Tag Archives: physics

Hexbug Nanos (TM), robotic insect toys, engage students in scientific research

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Caption: Hexbug Nanos used in online lab course to teach undergraduate research skills in physics. Credit: Kristopher Vargas, Pomona College

An October 21, 2022 news item on phys.org features a new approach to teaching undergraduate physics (Note: Links have been removed),

Although the sudden switch to remote and hybrid learning was seen as an enormous challenge during the COVID-19 pandemic, academic and commercial interest in creative online lab class development has since skyrocketed.

In the American Journal of Physics, researchers from Pomona College in California developed an online undergraduate physics lab course using small robotic bugs called Hexbug Nanos (TM) to engage students in scientific research from their homes.

An October 21, 2022 American Institute of Physics (AIP) news release (also on EurekAlert), which originated the news item, fills in more details,

Hexbug Nanos look like bright-colored beetles with 12 flexible legs that move rapidly in a semi-random manner. This makes collections of Hexbugs ideal models for exploring particle behavior that can be difficult for students to visualize. For the lab course, students used the Hexbugs that were mailed to them, along with a smartphone and common household items.

“We found that the pandemic-inspired reliance on simple, home-built experiments, while de-emphasizing the use of sophisticated equipment, enabled students to more effectively achieve laboratory learning objectives such as designing, implementing, and troubleshooting an experimental apparatus,” co-author Janice Hudgings said.

Students first completed a short experiment to investigate the ideal gas law, which describes how pressure, volume, and temperature of a gas are related. They used a rectangular cardboard box divided by a movable wall, made from cardboard and bamboo skewers, that slid along the length of the box.

Varying numbers of Hexbugs were placed on either side of the moving wall to model two gases of different pressures. Students used their smartphones to record the “gas molecules” colliding into the moving wall. Video tracking software was used to obtain the position of the wall as a function of time while it moved until the pressure in the two chambers equalized.

Students then proposed semesterlong research projects of their choice, designing experiments using Hexbugs to investigate concepts in statistical mechanics and electrical conduction. One project focused on the Drude model, which uses classical physics to describe the movement of electrons in a metal.

The at-home setup included a long rectangular cardboard box, with 2-inch cardboard rings at fixed locations used to model defects in the metal. Gravity is applied by raising one end of the box relative to the other end. The Hexbug “electrons” are released near the top of the box, randomly scattering from the defects as they are gradually “conducted” down the box due to the gravitational field.

“The Hexbug experiment provides a clearly visible, macroscale model of carrier transport in a wire that is consistent with the Drude model,” Hudgings said.

Similar Hexbug experiments could also be useful as online or in-person lab or lecture demonstrations in statistical mechanics, physical chemistry, biophysics, or introductory electromagnetism.

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

Using Hexbugs™ to model gas pressure and electrical conduction: A pandemic-inspired distance lab by Genevieve DiBaria, Liliana Valle, Refilwe Tanah Buac, Lucas Cunningham, Eleanor Hort, Taylor Venenciano, and Janice Hudgings. American Journal of Physics 90, 817 (2022) DOI: https://doi.org/10.1119/5.0087142 Published online: October 21, 2022

This paper is open access.

Ars Scientia talks at the University of British Columbia (UBC) in February, March, and April 2023

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The University of British Columbia (UBC; Vancouver, Canada) partnership between its Stewart Blusson Quantum Matter Institute (Blusson QMI), its Morris & Helen Belkin Art Gallery (the Belkin), and its Department of Physics and Astronomy (UBC PHAS) is known as Ars Scientia. (See my September 6, 2021 posting for more; scroll down to the Ars Scientia subhead.)

It’s been a while since I’ve seen any notices about Ars Scientia events but the Belkin Gallery announced three in a February 15, 2023 notice (received via email),

Ars Scientia Artist Talks

Room 311, Brimacombe Building, 2355 East Mall, UBC

Join us for a series of artist talks hosted at UBC’s Stewart Blusson Quantum Matter Institute (Blusson QMI). Our current cohort of Ars Scientia artists-in-residence have formed collaborative partnerships with scientists and engineers while embedded at Blusson QMI.

Tuesday, February 21 [2023] at 2 pm

JG Mair

Tuesday, March 28 [2023] at 1 pm

Scott Billings

Tuesday, April 2 [2023] at 2 pm

Timothy Taylor

IMAGE (ABOVE): AN ARS SCIENTIA COLLABORATION BETWEEN VISUAL ARTIST JG MAIR AND PHYSICIST ALANNAH HALLAS AT BLUSSON QMI; THE TWO WORKED TOGETHER IN HALLAS’S LAB TO TURN “INSIGHTFUL FAILURES” OF HIGH-ENTROPY OXIDES (A TYPE OF QUANTUM MATERIAL) INTO AN ARTIST’S MEDIUM – PAINT. PHOTO: RACHEL TOPHAM PHOTOGRAPHY.

I have found more details about the upcoming talk here on the Belkin Gallery’s Artist Talks: JG Mair, Scott Billings and Timothy Taylor events page,

Artist Talk with JG Mair, Tuesday, 21 February [2023] at 2 pm

Please join visual and media artist JG Mair for a discussion about his art practice and experiences as a collaborative participant in the Ars Scientia residency. As part of his talk, Mair will present one of his major works, Chroma Chamber, a web-based new media art installation that investigates human expectations of vision and machine algorithms by programmatically collating real-time Google image results to surround the viewer with the distilled colour of the words they speak. Visit Blusson QMI for more details. [Note 1: On the Blusson QMI page, the talk is titled: Algorithmic allegories by JG Mair; Note 2: You’ll find a map showing the Brimacombe building location.]

I wasn’t able to find out more about the other talks but I did get more information about the three artists, Belkin Gallery’s Artist Talks: JG Mair, Scott Billings and Timothy Taylor events page.

JG Mair is a Vancouver-based multidisciplinary artist and media designer specializing in mixed media, web and audio. He has a BFA from the University of Victoria and a BEd from the University of British Columbia. Mair has been working in the areas of both traditional and digital contemporary art and as a sound designer for various game studios developing titles for publishers including Apple, Electronic Arts, Microsoft and Netflix. Mair has had exhibitions and residencies in Canada, USA, South Korea and Japan.

Scott Billings is a visual artist, industrial designer and engineer based in Vancouver. His sculptures and video installations have been described as existing somewhere between cinema and automata. Centering on issues of animality, mobility and spectatorship, Billings’s work examines the mimetic relationship between the physical apparatus and the virtual motion it delivers. In what ways does the apparatus itself reveal both the mechanisms of causality and its own dormant animal quality? Billings addresses this question under the pursuit of the technological conundrum and a preoccupation with precise geometry and logic. Billings holds an MFA from the University of British Columbia, a BFA from Emily Carr University and a BASc in Mechanical Engineering from the University of Waterloo. He teaches at UBC and Emily Carr as a sessional instructor. Billings is represented by Wil Aballe Art Projects.

