Events List for the Academic Year
Event Time:
Wednesday, June 12, 2024 | 8:00 am - 5:00 pm
Event Location:
UBC Scarfe & HEBB buildings
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2024-06-12T08:00:00
2024-06-14T17:00:00
Dawn VII Meeting (June 12-14)
Event Information:
We invite you to register for the Dawn VII meeting taking place right here on UBC campus in June, 2024.
Every 2-3 years, the community of physicists working with ground-based gravitational wave (GW) detectors holds a discussion-based “Dawn” meeting to plan for the future of the field.
This year the global ground-based GW community, including experts in GW detector technology, GW astrophysics, multi-messenger astronomy, cosmology, nuclear physics, and tests of general relativity, is converging in Vancouver: Blusson QMI is hosting the Dawn VII meeting June 12-13 in the Scarfe building: https://dawn7.phas.ubc.ca/
You can find a program outline here: https://dawn7.phas.ubc.ca/program/
Dawn VII will be a good introduction to challenges, opportunities, and relevant timescales for astrophysics, nuclear physics, and fundamental physics (including cosmology and tests of general relativity) we can achieve with future GW detectors, as well as the development of enabling detector technologies.
There will also be satellite workshops devoted to GW detector technology (including a workshop on thin-film coatings hosted in Brimacombe), multi-messenger astronomy with GWs, and machine learning for GW analysis (taking place in Hebb) on Friday June 14.
It should be a fun and engaging meeting - we encourage you to register! (Registration is $280, and the conference dinner in the Ponderosa Ballroom the evening of June 12 is $95.)
Best,
Jess for the Dawn VII Local Organizing Committee
-------------------------------------------------
*We encourage you to register by May 8th
Event Location:
UBC Scarfe & HEBB buildings
Event Time:
Friday, May 3, 2024 | 10:00 am - 12:00 pm
Event Location:
QMI 188 (2355 East Mall)
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2024-05-03T10:00:00
2024-05-03T12:00:00
Emergent optical and electronic properties in atomically thin rhombohedral-stacked transition metal dichalcogenides
Event Information:
Abstract:
Rhombohedral(R)-stacked TMD means the neighbouring layers are oriented in the same direction, which can be obtained through either chemical synthesis or artificial stack with a small twist. The investigation into how the stacking order determines the properties of TMD homobilayers is crucial for understanding the exotic physics observed in two-dimensional semiconductors.
Here we use various optical spectroscopy techniques to explore the emergent excitonic and correlated phenomena in both homogeneous and twisted TMD homobilayers of rhombohedral stacking. Specifically, we observe a spontaneous electrical polarization arising from the asymmetric interlayer-coupling-induced Berry phase in R-stacked MoS2 bilayer. Utilizing this polarization, we achieve an efficient and scalable photovoltaic effect in a Gr/R-MoS2/Gr heterostructure. By employing non-degenerate pump-probe photocurrent spectroscopy, we disentangle the competition between thermal and electronic effects, extracting a 2ps intrinsic photocurrent speed.
More importantly, the out-of-plane electrical polarization in R-stacked MoS2 can be switched through in-plane sliding motion, which is referred to as sliding ferroelectricity. By harnessing the coupling between electronic polarization and excitonic effects, we demonstrate an optical method to probe the domain wall motion in both R-stacked MoS2 homo-bilayer and tri-layer.
Finally, we report the discovery of a series of correlated insulating states at both integer and fractional fillings, arising from Γ-valley flat bands, in a small-angle twisted MoSe2 homo-bilayer. We observe a Mott-insulator state instead of a semi-metal on the half-filled honeycomb lattice, in contrast to the theoretical prediction based on continuum model. The observed phenomenon is consistent with the picture of semi-metal to insulator transition at large U/t limit. Our exploration on the moire homo-bilayer in rhombohedral stacking offers a new opportunity to simulate the Mott-Hubbard physics with spin SU (2) symmetry.
Event Location:
QMI 188 (2355 East Mall)
Event Time:
Monday, April 29, 2024 | 10:00 am - 12:00 pm
Event Location:
14th floor meeting room, BC Cancer Research Institute
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2024-04-29T10:00:00
2024-04-29T12:00:00
An analysis of imaging and biological effects impacting theranostic dosimetry using radiopharmaceutical pairs
Event Information:
Abstract:
Radiopharmaceutical therapy (RPT) is a safe and effective cancer treatment using alpha or beta emitting radiopharmaceuticals that specifically target cancer cells to selectively destroy cancer tissue while sparing healthy cells. Treatment can be personalized on a patient-by-patient basis using dosimetry to determine suitable administered activities for subsequent treatment cycles. Dosimetry requires obtaining quantitative single photon emission computed tomography (SPECT) images which can only be done using gamma emitting radioisotopes.
Not all therapeutic radioisotopes are suitable for SPECT imaging. In such cases, it may be necessary to use an imaging surrogate to predict the radiation dose from the therapeutic isotope, either pre-therapy or during combination RPT. However, these methods may introduce inaccuracies into the dosimetry estimate. This dissertation aims to investigate some “theranostic pair” radiopharmaceuticals and determine if these pairs may be suitable for theranostic dosimetry.
