edge research. Furthermore, my group has been working in this field for ten years, and our extensive experience has allowed us to make rapid progress.”

Quantum research is one of four key pillars of the Purdue Computes initiative, which emphasizes the university’s extensive technological and computational environment.

This research was supported by the National Science Foundation (grant number PHY-2110591), the Office of Naval Research (grant number N00014-18-1-2371), and the Gordon and Betty Moore Foundation (grant DOI 10.37807/gbmf12259). The project is also partially supported by the Laboratory Directed Research and Development program at Sandia National Laboratories.

Here’s a link to and a citation for the paper,

Quantum control and Berry phase of electron spins in rotating levitated diamonds in high vacuum by Yuanbin Jin, Kunhong Shen, Peng Ju, Xingyu Gao, Chong Zu, Alejandro J. Grine & Tongcang Li. Nature Communications volume 15, Article number: 5063 (2024) DOI: https://doi.org/10.1038/s41467-024-49175-3 Published online: 13 June 2024

This paper is open access.

Measuring quantum gravity

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It was about two years ago that a local (Vancouver, Canada) group of movers and shakers announced the launch of a Vancouver-based Quantum Gravity Institute at the Quantum Mechanics & Gravity conference (August 15 – 19, 2022) in my July 26, 2022 posting where I also provided an overview of the doings in the Canadian quantum scene. (I can’t find an online presence for the institute but there is the Vancouver-based Quantum Gravity Society which organized the 2022 conference and the institute.)

All of this being the buildup to a quantum gravity announcement in a February 23, 2024 news item on Nanowerk,

Scientists are a step closer to unravelling the mysterious forces of the universe after working out how to measure gravity on a microscopic level.

Experts have never fully understood how the force which was discovered by Isaac Newton works in the tiny quantum world.

Even Einstein was baffled by quantum gravity and, in his theory of general relativity, said there is no realistic experiment which could show a quantum version of gravity.

But now physicists at the University of Southampton [UK], working with scientists in Europe, have successfully detected a weak gravitational pull on a tiny particle using a new technique.

They claim it could pave the way to finding the elusive quantum gravity theory.

A February 26, 2024 University of Southampton press release, also on EurekAlert but published on February 23, 2024, delves further into quantum gravity,

The experiment, published in the Science Advances journal, used levitating magnets to detect gravity on microscopic particles – small enough to boarder on the quantum realm.

Lead author Tim Fuchs, from the University of Southampton, said the results could help experts find the missing puzzle piece in our picture of reality.

He added: “For a century, scientists have tried and failed to understand how gravity and quantum mechanics work together.

“Now we have successfully measured gravitational signals at a smallest mass ever recorded, it means we are one step closer to finally realising how it works in tandem.

“From here we will start scaling the source down using this technique until we reach the quantum world on both sides.

“By understanding quantum gravity, we could solve some of the mysteries of our universe – like how it began, what happens inside black holes, or uniting all forces into one big theory.”

The rules of the quantum realm are still not fully understood by science – but it is believed that particles and forces at a microscopic scale interact differently than regular-sized objects.

Academics from Southampton conducted the experiment with scientists at Leiden University in the Netherlands and the Institute for Photonics and Nanotechnologies in Italy, with funding from the EU Horizon Europe EIC Pathfinder grant (QuCoM).

Their study used a sophisticated setup involving superconducting devices, known as traps, with magnetic fields, sensitive detectors and advanced vibration isolation.

It measured a weak pull, just 30aN, on a tiny particle 0.43mg in size by levitating it in freezing temperatures a hundredth of a degree above absolute zero – about minus-273 degrees Celsius.

The results open the door for future experiments between even smaller objects and forces, said Professor of Physics Hendrik Ulbricht also at the University of Southampton.

He added: “We are pushing the boundaries of science that could lead to new discoveries about gravity and the quantum world.

“Our new technique that uses extremely cold temperatures and devices to isolate vibration of the particle will likely prove the way forward for measuring quantum gravity.

“Unravelling these mysteries will help us unlock more secrets about the universe’s very fabric, from the tiniest particles to the grandest cosmic structures.”

Here’s a link to and a citation for the paper,

Measuring gravity with milligram levitated masses by Tim M. Fuchs, Dennis G. Uitenbroek, Jaimy Plugge, Noud van Halteren, Jean-Paul van Soest, Andrea Vinante, Hendrik Ulbricht, and Tjerk H. Oosterkamp. Science Advances 23 Feb 2024 Vol 10, Issue 8 DOI: 10.1126/sciadv.adk2949

This paper is open access.