Timothy Taylor is an Associate Professor and Graduate Advisor at the School of Creative Writing. He is also a bestselling and award-winning author of eight book-length works of fiction and nonfiction, a prolific journalist, and creative nonfiction writer. In addition to his writing and teaching at UBC, Taylor travels widely, having in recent years spent time on assignment in China, Tibet, Japan, Dubai, Brazil, the Canadian arctic and other places. He lives in Point Grey Vancouver with his wife, his son, and a pair of Brittany Spaniels named Keaton and Murphy.

Hopefully, the talk is a little more accessible than its description.

The physics of the multiverse of madness

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The Dr. Strange movie (Dr. Strange in the Multiverse of Madness released May 6, 2022) has inspired an essay on physics. From a May 9, 2022 news item on phys.org

If you’re a fan of science fiction films, you’ll likely be familiar with the idea of alternate universes—hypothetical planes of existence with different versions of ourselves. As far from reality as it sounds, it is a question that scientists have contemplated. So just how well does the fiction stack up with the science?

The many-worlds interpretation is one idea in physics that supports the concept of multiple universes existing. It stems from the way we comprehend quantum mechanics, which defy the rules of our regular world. While it’s impossible to test and is considered an interpretation rather than a scientific theory, many physicists think it could be possible.

“When you look at the regular world, things are measurable and predictable—if you drop a ball off a roof, it will fall to the ground. But when you look on a very small scale in quantum mechanics, the rules stop applying. Instead of being predictable, it becomes about probabilities,” says Sarah Martell, Associate Professor at the School of Physics, UNSW Science.

A May 9, 2022 University of New South Wales (UNSW; Australia) press release originated the news item,

The fundamental quantum equation – called a wave function – shows a particle inhabiting many possible positions, with different probabilities assigned to each. If you were to attempt to observe the particle to determine its position – known in physics as ‘collapsing’ the wave function – you’ll find it in just one place. But the particle actually inhabits all the positions allowed by the wave function.

This interpretation of quantum mechanics is important, as it helps explain some of the quantum paradoxes that logic can’t answer, like why a particle can be in two places at once. While it might seem impossible to us, since we experience time and space as fixed, mathematically it adds up.

“When you make a measurement in quantum physics, you’re only measuring one of the possibilities. We can work with that mathematically, but it’s philosophically uncomfortable that the world stops being predictable,” A/Prof. Martell says.

“If you don’t get hung up on the philosophy, you simply move on with your physics. But what if the other possibility were true? That’s where this idea of the multiverse comes in.”

The quantum multiverse

Like it is depicted in many science fiction films, the many-worlds interpretation suggests our reality is just one of many. The universe supposedly splits or branches into other universes any time we take action – whether it’s a molecule moving, what you decide to eat or your choice of career. 

In physics, this is best explained through the thought experiment of Schrodinger’s cat. In the many-worlds interpretation, when the box is opened, the observer and the possibly alive cat split into an observer looking at a box with a deceased cat and one looking at a box with a live cat.

“A version of you measures one result, and a version of you measures the other result. That way, you don’t have to explain why a particular probability resulted. It’s just everything that could happen, does happen, somewhere,” A/Prof. Martell says.

“This is the logic often depicted in science fiction, like Spider-Man: Into the Spider-Verse, where five different Spider-Man exist in different universes based on the idea there was a different event that set up each one’s progress and timeline.”

This interpretation suggests that our decisions in this universe have implications for other versions of ourselves living in parallel worlds. But what about the possibility of interacting with these hypothetical alternate universes?

According to the many-worlds interpretation, humans wouldn’t be able to interact with parallel universes as they do in films – although science fiction has creative licence to do so.

“It’s a device used all the time in comic books, but it’s not something that physics would have anything to say about,” A/Prof. Martell says. “But I love science fiction for the creativity and the way that little science facts can become the motivation for a character or the essential crisis in a story with characters like Doctor Strange.”

“If for nothing else, science fiction can help make science more accessible, and the more we get people talking about science, the better,” A/Prof. Martell says.

“I think we do ourselves a lot of good by putting hooks out there that people can grab. So, if we can get people interested in science through popular culture, they’ll be more interested in the science we do.” 

The university also offers a course as this October 6, 2020 UNSW press release reveals,

From the morality plays in Star Trek, to the grim futures in Black Mirror, fiction can help explore our hopes – and fears – of the role science might play in our futures.

But sci-fi can be more than just a source of entertainment. When fiction gets the science right (or right enough), sci-fi can also be used to make science accessible to broader audiences. 

“Sci-fi can help relate science and technology to the lived human experience,” says Dr Maria Cunningham, a radio astronomer and senior lecturer in UNSW Science’s School of Physics. 

“Storytelling can make complex theories easier to visualise, understand and remember.”

Dr Cunningham – a sci-fi fan herself – convenes ‘Brave New World’: a course on science fact and fiction aimed at students from a non-scientific background. The course explores the relationship between literature, science, and society, using case studies like Futurama and MacGyver.

She says her own interest in sci-fi long predates her career in science.

“Fiction can help get people interested in science – sometimes without them even knowing it,” says Dr Cunningham.

“Sci-fi has the potential to increase the science literacy of the general population.”

Here, Dr Cunningham shares three tricky physics concepts best explained through science fiction (spoilers ahead).

Cunningham goes on to discuss the Universal Speed Limit, Time Dilation, and, yes, the Many Worlds Interpretation.

The course, “Brave New World: Science Fiction, Science Fact and the Future – GENS4015” is still offered but do check the link to make sure it takes you to the latest version (I found 2023). One more thing, it is offered wholly on the internet.

Physics of a singing saw could lead to applications in sensing, nanoelectronics, photonics, etc.

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I’d forgotten how haunting a musical saw can sound,

An April 22, 2022 news item on Nanowerk announces research into the possibilities of a singing saw,

The eerie, ethereal sound of the singing saw has been a part of folk music traditions around the globe, from China to Appalachia, since the proliferation of cheap, flexible steel in the early 19th century. Made from bending a metal hand saw and bowing it like a cello, the instrument reached its heyday on the vaudeville stages of the early 20th century and has seen a resurgence thanks, in part, to social media.

As it turns out, the unique mathematical physics of the singing saw may hold the key to designing high quality resonators for a range of applications.