In addition to a comprehensive literature review of theranostic dosimetry and the validity of multiple theranostic pairs used clinically and pre-clinically, three Monte Carlo based simulation studies are
performed:
- First, an investigation into the theranostic pair 177Lu (a beta/gamma
emitter) and 90Y (a beta emitter) to determine if Bremstrahhlung photons emitted by 90Y reduce the accuracy of quantitative SPECT imaging of 177Lu
- Then, simulations of 225Ac (an alpha emitter) and 177Lu within prostate cancer cells were performed and used to create nucleus absorbed dose kernels which were convolved with multicellular tumour maps of varying morphologies (i.e. hypoxic, necrotic, and normoxic tumour
phenotypes) to assess the absorbed dose distribution differences between particulate radiation from 225Ac and 177Lu on a microscopic scale
- Finally, the proposition of a novel method using 99mTc (a gamma
emitter) to improve bone marrow dosimetry is discussed and tested. Bone marrow dosimetry during RPT for prostate cancer with 177Lu labelled pharmaceuticals is extremely challenging, and we propose using 99mTc-sulfur colloids to assist in the determination of bone marrow location during imaging and subsequently use 177Lu for bone marrow dosimetry, which requires simultaneous SPECT imaging of 177Lu and 99mTc.
We test the feasibility of this and suggest additions to clinical scatter correction methods to reduce the impact of photon contamination from 177Lu on 99mTc images.
Event Location:
14th floor meeting room, BC Cancer Research Institute
Event Time:
Thursday, April 18, 2024 | 10:00 am - 11:00 am
Event Location:
BRIM 311
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2024-04-18T10:00:00
2024-04-18T11:00:00
Anomalous Hall Crystals in Graphene: interaction-driven Chern bands at zero magnetic field
Event Information:
Abstract: Recent experiments have discovered that pentalayer-graphene subject to a moire superlattice spontaneously breaks time-reversal, resulting in a quantized anomalous Hall effect at zero magnetic field. At fractional filling, the material exhibits a zero-field fractional quantum Hall effect. In contrast to other moire-materials, the origin of Chern bands in this material is not so clear. I will present a theoretical picture in which Chern bands arise from an “anomalous Hall crystal” stabilized primarily by interactions. So far this picture is supported mainly by mean-field calculations, so I’ll conclude with some open questions about how the Hall crystal could be verified.
Speaker Bio: Michael Zaletel is an Associate Professor of Physics and theAllison and Thomas Schneider Chair at UC Berkley.
Event Location:
BRIM 311
Event Time:
Friday, April 12, 2024 | 12:00 pm - 2:00 pm
Event Location:
https://lbnl.zoom.us/j/93893398617?pwd=dmlKMCtvaGE3VnkwTDZEdW5xK3VMdz09 Meeting ID: 938 9339 8617 Passcode: 638333
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2024-04-12T12:00:00
2024-04-12T14:00:00
Advances in decay spectroscopy of 160Gd and developments for transfer experiments using radioactive isotope beams
Event Information:
[Abstract]
The structure of the atomic nucleus can rapidly evolve from a spherical shape into one with significant deformation as the number of protons and neutrons change within the nucleus. These exotic nuclei present the opportunity to study the evolution of the nuclear force via the resulting nuclear structure exhibited by the nucleus. In this work, the results of nuclear structure experiments on three isotopes are presented. These experiments, all performed at the TRIUMF-ISAC radioactive beam facility, help to improve understanding of the evolution of nuclear structure from single-particle to collective excitations in nuclei.
The structure of the highly-deformed 160Gd has been studied via the beta-decay of 160Eu using the GRIFFIN spectrometer. New measurements of spectroscopic information and lifetimes of excited-states has shed new light on the structure of K=4+ deformed bands located in this nucleus and supports these are being hexadecapole phonon bands. Lifetime measurements in 160Gd also show the 1999 keV state as having positive, not negative, parity. This result raises questions about the established structure of the beta-decaying states in the parent 160Eu.Development and analysis in support of transfer reaction experiments at TRIUMF-ISAC was performed. Upgrades to the TRIFIC ionization chamber used in conjunction with the TIGRESS gamma-ray spectrometer are discussed. Experimental data from (d,p) neutron transfer reactions on the stable 86Kr and the radioactive 93Sr nucleus is presented here. In the resulting 87Kr, single-particle structure analysis of this data shows the evolution of neutron orbitals directly above the N=50 neutron shell closure. The structure of 94Sr was observed via (d,p) reactions on 93Sr. This experiment is the first ever population of 94Sr via a (d,p) reaction, and spectroscopic factors and angular distributions for a number of excited-states are first reported. The transfer data analysis on 86Kr and 93Sr is also in support of a larger experimental campaign using the Surrogate Reaction Method to experimentally constrain neutron capture cross-sections on unstable nuclei and briefly discussed here.