Art/sci projects (+ related events) in Vancouver

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There are a couple of art/science (or sciart projects) available for viewing in Vancouver, Canada which I’m listing in what is roughly in date order with a few out-of-order additions at the end including a January 18, 2018 movie screening.

Art/sci exhibitions

From the Curiosity Collider calendar of art + sci events around town,

Work in Progress: The Making of A Science Illustrator

When: 24 Nov 2017 – 24 Jan 2018 [emphasis mine]

Where: Creative Coworkers, 343 Railway St, Vancouver, BC V6A 1A4, Canada (map)

Description:  Science illustrator Jen Burgess graduated from California State University Monterey Bay’s renowned science illustration program in 2015, and since then the varied body of work she created has been idle in flat files. When the opportunity arose to share this work in person and find it some new homes, she could not resist.

The work is primarily natural history subject matter, in a variety of media including graphite, pen and ink, coloured pencil, watercolour, gouache, acrylic, and digital. To reflect the location of the show, the theme of the show is “Work in Progress,” so adjacent to many of the pieces Jen will display some sketches, work in progress scans, photos, and/or write ups, so you can get a glimpse into the process of creating each piece. In addition, there will be work from Jen’s June 2016 self-imposed residency in Haida Gwaii, from the show entitled “On a Tangent Tear” which was on display at Emily Carr House in Victoria in September 2016. Most original works and some prints will be available for sale. Please join Jen Burgess and the team at Creative Coworkers on Friday November 24th to have a drink after work or after dinner and see some artwork before heading out to your late evening plans. There will be a cash bar and some light snacks provided. Admission is free but donations will be gratefully accepted if you would like to help Jen cover the costs of framing. Please RSVP! The show will be up from November 24 through January 24, so if you cannot make it, please stop by and see the work on your own time. There may be plans afoot for a closing reception as well, perhaps with a silent auction. Stay tuned!

The Curiosity Collider calendar also listed this event (from the Beaty Biodiversity Museum Exhibition page),

Life In Colour

Drawings by Angela Gooliaff, colouring by you
September 16, 2017 – February 18, 2018

Colour your way through nature on a giant mural that showcases ecosystems from BC and around the world.

Presented by Hemlock Printers, artist Angela Gooliaff explores keystone species in both the terrestrial and aquatic ecosystems, employing feminine symbology of peace and wisdom, and story through a giant interactive colouring book mural. “I have connected my investigation of keystone species with the adult colouring book movement as an interruption to the current story of the natural world,” says Gooliaff.

By presenting a web of life for visitors to interact with, it will be visually apparent just how biodiverse our ecosystems are and how drastic an impact the removal of one species from the environment could be. Gooliaff concludes that by “giving the audience control to own their story through colour, perhaps will get them thinking about their own story and placement within the natural world.”

Science get together

Vancouver’s H. R. MacMillan Space Centre is hosting a January 25, 2018 event in their Cosmic Night series in January 2018, from the Cosmic Nights: Beyond Our Universe event page,

Is there anything beyond the universe? What came before the Big Bang? These are questions that don’t have answers, but we have theories! This installment of Cosmic Nights we delve into theories of the Multiverse!

Cosmic Nights is a themed party featuring a custom planetarium show, music, drinks, science demonstrations, games, and a special guest lecturer – all surrounding an exciting theme. Experience the Space Centre after hours in a 19+ environment!

Cosmic Nights returns on Thursday, January 25 [2018] with Cosmic Nights: Beyond our Universe. Jump into multiple universes, the Big Bang and other ideas that are bending our cosmic minds. Select your preferred Planetarium Star Theatre show time and then come early or stay late to experience all this event has to offer!

6:30pm – 10:00pm – Drinks | Music | Games | Demonstrations I Lecture I Planetarium

7:30 or 9:00pm – Planetarium Star Theatre show: Cosmology Questions
How did it all begin? What is the Big Bang Theory and what does this theory suggest about an end to our universe? Are there universes in addition to the one we live in? How do scientists even attempt to answer these mind-blowing questions? We’ll talk about some of the biggest questions about the universe and leave you with even more ideas to explore.

8pm and 9pm – “The Multiverse” lecture by Dr. Douglas Scott
Can there be more than one universe?  Why is the Universe that we live in the way that it is?  Does our existence imply that the universe has to have certain properties? Can we imagine universes that are quite different? What does the word “multiverse” even mean? These and other questions will be tackled in this special talk (and others quite like it, all across the multiverse!).