In a new paper, a team of researchers from the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) and the Department of Physics used the singing saw to demonstrate how the geometry of a curved sheet, like curved metal, could be tuned to create high-quality, long-lasting oscillations for applications in sensing, nanoelectronics, photonics and more.

An April 21, 2022 Harvard University John A. Paulson School of Engineering and Applied Sciences (SEAS) news release by Leah Burrows (also on EurekAlert but published on April 22, 2022) delves further into physics of singing saws,

“Our research offers a robust principle to design high-quality resonators independent of scale and material, from macroscopic musical instruments to nanoscale devices, simply through a combination of geometry and topology,” said L Mahadevan, the Lola England de Valpine Professor of Applied Mathematics, of Organismic and Evolutionary Biology, and of Physics and senior author of the study.

While all musical instruments are acoustic resonators of a kind, none work quite like the singing saw.

“How the singing saw sings is based on a surprising effect,” said Petur Bryde, a graduate student at SEAS and co-first author of the paper. “When you strike a flat elastic sheet, such as a sheet of metal, the entire structure vibrates. The energy is quickly lost through the boundary where it is held, resulting in a dull sound that dissipates quickly. The same result is observed if you curve it into a J-shape. But, if you bend the sheet into an S-shape, you can make it vibrate in a very small area, which produces a clear, long-lasting tone.”

The geometry of the curved saw creates what musicians call the sweet spot and what physicists call localized vibrational modes — a confined area on the sheet which resonates without losing energy at the edges.

Importantly, the specific geometry of the S-curve doesn’t matter. It could be an S with a big curve at the top and a small curve at the bottom or visa versa. 

“Musicians and researchers have known about this robust effect of geometry for some time, but the underlying mechanisms have remained a mystery,” said Suraj Shankar, a Harvard Junior Fellow in Physics and SEAS and co-first author of the study.  “We found a mathematical argument that explains how and why this robust effect exists with any shape within this class, so that the details of the shape are unimportant, and the only fact that matters is that there is a reversal of curvature along the saw.”

Shankar, Bryde and Mahadevan found that explanation via an analogy to very different class of physical systems — topological insulators. Most often associated with quantum physics, topological insulators are materials that conduct electricity in their surface or edge but not in the middle and no matter how you cut these materials, they will always conduct on their edges.

“In this work, we drew a mathematical analogy between the acoustics of bent sheets and these quantum and electronic systems,” said Shankar.

By using the mathematics of topological systems, the researchers found that the localized vibrational modes in the sweet spot of singing saw were governed by a topological parameter that can be computed and which relies on nothing more than the existence of two opposite curves in the material. The sweet spot then behaves like an internal “edge” in the saw.

“By using experiments, theoretical and numerical analysis, we showed that the S-curvature in a thin shell can localize topologically-protected modes at the ‘sweet spot’ or inflection line, similar to exotic edge states in topological insulators,” said Bryde. “This phenomenon is material independent, meaning it will appear in steel, glass or even graphene.”

The researchers also found that they could tune the localization of the mode by changing the shape of the S-curve, which is important in applications such as sensing, where you need a resonator that is tuned to very specific frequencies.

Next, the researchers aim to explore localized modes in doubly curved structures, such as bells and other shapes.

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

Geometric control of topological dynamics in a singing saw by Suraj Shankar, Petur Bryde, and L. Mahadevan. The Proceedings of the National Academy of Sciences (PNAS) April 21, 2022 | 119 (17) e2117241119 DOI: https://doi.org/10.1073/pnas.2117241119

This paper is open (free) access.

Quantum Mechanics & Gravity conference (August 15 – 19, 2022) launches Vancouver (Canada)-based Quantum Gravity Institute and more

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I received (via email) a July 21, 2022 news release about the launch of a quantum science initiative in Vancouver (BTW, I have more about the Canadian quantum scene later in this post),

World’s top physicists unite to tackle one of Science’s greatest
mysteries

Vancouver-based Quantum Gravity Society leads international quest to
discover Theory of Quantum Gravity

Vancouver, B.C. (July 21, 2022): More than two dozen of the world’s
top physicists, including three Nobel Prize winners, will gather in
Vancouver this August for a Quantum Gravity Conference that will host
the launch a Vancouver-based Quantum Gravity Institute (QGI) and a
new global research collaboration that could significantly advance our
understanding of physics and gravity and profoundly change the world as
we know it.

For roughly 100 years, the world’s understanding of physics has been
based on Albert Einstein’s General Theory of Relativity (GR), which
explored the theory of space, time and gravity, and quantum mechanics
(QM), which focuses on the behaviour of matter and light on the atomic
and subatomic scale. GR has given us a deep understanding of the cosmos,
leading to space travel and technology like atomic clocks, which govern
global GPS systems. QM is responsible for most of the equipment that
runs our world today, including the electronics, lasers, computers, cell
phones, plastics, and other technologies that support modern
transportation, communications, medicine, agriculture, energy systems
and more.

While each theory has led to countless scientific breakthroughs, in many
cases, they are incompatible and seemingly contradictory. Discovering a
unifying connection between these two fundamental theories, the elusive
Theory of Quantum Gravity, could provide the world with a deeper
understanding of time, gravity and matter and how to potentially control
them. It could also lead to new technologies that would affect most
aspects of daily life, including how we communicate, grow food, deliver
health care, transport people and goods, and produce energy.

“Discovering the Theory of Quantum Gravity could lead to the
possibility of time travel, new quantum devices, or even massive new
energy resources that produce clean energy and help us address climate
change,” said Philip Stamp, Professor, Department of Physics and
Astronomy, University of British Columbia, and Visiting Associate in
Theoretical Astrophysics at Caltech [California Institute of Technology]. “The potential long-term ramifications of this discovery are so incredible that life on earth 100
years from now could look as miraculous to us now as today’s
technology would have seemed to people living 100 years ago.”

The new Quantum Gravity Institute and the conference were founded by the
Quantum Gravity Society, which was created in 2022 by a group of
Canadian technology, business and community leaders, and leading
physicists. Among its goals are to advance the science of physics and
facilitate research on the Theory of Quantum Gravity through initiatives
such as the conference and assembling the world’s leading archive of
scientific papers and lectures associated with the attempts to reconcile
these two theories over the past century.