Event Location:
https://lbnl.zoom.us/j/93893398617?pwd=dmlKMCtvaGE3VnkwTDZEdW5xK3VMdz09 Meeting ID: 938 9339 8617 Passcode: 638333
Event Time:
Thursday, April 11, 2024 | 4:00 pm - 5:00 pm
Event Location:
HENN 202
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2024-04-11T16:00:00
2024-04-11T17:00:00
From Antarctica to PHAS: Lessons on inclusive leadership and collaboration in STEM
Event Information:
Abstract:I will share my reflections upon my four-year journey in the Homeward Bound Program, a leadership training for women in STEM that culminated in an expedition to Antarctica. This will be an interactive session geared towards all members of PHAS, including undergraduate/graduate students, postdocs, faculty and staff. You will learn more about the wildlife and landscape of the Antarctic peninsula, and what I did in the expedition with women leaders in various STEM disciplines. Most importantly, I will use this opportunity to gather your ideas on how to make our department and discipline more inclusive and welcoming for all.
Bio:
Allison Man is an Assistant Professor in the Department of Physics & Astronomy at UBC. Her research area is galaxy evolution. She studies how massive galaxies assemble their stars in the first few billion years of the cosmic history. She uses gravitational lensing to obtain a resolved view of distant galaxies — they are otherwise too faint and too small to be observed with current telescopes.
On a lighter note from discussions on her Homeward bound experience, she has described a new-found delight in penguins, Antarctic ocean swimming and learning from others in multidisciplinary STEM fields to the Fine Arts!
Learn More:
Read this article about Allison being chosen as a participant on the 5th Homeward Bound Program
Check out the Homeward bound website
Learn about the UBC Extragalactic Astrophysics Group and what they study on Allison's faculty webpage
Event Location:
HENN 202
Event Time:
Wednesday, April 10, 2024 | 2:00 pm - 3:00 pm
Event Location:
BRIM 311
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2024-04-10T14:00:00
2024-04-10T15:00:00
Dissipation driven dynamical topological phase transitions in two-dimensional superconductors
Event Information:
Abstract: By quenching the interaction strength, we induce and study a topological dynamical phase transition between superconducting phases of a planar fermionic model. Using the Lindblad Master Equation approach to account for the interactions of Bogoliubov quasiparticles among themselves and with the fluctuations of the superconducting order parameter, we derive the corresponding relaxation dynamics of the order parameter. To fully characterize the phase transition, we also compute the fidelity and the spin-Hall conductance of the system. Our approach provides us crucial informations for experimental implementations, such as the dependence of the critical time on the system-bath coupling.
Speaker Bio: Domenico Giuliano has received his Ph. D. in 1998 from the Università di Napoli (Naples University) “Federico II” – Italy. During his Ph. D. he has spent six months at Stanford University, under the supervision of Prof. Robert Laughlin. After graduating, he moved back to Stanford, on a two-year post-doc appointment, supervised again by Prof. Laughlin. After that, he has spent two more years in Napoli as a post-doc research associate under the supervision of Prof. Arturo Tagliacozzo, in 2003 he has become a university researcher at the University of Calabria, in Soutern Italy. From year 2020 he is an associate professor of theorical physics at the same university. In the past, he has been visiting several times the department of Physics at the University of British Coumbia, on a long-lasting scientific collaboration with Prof. Ian Affleck and his group. Domenico’s main research interest are in theoretical condensed matter. They include: Fractionalization of quantum number and fractional statistics; Low-dimensional correlated system, including one-dimensional Luttinger liquids; Topological insulators and topological superconductors; Kondo effect and its applications; Quantum phase transitions.
Event Location:
BRIM 311
Pushing the frontiers of galaxy formation modeling with multi-scale simulations and machine learning
Event Location:
HENN 318
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2024-04-08T16:00:00
2024-04-08T17:00:00
Pushing the frontiers of galaxy formation modeling with multi-scale simulations and machine learning
Event Information:
Abstract:
Supermassive black holes (SMBHs) in Active Galactic Nuclei (AGN) play a key role in the formation of galaxies and large-scale structure, but the triggering and impact of AGN feedback across scales and the origin of the observed SMBH–galaxy connection remain major open questions owing to the multi-scale and multi-physics nature of the problem. AGN feedback can also profoundly affect the properties and spatial distribution of baryons on scales that contain a large amount of cosmological information. Current and upcoming cosmological surveys will provide unprecedented data to constrain the fundamental cosmological parameters, but uncertainties in galaxy formation physics remain a major theoretical obstacle to extract information from cosmological experiments.
In this talk, I will present new simulation techniques that are pushing the frontiers of galaxy formation modeling towards (1) the smallest scales, developing physically predictive models of SMBH accretion and feedback explicitly at sub-pc resolution in a full cosmological context to interpret a plethora of galaxy and AGN observables, and (2) the largest scales, developing thousands of large-volume simulations exploring a wide range of sub-grid feedback implementations to train robust machine learning algorithms that can maximize the extraction of information from cosmological surveys while marginalizing over uncertainties in galaxy formation physics. I will demonstrate the feasibility of these orthogonal approaches to address fundamental problems and discuss their potential to significantly advance the fields of galaxy evolution and cosmology.