Bio: Douglas Scott is a Professor of Physics & Astronomy at the University of British Columbia, who was trained in Edinburgh, Cambridge and Berkeley.  He specialises in cosmology- the study of the universe on the largest scales and has co-authored more than 500 papers on a wide range of both concrete and speculative astrophysical topics.

7pm-9pm – Groundstation Canada Theatre  – Cocktail Crash Course: String Theory and Quantum Gravity 
A fun, interactive science demo on string theory and quantum gravity – enough fun facts to impress at a cocktail party. Trivia prizes are also up for grabs!

TICKETS: $20 early bird tickets until January 11th, $25 after.
Tickets available online through Eventbrite. Or, save the service fee by purchasing in person at the Space Centre or by calling 604.738.7827 ext. 240.

Beer from Red Truck Beer Company, wine frrom Hester Creek Estate Winery. Games by Starlit Citadel.

19+ event. All attendees will be required to provide photo ID upon entry.

You can go here to buy tickets.

Curiosity Colllider Café

The Curiosity Collider folks themselves are holding a January 31, 2018 Collider Café with the theme: Art. Science. Fusion. (from a January 9, 2018 announcement received via email),

Save the date – our next Collider Cafe will be on Wednesday, January 31 [2018]. Speakers include:

  • Visualizing Medicine (Paige Blumer, medical illustration)
  • Art = Science in Love (Martin Krzywinski, data visualization)
  • Geo-synth Music Video (Mika McKinnon, science communication)
  • Sciart Zine (Raymond Nakamura & Katrina Wong, creative collaboration)

I found more details,

Date/Time
Date(s) – 31/01/2018
8:00 pm – 9:30 pm

Location
Café Deux Soleils
[2096 Commercial Drive, Vancouver]

Curiosity Collider calls

I believe this is the first time the organization has announced calls for submissions. There are two (from the January 9, 2018 announcement received via email),

Call for Submissions

Do you exist in both the worlds of art and science? Does your artistic practice rely on science? Does your scientific practice rely on art? We are launching two calls for submissions:

Want to receive future calls for submissions? Update your email subscription options so you don’t miss out!

More from Curiosity Collider

This January 9, 2018 announcement was very full,

Enjoy!

Complex networks to provide ‘grand unified theory’

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Trying to mesh classical physics and quantum physics together in one theory which accounts for behaviour on the macro and quantum scales has occupied scientists for decades and it seems that mathematicians have discovered a clue so solving the mystery. A Sept. 13, 2015 news item on Nanotechnology Now describes the findings,

Mathematicians investigating one of science’s great questions — how to unite the physics of the very big with that of the very small — have discovered that when the understanding of complex networks such as the brain or the Internet is applied to geometry the results match up with quantum behavior.

A Sept. 9, 2015 Queen Mary University of London press release, which originated the news item, describes the collaboration between Queen Mary and Karlsruhe Institute of Technology mathematicians,

The findings, published today (Thursday) in Scientific Reports, by researchers from Queen Mary University of London and Karlsruhe Institute of Technology, could explain one of the great problems in modern physics.

Currently ideas of gravity, developed by Einstein and Newton, explain how physics operates on a very large scale, but do not work at the sub-atomic level. Conversely, quantum mechanics works on the very small scale but does not explain the interactions of larger objects like stars. Scientists are looking for a so called ‘grand unified theory’ that joins the two, known as quantum gravity.

Several models have been proposed for how different quantum spaces are linked but most assume that the links between quantum spaces are fairly uniform, with little deviation from the average number of links between each space. The new model, which applies ideas from the theory of complex networks, has found that some quantum spaces might actually include hubs, i.e. nodes with significantly more links than others, like a particularly popular Facebook user.

Calculations run with this model show that these spaces are described by well-known quantum Fermi-Dirac, and Bose-Einstein statistics, used in quantum mechanics, indicating that they could be useful to physicists working on quantum gravity.

Dr Ginestra Bianconi, from Queen Mary University of London, and lead author of the paper, said:

“We hope that by applying our understanding of complex networks to one of the fundamental questions in physics we might be able to help explain how discrete quantum spaces emerge.

“What we can see is that space-time at the quantum-scale might be networked in a very similar way to things we are starting to understand very well like biological networks in cells, our brains and online social networks.”

Here’s a link to and a citation for the paper,

Complex Quantum Network Manifolds in Dimension d > 2 are Scale-Free by Ginestra Bianconi & Christoph Rahmede. Scientific Reports 5, Article number: 13979 (2015) doi:10.1038/srep13979 Published online: 10 September 2015

This is an open access paper.