Attending the Quantum Gravity Conference in Vancouver (August 15-19 [2022])
will be two dozen of the world’s top physicists, including Nobel
Laureates Kip Thorne, Jim Peebles and Sir Roger Penrose, as well as
physicists Baron Martin Rees, Markus Aspelmeyer, Viatcheslav Mukhanov
and Paul Steinhardt. On Wednesday, August 17, the conference will be
open to the public, providing them with a once-in-a-lifetime opportunity
to attend keynote addresses from the world’s pre-eminent physicists.
… A noon-hour discussion on the importance of the
research will be delivered by Kip Thorne, the former Feynman Professor
of physics at Caltech. Thorne is well known for his popular books, and
for developing the original idea for the 2014 film “Interstellar.” He
was also crucial to the development of the book “Contact” by Carl Sagan,
which was also made into a motion picture.

“We look forward to welcoming many of the world’s brightest minds to
Vancouver for our first Quantum Gravity Conference,” said Frank
Giustra, CEO Fiore Group and Co-Founder, Quantum Gravity Society. “One
of the goals of our Society will be to establish Vancouver as a
supportive home base for research and facilitate the scientific
collaboration that will be required to unlock this mystery that has
eluded some of the world’s most brilliant physicists for so long.”

“The format is key,” explains Terry Hui, UC Berkley Physics alumnus
and Co-Founder, Quantum Gravity Society [and CEO of Concord Pacific].
“Like the Solvay Conference nearly 100 years ago, the Quantum Gravity
Conference will bring top scientists together in salon-style gatherings. The
relaxed evening format following the conference will reduce barriers and
allow these great minds to freely exchange ideas. I hope this will help accelerate
the solution of this hundred-year bottleneck between theories relatively
soon.”

“As amazing as our journey of scientific discovery has been over the
past century, we still have so much to learn about how the universe
works on a macro, atomic and subatomic level,” added Paul Lee,
Managing Partner, Vanedge Capital, and Co-Founder, Quantum Gravity
Society. “New experiments and observations capable of advancing work
on this scientific challenge are becoming increasingly possible in
today’s physics labs and using new astronomical tools. The Quantum
Gravity Society looks forward to leveraging that growing technical
capacity with joint theory and experimental work that harnesses the
collective expertise of the world’s great physicists.”

About Quantum Gravity Society

Quantum Gravity Society was founded in Vancouver, Canada in 2020 by a
group of Canadian business, technology and community leaders, and
leading international physicists. The Society’s founding members
include Frank Giustra (Fiore Group), Terry Hui (Concord Pacific), Paul
Lee and Moe Kermani (Vanedge Capital) and Markus Frind (Frind Estate
Winery), along with renowned physicists Abhay Ashtekar, Sir Roger
Penrose, Philip Stamp, Bill Unruh and Birgitta Whaley. For more
information, visit Quantum Gravity Society.

About the Quantum Gravity Conference (Vancouver 2022)

The inaugural Quantum Gravity Conference (August 15-19 [2022]) is presented by
Quantum Gravity Society, Fiore Group, Vanedge Capital, Concord Pacific,
The Westin Bayshore, Vancouver and Frind Estate Winery. For conference
information, visit conference.quantumgravityinstitute.ca. To
register to attend the conference, visit Eventbrite.com.

The front page on the Quantum Gravity Society website is identical to the front page for the Quantum Mechanics & Gravity: Marrying Theory & Experiment conference website. It’s probable that will change with time.

This seems to be an in-person event only.

The site for the conference is in an exceptionally pretty location in Coal Harbour and it’s close to Stanley Park (a major tourist attraction),

The Westin Bayshore, Vancouver
1601 Bayshore Drive
Vancouver, BC V6G 2V4
View map

Assuming that most of my readers will be interested in the ‘public’ day, here’s more from the Wednesday, August 17, 2022 registration page on Eventbrite,

Tickets:

  • Corporate Table of 8 all day access – includes VIP Luncheon: $1,100
  • Ticket per person all day access – includes VIP Luncheon: $129
  • Ticket per person all day access (no VIP luncheon): $59
  • Student / Academia Ticket – all day access (no VIP luncheon): $30

Date:

Wednesday, August 17, 2022 @ 9:00 a.m. – 5:15 p.m. (PT)

Schedule:

  • Registration Opens: 8:00 a.m.
  • Morning Program: 9:00 a.m. – 12:30 p.m.
  • VIP Lunch: 12:30 p.m. – 2:30 p.m.
  • Afternoon Program: 2:30 p.m. – 4:20 p.m.
  • Public Discussion / Debate: 4:20 p.m. – 5:15 p.m.

Program:

9:00 a.m. Session 1: Beginning of the Universe

  • Viatcheslav Mukhanov – Theoretical Physicist and Cosmologist, University of Munich
  • Paul Steinhardt – Theoretical Physicist, Princeton University

Session 2: History of the Universe

  • Jim Peebles, 2019 Nobel Laureate, Princeton University
  • Baron Martin Rees – Cosmologist and Astrophysicist, University of Cambridge
  • Sir Roger Penrose, 2020 Nobel Laureate, University of Oxford (via zoom)

12:30 p.m. VIP Lunch Session: Quantum Gravity — Why Should We Care?

  • Kip Thorne – 2017 Nobel Laureate, Executive Producer of blockbuster film “Interstellar”

2:30 p.m. Session 3: What do Experiments Say?

  • Markus Aspelmeyer – Experimental Physicist, Quantum Optics and Optomechanics Leader, University of Vienna
  • Sir Roger Penrose – 2020 Nobel Laureate (via zoom)

Session 4: Time Travel

  • Kip Thorne – 2017 Nobel Laureate, Executive Producer of blockbuster film “Interstellar”

Event Partners

  • Quantum Gravity Society
  • Westin Bayshore
  • Fiore Group
  • Concord Pacific
  • VanEdge Capital
  • Frind Estate Winery

Marketing Partners

  • BC Business Council
  • Greater Vancouver Board of Trade

Please note that Sir Roger Penrose will be present via Zoom but all the others will be there in the room with you.

Given that Kip Thorne won his 2017 Nobel Prize in Physics (with Rainer Weiss and Barry Barish) for work on gravitational waves, it’s surprising there’s no mention of this in the publicity for a conference on quantum gravity. Finding gravitational waves in 2016 was a very big deal (see Josh Fischman’s and Steve Mirsky’s February 11, 2016 interview with Kip Thorne for Scientific American).

Some thoughts on this conference and the Canadian quantum scene

This conference has a fascinating collection of players. Even I recognized some of the names, e.g., Penrose, Rees, Thorne.

The academics were to be expected and every presenter is an academic, often with their own Wikipedia page. Weirdly, there’s no one from the Perimeter Institute Institute for Theoretical Physics or TRIUMF (a national physics laboratory and centre for particle acceleration) or from anywhere else in Canada, which may be due to their academic specialty rather than an attempt to freeze out Canadian physicists. In any event, the conference academics are largely from the US (a lot of them from CalTech and Stanford) and from the UK.