Bio:
Dr. Daniel Anglés-Alcázar is an Assistant Professor of Physics at the University of Connecticut, specializing in Computational Galaxy Formation.
Learn More:
See his research group website here
Read more about his research interests here
Event Location:
HENN 318
Event Time:
Monday, April 8, 2024 | 10:00 am - 12:30 pm
Event Location:
UBC plaza area between the UBC Bookstore (6200 University Blvd) and the UBC Alumni Centre (6163 University Blvd)
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2024-04-08T10:00:00
2024-04-08T12:30:00
Partial Solar Eclipse Viewing Event
Event Information:
Come and join us for this partial eclipse viewing event! PHAS ASTRO faculty and students will be on-site to share information and to lend you eclipse glasses to view the eclipse.
UBC Partial Eclipse Event:Date: Monday, April 8th, 2024Time: 10:00am – 12:30pmLocation: in the plaza area between the UBC Bookstore (6200 University Blvd) and the UBC Alumni Centre (6163 University Blvd)
Who will be there: Department of Physics & Astronomy ASTRO Faculty and students will be your guides to what is happening during this eclipse, and how to view it safely!
Equipment: eclipse glasses, two solar telescopes and edible pin-hole cameras for kids!
Want to learn more?
Check out the Discover the Universe website which has lots of resources on the April eclipse
Read the Canadian Space Agency site for more eclipse information
View the NASA site for more!
Event Location:
UBC plaza area between the UBC Bookstore (6200 University Blvd) and the UBC Alumni Centre (6163 University Blvd)
Event Time:
Friday, April 5, 2024 | 3:00 pm - 4:00 pm
Event Location:
HENN 201
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2024-04-05T15:00:00
2024-04-05T16:00:00
The International Liquid-Mirror Telescope
Event Information:
Abstract:
A unique and novel optical telescope has recently started operating. Perched on a mountaintop in the Indian Himalayas, the ILMT uses a low-cost 4-metre rotating parabolic mirror, surfaced with a thin reflecting film of liquid mercury, to collect and focus light. The telescope views objects as they pass overhead, compensating for the Earth's rotation by continuously scanning its electronic camera. In a single night it is able to survey an area of sky that is 250 times larger than the full moon. The ILMT observes the same strip of sky night after night, looking for anything that changes, including asteroids, supernovae, variable stars, active galaxies, quasars and space debris. I will give an overview of the project and describe the technology that made it possible.
Bio:
Paul Hickson is a professor of Astronomy at UBC.
Learn More:
Find out more on Paul's faculty webpage here
Read about the International Liquid Mirror Telescope (ILMT) telescope from this UBC Science article here
Watch Paul talk about the ILMT telescope on Youtube here
Here's another article about the 4 metre International Liquid Mirror Telescope
Event Location:
HENN 201
Event Time:
Thursday, April 4, 2024 | 4:00 pm - 5:00 pm
Event Location:
HENN 202
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2024-04-04T16:00:00
2024-04-04T17:00:00
The Art of the Impossible: Probing Challenging Higgs Channels at the LHC
Event Information:
Abstract:
The search for the Higgs boson was central to the conception and design of the LHC detectors. However, measurements of the Higgs coupling to the second and third-generation quarks were regarded as extremely challenging and, in some cases, impossible. Scientific ingenuity and original thought have allowed ATLAS and CMS to probe the coupling of the Higgs boson to quarks. I will discuss techniques (including machine learning) used to achieve this and provide a brief perspective on future directions.
Bio:
Heather attended the University of Cape Town in South Africa from 1999-2005 where she obtained a BSc, BSc (Hons) and then a MSc in Physics. She then attended the California Institute of Technology and obtained her Ph.D. in Physics in 2011. She then worked at CERN as a Research Fellow and Research Staff Scientist from 2011-2017 before moving to LBNL as a Divisional Fellow in 2017. Heather joined the UC Berkeley faculty as assistant professor in 2019. She received the IUPAP C11 Young Scientist Prize in 2018. She is currently serving in a high-level management role within the ATLAS experiment as the Data Preparation Coordinator.
Research Interests:
I am an experimental particle physicist working on the ATLAS experiment at the Large Hadron Collider (LHC) just outside Geneva in Switzerland. I have broad interests in particle physics, but the primary focus of my research is the Higgs boson -- the most recently discovered elementary particle, the only known elementary scalar of nature and the final piece of the remarkably successful Standard Model. However, this discovery leaves many important questions unanswered and uncovers further questions. The Higgs is not just another particle. It is profoundly different from all other elementary particles, relates to the most obscure sectors of the Standard Model and is linked to some of the deep questions, so it might prove to be a portal to find new physics. I study the properties of the Higgs boson and, in particular, how it interacts with different types of quarks, including top, bottom and charm quarks. Other research interests include the development of track reconstruction algorithms, silicon detectors and algorithms for quantum computers. A theme throughout my research is applications of machine learning.
I collaborate with Professors Marjorie Shapiro and Haicheln Wang at UC Berkeley and with scientists in the ATLAS group at Lawrence Berkeley National Laboratory (LBNL). The ATLAS group at LBNL works on a broad range of physics topics from measurements to the Standard Model to searches for new physics. The group also plays important roles in the operation of the ATLAS pixel detectors, design and construction of upgraded silicon detectors, software development for improved detector performance, event generation, simulation, and computing.
Learn More:
See Heather's UC Berkely faculty website page here: Heather Gray | Physics (berkeley.edu)
Learn more about the Gray Research Group here: Gray Research Group | Physics (berkeley.edu)
Event Location:
HENN 202
Event Time:
Thursday, April 4, 2024 | 10:00 am - 11:00 am
Event Location:
BRIM 311
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2024-04-04T10:00:00
2024-04-04T11:00:00
Electrons in twisted layers: design, surprise, and a new set of eyes
Event Information:
Abstract: The goal of building a quantum computer has lead to rapid advances in experiments that allow for high-precision dynamical control of quantum systems at the single qubit level. However, a major challenge in harnessing the power of these devices is in understanding how best to control noise. In particular, many interesting phases of matter, including topological phases, that exist in closed quantum systems are not stable at finite temperature, suggesting that they are particularly sensitive to the kinds of open-system noise present in such devices. Quantum error correction protocols can be used to rectify this, but these involve non-local processes. In this talk, I will explore approaches to stabilizing symmetry-protected topological order at arbitrarily long times in 1 dimension using local open-system dynamics. I will show that this can be done when the noise is of a particular type relevant to Rydberg atom arrays, known as biased erasure noise, and comment on the implications of these results for possible steady-state phases of open quantum systems.
Speaker Bio: Fiona Burnell is a UBC alumnae and an associate professor at the University of Minnesota. Her research interests include understanding how topology and symmetry dictate the possible phases of matter that can be found in nature, studying how and when quantum dynamics can result in systems evading their naive thermal equilibrium, and contemplating experiments that can reveal patterns of quantum entanglement in many-body systems.
Event Location:
BRIM 311
Event Time:
Thursday, March 28, 2024 | 4:00 pm - 5:00 pm
Event Location:
HENN 202
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2024-03-28T16:00:00
2024-03-28T17:00:00
From Solid State Physics To Nanoparticles That Enable COVID-19 Vaccines And Gene Therapies: A Personal Journey
Event Information:
Abstract: In 1972 I received a PhD in solid state physics from the UBC Physics Department. I then made a direct transition into the Biochemistry Department at Oxford. This talk will follow my career since then, starting with very basic studies using NMR to understand properties of lipids in biological membranes. These studies evolved into using lipid-based systems as delivery systems for cancer drugs and nucleic acid-based drugs. I have focused on two fundamental problems associated with modern medicine. First, most commonly used drugs, such as anticancer drugs, are so-called “small molecules” that go everywhere in the body following systemic administration with less than 0.1% reaching disease sites such as tumours. We clearly need delivery systems to delivery these agents more accurately. Second, the reason we use small molecule drugs is because they are small enough to permeate into cells to reach intracellular target sites. Again, it would be of obvious benefit if we could develop systems to deliver larger nucleic acid-based drugs into target cells in order to use the same machinery that cells use to treat disease. These efforts have resulted in five nanomedicine drugs that have received regulatory approval and are now used clinically to treat diseases such as metastatic breast cancer as well as enabling the Pfizer.BioNTech COVID-19 vaccine that has played a pivotal role in alleviating the global pandemic.
Bio:
Pieter R. Cullis, PhD, FRSC, FRS, OBC, OC, Director, Nanomedicines Research Group, Professor, Department of Biochemistry and Molecular Biology, University of British Columbia.
Dr. Cullis and co-workers have been responsible for fundamental advances in the development of nanomedicines employing lipid nanoparticle (LNP) technology for cancer therapies, gene therapies and vaccines. This work has contributed to five drugs that have received clinical approval by the FDA, the European EMA and Health Canada. Dr. Cullis has also co-founded eleven biotechnology companies that now employ over 400 people, has published over 400 scientific articles (h index 138) and is an inventor on over 100 patents. He has also co-founded and been Founding Scientific Director of two National Centre of Excellence networks, the Centre for Drug Research and Development (now AdMare) in 2004 and the NanoMedicines Innovation Network in 2019. These not-for-profit networks are aimed at translating basic research in the life sciences into commercially viable products and have given rise to numerous start-up companies.