The business people are a bit of a surprise. The BC Business Council and the Greater Vancouver Board of Trade? Frank Giustra who first made his money with gold mines, then with Lionsgate Entertainment, and who continues to make a great deal of money with his equity investment company, Fiore Group? Terry Hui, Chief Executive Office of Concord Pacific, a real estate development company? VanEdge Capital, an early stage venture capital fund? A winery? Missing from this list is D-Wave Systems, Canada’s quantum calling card and local company. While their area of expertise is quantum computing, I’d still expect to see them present as sponsors. *ETA December 6, 2022: I just looked at the conference page again and D-Wave is now listed as a sponsor.*

The academics? These people are not cheap dates (flights, speaker’s fees, a room at the Bayshore, meals). This is a very expensive conference and $129 for lunch and a daypass is likely a heavily subsidized ticket.

Another surprise? No government money/sponsorship. I don’t recall seeing another academic conference held in Canada without any government participation.

Canadian quantum scene

A National Quantum Strategy was first announced in the 2021 Canadian federal budget and reannounced in the 2022 federal budget (see my April 19, 2022 posting for a few more budget details).. Or, you may find this National Quantum Strategy Consultations: What We Heard Report more informative. There’s also a webpage for general information about the National Quantum Strategy.

As evidence of action, the Natural Science and Engineering Research Council of Canada (NSERC) announced new grant programmes made possible by the National Quantum Strategy in a March 15, 2022 news release,

Quantum science and innovation are giving rise to promising advances in communications, computing, materials, sensing, health care, navigation and other key areas. The Government of Canada is committed to helping shape the future of quantum technology by supporting Canada’s quantum sector and establishing leadership in this emerging and transformative domain.

Today [March 15, 2022], the Honourable François-Philippe Champagne, Minister of Innovation, Science and Industry, is announcing an investment of $137.9 million through the Natural Sciences and Engineering Research Council of Canada’s (NSERC) Collaborative Research and Training Experience (CREATE) grants and Alliance grants. These grants are an important next step in advancing the National Quantum Strategy and will reinforce Canada’s research strengths in quantum science while also helping to develop a talent pipeline to support the growth of a strong quantum community.

Quick facts

Budget 2021 committed $360 million to build the foundation for a National Quantum Strategy, enabling the Government of Canada to build on previous investments in the sector to advance the emerging field of quantum technologies. The quantum sector is key to fuelling Canada’s economy, long-term resilience and growth, especially as technologies mature and more sectors harness quantum capabilities.

Development of quantum technologies offers job opportunities in research and science, software and hardware engineering and development, manufacturing, technical support, sales and marketing, business operations and other fields.

The Government of Canada also invested more than $1 billion in quantum research and science from 2009 to 2020—mainly through competitive granting agency programs, including Natural Sciences and Engineering Research Council of Canada programs and the Canada First Research Excellence Fund—to help establish Canada as a global leader in quantum science.

In addition, the government has invested in bringing new quantum technologies to market, including investments through Canada’s regional development agencies, the Strategic Innovation Fund and the National Research Council of Canada’s Industrial Research Assistance Program.

Bank of Canada, cryptocurrency, and quantum computing

My July 25, 2022 posting features a special project, Note: All emphases are mine,

… (from an April 14, 2022 HKA Marketing Communications news release on EurekAlert),

Multiverse Computing, a global leader in quantum computing solutions for the financial industry and beyond with offices in Toronto and Spain, today announced it has completed a proof-of-concept project with the Bank of Canada through which the parties used quantum computing to simulate the adoption of cryptocurrency as a method of payment by non-financial firms.

“We are proud to be a trusted partner of the first G7 central bank to explore modelling of complex networks and cryptocurrencies through the use of quantum computing,” said Sam Mugel, CTO [Chief Technical Officer] at Multiverse Computing. “The results of the simulation are very intriguing and insightful as stakeholders consider further research in the domain. Thanks to the algorithm we developed together with our partners at the Bank of Canada, we have been able to model a complex system reliably and accurately given the current state of quantum computing capabilities.”

Multiverse Computing conducted its innovative work related to applying quantum computing for modelling complex economic interactions in a research project with the Bank of Canada. The project explored quantum computing technology as a way to simulate complex economic behaviour that is otherwise very difficult to simulate using traditional computational techniques.

By implementing this solution using D-Wave’s annealing quantum computer, the simulation was able to tackle financial networks as large as 8-10 players, with up to 2^90 possible network configurations. Note that classical computing approaches cannot solve large networks of practical relevance as a 15-player network requires as many resources as there are atoms in the universe.

Quantum Technologies and the Council of Canadian Academies (CCA)

In a May 26, 2022 blog posting the CCA announced its Expert Panel on Quantum Technologies (they will be issuing a Quantum Technologies report),

The emergence of quantum technologies will impact all sectors of the Canadian economy, presenting significant opportunities but also risks. At the request of the National Research Council of Canada (NRC) and Innovation, Science and Economic Development Canada (ISED), the Council of Canadian Academies (CCA) has formed an Expert Panel to examine the impacts, opportunities, and challenges quantum technologies present for Canadian industry, governments, and Canadians. Raymond Laflamme, O.C., FRSC, Canada Research Chair in Quantum Information and Professor in the Department of Physics and Astronomy at the University of Waterloo, will serve as Chair of the Expert Panel.

“Quantum technologies have the potential to transform computing, sensing, communications, healthcare, navigation and many other areas,” said Dr. Laflamme. “But a close examination of the risks and vulnerabilities of these technologies is critical, and I look forward to undertaking this crucial work with the panel.”

As Chair, Dr. Laflamme will lead a multidisciplinary group with expertise in quantum technologies, economics, innovation, ethics, and legal and regulatory frameworks. The Panel will answer the following question:

In light of current trends affecting the evolution of quantum technologies, what impacts, opportunities and challenges do these present for Canadian industry, governments and Canadians more broadly?

The Expert Panel on Quantum Technologies:

Raymond Laflamme, O.C., FRSC (Chair), Canada Research Chair in Quantum Information; the Mike and Ophelia Lazaridis John von Neumann Chair in Quantum Information; Professor, Department of Physics and Astronomy, University of Waterloo

Sally Daub, Founder and Managing Partner, Pool Global Partners

Shohini Ghose, Professor, Physics and Computer Science, Wilfrid Laurier University; NSERC Chair for Women in Science and Engineering

Paul Gulyas, Senior Innovation Executive, IBM Canada

Mark W. Johnson, Senior Vice-President, Quantum Technologies and Systems Products, D-Wave Systems

Elham Kashefi, Professor of Quantum Computing, School of Informatics, University of Edinburgh; Directeur de recherche au CNRS, LIP6 Sorbonne Université

Mauritz Kop, Fellow and Visiting Scholar, Stanford Law School, Stanford University

Dominic Martin, Professor, Département d’organisation et de ressources humaines, École des sciences de la gestion, Université du Québec à Montréal

Darius Ornston, Associate Professor, Munk School of Global Affairs and Public Policy, University of Toronto

Barry Sanders, FRSC, Director, Institute for Quantum Science and Technology, University of Calgary

Eric Santor, Advisor to the Governor, Bank of Canada

Christian Sarra-Bournet, Quantum Strategy Director and Executive Director, Institut quantique, Université de Sherbrooke

Stephanie Simmons, Associate Professor, Canada Research Chair in Quantum Nanoelectronics, and CIFAR Quantum Information Science Fellow, Department of Physics, Simon Fraser University

Jacqueline Walsh, Instructor; Director, initio Technology & Innovation Law Clinic, Dalhousie University

You’ll note that both the Bank of Canada and D-Wave Systems are represented on this expert panel.

The CCA Quantum Technologies report (in progress) page can be found here.

Does it mean anything?

Since I only skim the top layer of information (disparagingly described as ‘high level’ by the technology types I used to work with), all I can say is there’s a remarkable level of interest from various groups who are self-organizing. (The interest is international as well. I found the International Society for Quantum Gravity [ISQG], which had its first meeting in 2021.)

I don’t know what the purpose is other than it seems the Canadian focus seems to be on money. The board of trade and business council have no interest in primary research and the federal government’s national quantum strategy is part of Innovation, Science and Economic Development (ISED) Canada’s mandate. You’ll notice ‘science’ is sandwiched between ‘innovation’, which is often code for business, and economic development.

The Bank of Canada’s monetary interests are quite obvious.

The Perimeter Institute mentioned earlier was founded by Mike Lazaridis (from his Wikipedia entry) Note: Links have been removed,

… a Canadian businessman [emphasis mine], investor in quantum computing technologies, and founder of BlackBerry, which created and manufactured the BlackBerry wireless handheld device. With an estimated net worth of US$800 million (as of June 2011), Lazaridis was ranked by Forbes as the 17th wealthiest Canadian and 651st in the world.[4]

In 2000, Lazaridis founded and donated more than $170 million to the Perimeter Institute for Theoretical Physics.[11][12] He and his wife Ophelia founded and donated more than $100 million to the Institute for Quantum Computing at the University of Waterloo in 2002.[8]

That Institute for Quantum Computing? There’s an interesting connection. Raymond Laflamme, the chair for the CCA expert panel, was its director for a number of years and he’s closely affiliated with the Perimeter Institute. (I’m not suggesting anything nefarious or dodgy. It’s a small community in Canada and relationships tend to be tightly interlaced.) I’m surprised he’s not part of the quantum mechanics and gravity conference but that could have something to do with scheduling.

One last interesting bit about Laflamme, from his Wikipedia entry, Note: Links have been removed)

As Stephen Hawking’s PhD student, he first became famous for convincing Hawking that time does not reverse in a contracting universe, along with Don Page. Hawking told the story of how this happened in his famous book A Brief History of Time in the chapter The Arrow of Time.[3] Later on Laflamme made a name for himself in quantum computing and quantum information theory, which is what he is famous for today.

Getting back to the Quantum Mechanics & Gravity: Marrying Theory & Experiment, the public day looks pretty interesting and when is the next time you’ll have a chance to hobnob with all those Nobel Laureates?

Celebrate World Quantum Day (April 14, 2022) with Conversations at the Perimeter

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Canada’s Perimeter Institute Institute for Theoretical Physics (PI) is launching a podcast, Conversations from the Perimeter, on World Quantum Day (April 14, 2022).

Here are some details from an April 7, 2022 PI news release (a shortened version was received via email),

Get to know some of the brilliant minds trying to solve nature’s deepest mysteries.

In 2020, our long-running public lecture series evolved to deliver the same cutting-edge physics talks in a virtual webcast format. Now, we’re excited to launch the next evolution in the series.

Starting next week, [April 14, 2022] Conversations at the Perimeter will take you into the depths of dark matter, black holes, and beyond as we introduce you to researchers working at the forefront of science.

The series is co-hosted by quantum physicist and lecturer Lauren Hayward and journalist-turned-science communicator Colin Hunter. In each episode, they chat with a guest scientist about their research, their motivations, the challenges they encounter, and the drive that keeps them searching for answers. 

Conversations at the Perimeter is the next evolution in Perimeter Institute’s long-running public lecture series, which changed in 2020 (like so much else) when in-person lectures became impossible. The new format allows Perimeter to showcase brilliant scientists and their ideas in a way that is interactive, lively, and safe. 

As always, the talks will be freely available on Perimeter’s YouTube channel – and, for the first time, they’ll be available via podcast, on all the major podcast channels. 

The first season will consist of 10 episodes, released every Thursday beginning on April 14 [2022] (World Quantum Day). Season one guests include loop quantum gravity founder Carlo Rovelli, theoretical cosmologist (and social media star) Katie Mack, quantum information scientist Raymond Laflamme, and more!

Happy world Quantum Day!

A little more Christmas: “Kitty Q” award-winning game app explains quantum physics

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Caption: Kitty Q. Credit: Philipp Stollenmayer

It kind of reminds me of ‘Hello Kitty’. However, you can see in this larger version that 1/2 of this cat has a skeletal paw giving it kinship to Erwin Schrödinger’s cat.

The app was first announced in a September 28, 2021University of Würzburg press release on EurekAlert,

Cute but half-dead

Ding, dong. There is a box in front of the door. And inside there is … a cute but half-dead cat! The main character of the new game app “Kitty Q” of the Würzburg-Dresden Cluster of Excellence ct.qmat–Complexity and Topology in Quantum Matter of the Universities of Würzburg and Dresden accompanies children and teenagers aged 11 and older into the crazy quantum world. The adventure is intended to primarily get girls excited about the fascinating phenomena of quantum physics. The model for the lovingly designed “Kitty Q” is a popular thought experiment in quantum mechanics by Nobel Prize winner Erwin Schrödinger (1887 – 1961), known as Schrödinger’s cat–alive and dead at the same time.

But fun first

Those who embark on adventure with “Kitty Q” can tinker, try out, experiment on their smartphones and solve more than 20 attractive brainteasers along the way. Importantly, the kids don’t have to be math whizzes or physics geniuses. After all, “Kitty Q” is all about fun!