Dr. Cullis has received many awards including the Order of Canada in 2021 and the VinFuture Prize (Vietnam), the Prince Mahidol Award (Thailand), the Gairdner International Award (Canada) and the Tang Prize (Taiwan) in 2022. Two recently approved drugs that are enabled by LNP delivery systems devised by Dr. Cullis, members of his UBC laboratory and colleagues in the companies he has co-founded deserve special emphasis. The first is Onpattro which was approved by the US FDA in August 2018 to treat the previously fatal hereditary condition transthyretin-induced amyloidosis (hATTR). Onpattro is the first RNAi drug to receive regulatory approval. The second is Comirnaty, the COVID-19 mRNA vaccine developed by Pfizer/BioNTech that has received regulatory approval in many jurisdictions including Canada, the USA, the UK and Europe. Comirnaty has played a major role in containing the global Covid-19 pandemic with approximately 6B doses administered worldwide in 2021 and 2022.
Learn More:
See more about his research interests on his faculty webpage here
Read UBC Faculty of Medicine article: "Dr. Pieter Cullis names 2024 Canadian Medical Hall of Fame inductee" here
Read UBC faculty of Medicine article: "Dr. Pieter Cullis named fellow of U.K.'s prestigious Royal Society" here
Read UBC Biomedical Innovation at UBC artcile "Biomedical Innovator Spotlight: Dr. Pieter Cullis" here
For a breakdown on lipid nanoparticles and how this revolutionized the COVID-19 vaccines, see this reduced CBC Quirks & Quarks Q&A article: "Dr. Pieter Cullis talks lipid nanoparticles and vaccines of the future on CBC Radio’s Quirks & Quarks" here
Event Location:
HENN 202
Event Time:
Wednesday, March 27, 2024 | 3:00 pm - 4:00 pm
Event Location:
Henn 318
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2024-03-27T15:00:00
2024-03-27T16:00:00
Effective Field Theory for Extreme Mass Ratios
Event Information:
Abstract:
The standard approximations to the two-body problem in General Relativity include weak-field perturbation theory (“PN’’ and “PM’’) and a strong-field scheme which expands in powers of the mass ratio but retains all orders in G-Newton, ie. “self-force’’. In this talk we’ll discuss recent work which used inspiration from self-force to simplify perturbative computations. We introduce an effective field theory describing a pair of gravitationally interacting point particles in an expansion in their mass ratio. The leading (0SF) dynamics are trivially described by geodesic motion in curved spacetime and at higher SF orders the perturbations of the 0SF exact solution are accounted for by a small number of operators, eg. a recoil operator encoding backreaction onto the heavy body. Rather than building-up curved spacetime perturbatively, this approach leverages known non-perturbative solutions and unpacks them into very simple perturbative building blocks—suggesting a possible path towards manageable multi-loop integration for higher PM orders. We’ll mention a variety of old and new two-loop results computed using this EFT.
Event Location:
Henn 318
Event Time:
Monday, March 25, 2024 | 4:00 pm - 5:00 pm
Event Location:
HENN 318
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2024-03-25T16:00:00
2024-03-25T17:00:00
The SCALES project: Stirring the ISM with clustered feedback, and what it does to star clusters
Event Information:
Abstract:
Stellar clusters are critical constituents within galaxies: they are the results of extreme modes of star formation, and through their correlated stellar feedback they regulate their host galaxy evolution. Including the effect of clustered supernovae in the baryonic lifecycle of their host galaxies is a major step missing in current modern simulations of galaxy formation. In this talk, I will present a novel method to model individual star clusters and their critical influence on their host galaxy evolution within the hydrodynamical code GIZMO. By using a sink prescription that allows clusters to form via gas accretion and mergers, I will demonstrate the interplay between clustered feedback and the properties of the ISM on galactic scales. Lastly, I will discuss how the formation of star cluster populations is affected in this scenario.
Bio:
I am interested on how stellar clusters form and evolve in a hierarchical galaxy assembly context, with my ultimate goal being to be able to use old, massive stellar cluster populations as near-field cosmological tracers. In particular, I’m interested in:
The formation of clustered stellar systems over cosmic time, and their interplay with galaxy formation
Constraining the physics involved in globular cluster formation
Development of sub-grid models of star formation and feedback in numerical simulations of galaxy formation
Learn More:
See her personal webpage here
View this recent online colloquium she gave at the Waterloo Center for Astrophysics (Canada)
See her TedTalk here
Event Location:
HENN 318
Event Time:
Friday, March 22, 2024 | 2:00 pm - 4:00 pm
Event Location:
UBC Earth Science Building: ESB 1012 (also on zoom)
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2024-03-22T14:00:00
2024-03-22T16:00:00
Her Space, Her Time: How Trailblazing Women Scientists Decoded the Hidden Universe
Event Information:
International Women's Day event:
The event is co-sponsored by UBC’s Faculty of Science, Pacific Institute for Mathematical Sciences, Department of Mathematics, Quantum Matter Institute, Department of Physics & Astronomy and UBC Bookstore.
International Women’s Day takes place annually on March 8 to recognize and celebrate cis and trans women’s achievements, challenge biases, and to reflect on and advance efforts toward greater gender equality.
This year we’re honoured to welcome Dr. Shohini Ghose, Professor of Physics & Computer Science at Wilfrid Laurier University in Waterloo, to UBC Vancouver campus on March 22 for a book signing and talk as part of UBC’s IWD celebrations. Dr. Ghose is the author of two books. The latest (published in October 2023) is titled Her Space, Her Time: How Trailblazing Women Scientists Decoded the Hidden Universe, and it will be the topic of her talk.
Book signing: 2pm-3pm in the UBC Earth Sciences building ESB foyer
Talk: 3pm-4pm in the UBC Earth Sciences building ESB 1012
*Copies of the book will be available for purchase on-site.
Registration Free!
Please register for this hybrid event here: https://ubc.zoom.us/meeting/register/u5IocemupzMoGdOtKYNvqApF83zF3BqPQMIJ#/registration
Learn More:
Read Shohini's Wilfred Laurier University faculty webpage here
See Shohini's TED Talk here (2020)
Read more about her work in Inclusion, Diversity, Equity and Accessibility here
Event Location:
UBC Earth Science Building: ESB 1012 (also on zoom)
Event Time:
Thursday, March 21, 2024 | 4:00 pm - 5:00 pm
Event Location:
HENN 202
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2024-03-21T16:00:00
2024-03-21T17:00:00
Making and measuring macromolecular machines
Event Information:
Abstract :Molecular machines lie at the heart of biological processes ranging from DNA replication to cell migration. We use single-molecule tracking and manipulation to characterize the structural dynamics of these nanoscale assemblies, and further challenge our understanding by designing and testing structural variants with novel properties that expand the functional range of known biomolecular machines. In the process, we are developing an engineering capacity for molecular motors with tunable and dynamically controllable physical properties, providing a toolkit for precise perturbations of mechanical functions. We have previously developed a family of light-responsive myosin motors, enabling precise control of fast and processive molecular transport in vitro and in living cells. I will describe our ongoing efforts to augment and diversify engineered cytoskeletal motors, including newly developed light-responsive filamentous myosins for control of contractility. I will further discuss our measurements of dynamics and mechanics in CRISPR endonucleases. In the latter work, we have used high-resolution multimodal single-molecule methods to study the process of DNA interrogation by Cas9 and Cas12a. We have observed intermediate steps in target recognition and probed important effects of DNA torsion on the dynamics and specificity of these nucleoprotein machines.
Bio:
Zev Bryant is an Associate Professor of Bioengineering and Structural Biology at Stanford University.
Molecular motors lie at the heart of biological processes from DNA replication to vesicle transport. My laboratory seeks to understand the physical mechanisms by which these nanoscale machines convert chemical energy into mechanical work. We use single molecule tracking and manipulation techniques to observe and perturb substeps in the mechanochemical cycles of individual motors. Protein engineering helps us to explore relationships between molecular structures and mechanical functions. Broad topics of current interest include torque generation by DNA-associated ATPases and mechanical adaptations of unconventional myosins.
B.Sc., University of Washington, Biochemistry (1998)Ph.D., UC, Berkeley, Molecular and Cell Biology (2003)
Predoctoral Fellowship, Howard Hughes Medical Institute (1999)Harold M. Weintraub Award, FHCRC (2004)Alan Bearden Award, UC, Berkeley (2004)Postdoctoral Fellowship, Helen Hay Whitney Foundation (2005)Director's New Innovator Award, NIH (2008)Pew Scholars Award, Pew Charitable Trusts (2009)
Learn More:
Read his Stanford University profile page here
See his Stanford Engineering page here
Event Location:
HENN 202
Event Time:
Thursday, March 21, 2024 | 10:00 am - 11:00 am
Event Location:
BRIM 311
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2024-03-21T10:00:00
2024-03-21T11:00:00
Equilibrium and far-from-equilibrium properties of bipolaron coupled to dispersive phonons
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Abstract: In the first part of my talk, I will discuss a Holstein-like model with two electrons nonlinearly coupled to quantum phonons. Using an efficient method based on full quantum approach [1-4] we simulate the dynamical response of a system subject to a short spatially uniform optical pulse that couples to dipole-active vibrational modes. Nonlinear electron-phonon coupling can either soften or strengthen the phonon frequency in the presence of electron density [5]. When two electrons are free to propagate on a lattice subject to non-linear coupling to phonons that soften phonon frequency, an external optical pulse with well tuned frequency can induce attraction between electrons. Electrons remain bound long after the optical pulse is switched off. Changing the frequency of the pulse the attractive electron–electron interaction can be switched to repulsive. Two sequential optical pulses with different frequencies can switch between attractive and repulsive interaction [6].
In the second part, I will discuss the phase diagram of the bipolaron in the Holstein – Hubbard model in the presence of dispersive phonons. We show that a finite dispersion can stabilize a bound bipolaron even at large Coulomb repulsion U [7]. The sign of the curvature of the optical phonon dispersion plays a decisive role on the bipolaron binding energy and the effective mass in the presence of U. Finally, I will discuss the influence of U on the ARPES spectral function of the bipolaron.