“The game is an Escape Game after all, even though it conveys quite serious scientific content. It is intended to awaken curiosity and encourage trying things out. Indeed, that’s what science is all about: discovering new things by thinking and experimenting,” says the app designer Philipp Stollenmayer, explaining the character of the game app he developed. “The gamers experience an exciting world, collect stickers and design their cat individually. Just like in real life, you need to work in the quantum world to acquire your knowledge. It was important to me to show how much fun this could be!” “Kitty Q” is the first commissioned project for Stollenmayer who otherwise works exclusively on his own and has won all the major prizes in game design since 2013–most recently the Apple Design Award 2020.

Donuts, randomness, cold chips

The focus of the game app is on the more than 20 puzzles based on scientific facts from quantum physics–the concept of chance, donuts as “symbol” of topological quantum physics, cold chips for revolutionary high-tech and quantum computers, to name a few examples. Those who like can access background knowledge, edited in a popular way, as “Kittypedia articles” as soon as a puzzle has been solved.

“The research field of our Cluster of Excellence ct.qmat–topological quantum physics–promises revolutionary insights and groundbreaking developments. But the subject is still so young that it will take quite a few years before it arrives in classroom. We are trying to bridge this gap with the app,” explains Matthias Vojta, Professor of Theoretical Solid State Physics at Technische Universität (TU) Dresden and spokesperson of the Dresden branch of the ct.qmat research alliance. Topological quantum physics uses topology–a branch of mathematics–as a tool to theoretically describe the interior of novel quantum materials. This is a Nobel Prize-winning research approach that ct.qmat applies.

Attracting female physicists

The game takes unusual approaches to attract children and teens to mathematics, computer science, natural and technical sciences (STEM)–and especially to quantum physics–at an early age. The focus is particularly on girls, since young women are underrepresented in physics degree programs in particular. The game targets at an age group in which interest in physics and the natural sciences is shaped.

“At least since the German government passed the economic stimulus package last year and more than two billion euros flow into German quantum research, our field of science has arrived in society. Unfortunately, there is already a significant shortage of skilled personnel in physics. With our mobile game, we want to make physics an experience, appeal to tomorrow’s researchers and Nobel Prize winners, and thus keep Germany’s high tech economy running,” comments the spokesperson of the Würzburg branch Ralph Claessen, Professor of Experimental Physics at Julius Maximilian University (JMU) Würzburg.

The latest about Kitty Q can be found in a December 21, 2021 Technische Universität Dresden press release on EurekAlert,

“We are thrilled that our app ‘Kitty Q’ was honored as a ‘Serious Game’ at the Games Innovation Award Saxony. The references to quantum physics are always there, but our game can also be played completely without math or physics know-how. Detailed background knowledge is optionally available in the ‘Kittypedia’. We invested a lot of work in compiling these generally understandable encyclopedia articles on quantum physics. We are immensely pleased that this award highlights the aspect of knowledge transfer in particular,” explains Prof. Matthias Vojta, Professor of Theoretical Solid State Physics at Technische Universität (TU) Dresden and spokesperson of the Dresden branch of ct.qmat.

The next round of ” Kitty Q” is now starting with the project “QUANTube–Science Break”: “From January 2022 on, our young researchers will be answering questions about quantum physics sent to us by players from all over the world in entertaining explanatory videos. We are challenging ourselves in terms of easy comprehensibility and language suitable for children and young people,” explains the spokesperson of the Würzburg branch of the Cluster Prof. Ralph Claessen, Professor of Experimental Physics at Julius Maximilian University (JMU) Würzburg. “The fact that the DFG has now awarded a Community Prize to ‘QUANTube’ is a special honor for us because it is awarded by marketing experts from the research community and not by a specialist jury. Perhaps there is even some curiosity about our implementation behind the vote.”

The game app “Kitty Q” has so far been downloaded 65,000 times worldwide. “It’s great to see how enthusiastically people are playing and how great the feedback and ratings are. That is anything but a matter of course for a game that imparts knowledge,” says app designer Philipp Stollenmayer, who developed the game for the Würzburg-Dresden Cluster of Excellence. So far, Stollenmayer has won all the major prizes in game design for the games he has developed on his own–most recently the Apple Design Award 2020.

Answering questions from the players using video

Whoever solves a certain puzzle in the mobile game “Kitty Q–a Quantum Adventure” earns a bonus app, which can be used to ask the researchers of the Cluster of Excellence ct.qmat a question. So far, more than 45 questions on physics and quantum physics have been sent via the in-game bonus app.

All questions will be answered by the doctoral and postdoctoral researchers of the Cluster of Excellence on a topic-related basis in YouTube explanatory videos starting as of January 2022–in school break length of about five minutes and in line with the Science Year 2022, which has the motto “Inquire into a matter”. For recruiting next generation of scientists, the cluster also relies on its strong network with five non-university partner institutes: Helmholtz-Zentrum Dresden Rossendorf, Leibniz Institute for Solid State and Materials Research Dresden, Max Planck Institute for Chemical Physics of Solids Dresden, Max Planck Institute for the Physics of Complex Systems Dresden and Bavarian Center for Applied Energy Research.

“QUANTube–Science Break” #1 Schrödinger’s Cat

The first QUANTube episode answers questions about “Schrödinger’s cat”. The video will be published on the YouTube channel of the Cluster of Excellence ct.qmat at the end of January: https://www.youtube.com/c/ClusterofExcellencectqmat

America, England, Vietnam, China, and Germany–questions about cats were sent in from all over the world: What does the Q in kitty Q stand for? Why is the cat half dead? How long do cats live when they are half dead? What do the cat’s atoms look like when it is dead and alive at the same time? Why did Schrödinger use a cat and not another animal in his thought experiment in the first place?

A little preview of the new QUANTube video series is provided by a teaser video that answers the question, “What do cats actually have to do with physics?”

Here’s the QUANTube–Science Break video series teaser/preview,

You can find out more about Kitty Q (English language version) here or you can access the Katze Q (German language version) here.

How do viruses and physics go together? Find out at a Nov. 4, 2020 Perimeter Institute (PI) virtual lecture

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I got this announcement from an Oct. 29, 2020 Perimeter Institute (PI) Emmy Noether newsletter (received via email),

Catherne Beauchemin

A Physicist’s Adventures in Virology WEDNESDAY, NOVEMBER 4 at 7 pm ET [4 pm PT]

In recent years, there has been a rise in cynicism about many traditionally well-respected institutions – science, academia, news reporting, and even the concepts of experts and expertise more generally. Many people’s primary – or only – exposure to science is through biological or health science, especially during the COVID-19 pandemic.