Speaker Bio: Janez Bonca is a Professor and Dean of the Faculty of Mathematics and Physics at the University of Ljubljana, Slovenia. His research interests include theory of incommensurate systems, theory of strongly correlated systems and high temperature superconductors, theory of heavy fermion systems, theory of mesoscopic systems and quantum dots, theory of frustrated spin systems, physics of electron – phonon interaction and theory of polarons and bipolarons, study of systems driven far from equilibrium, thermalization in many-body systems, theory of many-body localization. Prof. Bonca completed his PhD from the University of Ljubljana, and worked as a Post-doctoral Associate at Los Alamos National Laboratory from 1992-1995.
Event Location:
BRIM 311
Event Time:
Monday, March 18, 2024 | 4:00 pm - 5:00 pm
Event Location:
HENN 318
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2024-03-18T16:00:00
2024-03-18T17:00:00
Emerging Views of the Kuiper Belt from JWST
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Abstract:
The Kuiper Belt (also called Trans-Neptunian region) is a large population of sub-planet-sized beyond the orbit of Neptune. These bodies provide windows into conditions of the outer solar nebula, the process of planet growth and differentiation in icy bodies, and current dynamics and dynamical evolution of the Solar System. Mapping of their orbits has revealed distinct dynamical structures that indicate that bodies in the Kuiper Belt have been moved and shuffled by significant outward migration of Uranus and Neptune, complicating the task of uncovering links between composition and nebular conditions. Ground- based visible to near-infrared (VNIR; 0.4 to 2.5 microns) spectra of the largest bodies (Pluto, Eris, Makemake) are dominated by methane. VNIR spectra of smaller (and therefore fainter) Kuiper Belt objects (KBOs) generally have fairly low S/N, precluding detailed compositional analysis.
The James Webb Space Telescope (JWST) opens a new era in spectral observations of KBO. The NIRSpec instrument extends spectral observations to 5.3 microns, a region that includes strong fundamental vibrational modes of many ices and organics of thought to populate these surfaces, and the sensitivity, even in this new wavelength range, is extraordinary. In this talk, I will present results of spectroscopy of KBOs and related populations from the first year of JWST observations. These highlights will include measurement of isotopic signatures in the methane on the largest bodies, discovery of three distinct spectral groups among the smaller bodies that likely map to ice retention lines in the early Solar System, irradiation chemistry on intermediate sized (D~1000 km) bodies, spectral support for binary formation from streaming instabilities, and spectra of Trojan asteroids, which are thought to be KBOs that were scattered inward and stored at 5.2 AU for 4.5 Gyr.
Bio:
Dr. Emery applies the techniques of astronomical reflection and emission spectroscopy and spectrophotometry of primitive and icy bodies in the near- (0.8 to 5.0 microns) and mid-infrared (5 to 50 microns) to investigate the formation and evolution of the Solar System and the distribution of organic material. The Jupiter Trojan asteroids have been a strong focus of his research, and he also regularly observes Kuiper Belt objects, icy satellites, and other asteroid groups to understand the state of their surfaces as related to these topics. Along with telescopic observations, he contributes to Solar System exploration as a science team member on the OSIRIS-REx asteroid sample return mission, the Lucy Trojan asteroid flyby mission, and the NEO Surveyor Mission infrared telescope mission.
Learn More:
Read his faculty bio on the Northern Arizona University Astronomy & Planetary Science page
Find our more about his experience as a planetary astronomer here
Event Location:
HENN 318
Event Time:
Thursday, March 14, 2024 | 4:00 pm - 5:00 pm
Event Location:
HENN 202
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2024-03-14T16:00:00
2024-03-14T17:00:00
Casting a Wide Net for Dark Matter
Event Information:
Abstract:I will discuss the need to extend the Standard Model of particle physics in order to describe the dark matter, a mysterious substance whose existence can be inferred from cosmological measurements, but whose fundamental nature remains unknown. I’ll discuss how a broad strategy of searching for dark matter using techniques from particle physics and astronomy maximize our chances of successfully discovering its identity, and what this could mean for future research in particle physics.
Bio:
Tim M.P. Tait is a Chancellor's Professor of Physics and Astronomy at the University of California, Irvine. His research interests include theoretical investigations of physics beyond the Standard Model of particle physics, particle physics phenomenology, high energy collider physics, and cosmology and involves both exploring new models and new phenomena, as well as theoretical interpretation of experimental results. He is a fellow of the American Physical Society and recipient of the Friedrich Wilhelm Bessel-Forschungspreis from the Alexander von Humboldt Foundation. Tait received a Ph.D. in physics from Michigan State University and did postdoctoral work at Argonne National Lab and the Fermi National Accelerator Laboratory.
Learn More:
Discover more from his homepage here
See his faculty webpage at the University of California, Irvine here
View his CV
Browse through his Wikipedia page
Event Location:
HENN 202