In health research, rising cynicism has spawned the anti-vaccine movement, and a growing reliance on advice from peer networks rather than experts. In part, such movements are fuelled by several examples of provably false, so-called “scientific results,” coming about either through fraud or incompetence. While skepticism is crucial to science, cynicism rooted in a lack of trust can devalue scientific contributions.

In her lecture webcast, physicist Catherine Beauchemin will explore the erosion of trust in health research, presenting examples from influenza and COVID-19. …

I went to the A Physicist’s Adventures in Virology event and livestrream page to find this,

Two essential ingredients of the scientific method are skepticism and independent confirmation – the ability to glean for oneself whether an established theory or a new hypothesis is true or false. But not everyone has the capacity to perform the experiments to obtain such a confirmation.

Consider, for example, the costs of constructing your own Large Hadron Collider, or your ability as a non-expert to critically read and understand a scientific publication. In practice, acceptance of scientific theories is more often based on trust than on independent confirmation. When that trust is eroded, issues emerge.

Catherine Beauchemin is a Professor of Physics at Ryerson University and a Deputy Program Director in the RIKEN Interdisciplinary Theoretical and Mathematical Sciences Program in Japan. For the last 18 years, she has been developing mathematical and computational descriptions of how viruses spread from cell to cell, a field she calls “virophysics.”

In her November 4 [2020] Perimeter Public Lecture webcast, Beauchemin will highlight some of the issues that have eroded trust in health research, presenting examples from influenza and COVID-19. She will show why she believes many of these issues have their root in the fact that hypotheses in health research are formulated as words rather than mathematical expressions – and why a dose of physics may be just the prescription we need.

Enjoy!

Loop quantum cosmology connects the tiniest with the biggest in a cosmic tango

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Caption: Tiny quantum fluctuations in the early universe explain two major mysteries about the large-scale structure of the universe, in a cosmic tango of the very small and the very large. A new study by researchers at Penn State used the theory of quantum loop gravity to account for these mysteries, which Einstein’s theory of general relativity considers anomalous.. Credit: Dani Zemba, Penn State

A July 29, 2020 news item on ScienceDaily announces a study showing that quantum loop cosmology can account for some large-scale mysteries,

While [1] Einstein’s theory of general relativity can explain a large array of fascinating astrophysical and cosmological phenomena, some aspects of the properties of the universe at the largest-scales remain a mystery. A new study using loop quantum cosmology — a theory that uses quantum mechanics to extend gravitational physics beyond Einstein’s theory of general relativity — accounts for two major mysteries. While the differences in the theories occur at the tiniest of scales — much smaller than even a proton — they have consequences at the largest of accessible scales in the universe. The study, which appears online July 29 [2020] in the journal Physical Review Letters, also provides new predictions about the universe that future satellite missions could test.

A July 29, 2020 Pennsylvania State University (Penn State) news release (also on EurekAlert) by Gail McCormick, which originated the news item, describes how this work helped us avoid a crisis in cosmology,

While [2] a zoomed-out picture of the universe looks fairly uniform, it does have a large-scale structure, for example because galaxies and dark matter are not uniformly distributed throughout the universe. The origin of this structure has been traced back to the tiny inhomogeneities observed in the Cosmic Microwave Background (CMB)–radiation that was emitted when the universe was 380 thousand years young that we can still see today. But the CMB itself has three puzzling features that are considered anomalies because they are difficult to explain using known physics.

“While [3] seeing one of these anomalies may not be that statistically remarkable, seeing two or more together suggests we live in an exceptional universe,” said Donghui Jeong, associate professor of astronomy and astrophysics at Penn State and an author of the paper. “A recent study in the journal Nature Astronomy proposed an explanation for one of these anomalies that raised so many additional concerns, they flagged a ‘possible crisis in cosmology‘ [emphasis mine].’ Using quantum loop cosmology, however, we have resolved two of these anomalies naturally, avoiding that potential crisis.”

Research over the last three decades has greatly improved our understanding of the early universe, including how the inhomogeneities in the CMB were produced in the first place. These inhomogeneities are a result of inevitable quantum fluctuations in the early universe. During a highly accelerated phase of expansion at very early times–known as inflation–these primordial, miniscule fluctuations were stretched under gravity’s influence and seeded the observed inhomogeneities in the CMB.

“To understand how primordial seeds arose, we need a closer look at the early universe, where Einstein’s theory of general relativity breaks down,” said Abhay Ashtekar, Evan Pugh Professor of Physics, holder of the Eberly Family Chair in Physics, and director of the Penn State Institute for Gravitation and the Cosmos. “The standard inflationary paradigm based on general relativity treats space time as a smooth continuum. Consider a shirt that appears like a two-dimensional surface, but on closer inspection you can see that it is woven by densely packed one-dimensional threads. In this way, the fabric of space time is really woven by quantum threads. In accounting for these threads, loop quantum cosmology allows us to go beyond the continuum described by general relativity where Einstein’s physics breaks down–for example beyond the Big Bang.”

The researchers’ previous investigation into the early universe replaced the idea of a Big Bang singularity, where the universe emerged from nothing, with the Big Bounce, where the current expanding universe emerged from a super-compressed mass that was created when the universe contracted in its preceding phase. They found that all of the large-scale structures of the universe accounted for by general relativity are equally explained by inflation after this Big Bounce using equations of loop quantum cosmology.

In the new study, the researchers determined that inflation under loop quantum cosmology also resolves two of the major anomalies that appear under general relativity.

“The primordial fluctuations we are talking about occur at the incredibly small Planck scale,” said Brajesh Gupt, a postdoctoral researcher at Penn State at the time of the research and currently at the Texas Advanced Computing Center of the University of Texas at Austin. “A Planck length is about 20 orders of magnitude smaller than the radius of a proton. But corrections to inflation at this unimaginably small scale simultaneously explain two of the anomalies at the largest scales in the universe, in a cosmic tango of the very small and the very large.”

The researchers also produced new predictions about a fundamental cosmological parameter and primordial gravitational waves that could be tested during future satellite missions, including LiteBird and Cosmic Origins Explorer, which will continue improve our understanding of the early universe.

That’s a lot of ‘while’. I’ve done this sort of thing, too, and whenever I come across it later; it’s painful.

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

Alleviating the Tension in the Cosmic Microwave Background Using Planck-Scale Physics by Abhay Ashtekar, Brajesh Gupt, Donghui Jeong, and V. Sreenath. Phys. Rev. Lett. 125, 051302 DOI: https://doi.org/10.1103/PhysRevLett.125.051302 Published 29 July 2020 © 2020 American Physical Society

This paper is behind a paywall.