Hi Everyone, check out this opportunity below:
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To learn more about life as a researcher<https://urldefense.proofpoint.com/v2/url?u=https-3A__grnh.se_6d7173521&d=Dw…> at PDT, please join our upcoming networking sessions hosted by Katie Zhao and two of our researchers, Seth Tribble (PhD, Statistics, Stanford) and Matthew Rispoli (PhD, Physics, Harvard). During the panel discussion, we will take questions from the audience so please join us to hear about our researcher’s experience and the work they are doing at PDT.
Date: Thursday, 10/6/2022
Time: 6:00 – 7:00pm EDT
Location: Rogers Stratton Room @ The Charles Hotel, 1 Bennett St, Cambridge, MA
RSVP: https://app.joinhandshake.com/emp/events/1116492<https://urldefense.proofpoint.com/v2/url?u=https-3A__app.joinhandshake.com_…>
Bring a friend: Don't hesitate to share our invitation with other PhD candidates and postdocs!
More about the event:
Curious what it means to be a Quantitative Researcher at PDT Partners? Join our moderated discussion with PDT researchers to learn about their journey to quantitative finance from academia. They will discuss their career path, the interesting work that challenges them and their decision to come to the quantitative finance industry. Learn how a team of scientists, mathematicians and engineers with PhDs in Physics, Computer Science, Statistics, Math, Economics and Electrical Engineering develop trading strategies using uniquely scientifically rigorous approaches in an open and collaborative culture.
We will discuss how PDT and quantitative research compares to other industries, our academic research culture and how researchers use the skills from their graduate program to tackle interesting and challenging problems. This will be an interactive discussion and you will hear directly from PDTers!
Here are the PDT researchers on our panel:
Matthew
Matthew completed his PhD in Physics at Harvard. Matthew was a part of the Harvard-MIT Center for Ultracold Atoms. His research was focused on using quantum gas microscopy to study entanglement and thermalization within isolated quantum many-body systems.
Seth
Seth received his PhD in Statistics from Stanford with a specialization in variance reduction techniques in MCMC estimation. Additionally, Seth has undergraduate degrees in Mathematics and Art History from Rice.
We hope to see you there!
Best,
Steven
Steven Panos
Executive Director, Talent and Culture Team
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Ann Quaicoe
Harvard Quantum Initiative
Staff Assistant
33 Oxford Street
Cambridge, MA 02138
Maxwell-Dworkin 111
P: (617) 496-2361
------------------
Modified Office Hours:
M-Th: 8:00AM - 6:00PM
F: Offline
Please see below for a talk that may be of interest to the HQI community.
From: Liz Alcock <ealcock(a)fas.harvard.edu>
Date: Monday, October 3, 2022 at 2:16 PM
To: "thusem(a)lists.fas.harvard.edu" <thusem(a)lists.fas.harvard.edu>, "hetg(a)lists.fas.harvard.edu" <hetg(a)lists.fas.harvard.edu>, "hetg-particle(a)lists.fas.harvard.edu" <hetg-particle(a)lists.fas.harvard.edu>, "hetg-string(a)lists.fas.harvard.edu" <hetg-string(a)lists.fas.harvard.edu>, "Ploucha, Clare" <cploucha(a)fas.harvard.edu>
Subject: CMSA colloquium: Subir Sachdev, Wednesday, Oct 5, 4:00 - 5: 00 pm (special time)
Dear colleagues,
We are happy to announce that Prof. Subir Sachdev from Harvard University physics department will be our next colloquium speaker.
The talk will take place at 20 Garden St., in seminar room G-10, between 4:00 - 5:00 pm. Note it is the special time.
Please find below and attached for title and abstract for Prof. Sachdev's lecture.
https://cmsa.fas.harvard.edu/event/colloquium_10522/
Best wishes,
Jie Wang
----------------
Speaker: Subir Sachdev (Harvard)
Date and time: Wed, Oct 5, 4:00 - 5:00 pm
Location: CMSA, 20 Garden St, seminar room G-10
Title: Quantum statistical mechanics of charged black holes and strange metals
Abstract: The Sachdev-Ye-Kitaev model was introduced as a toy model of interacting fermions without any particle-like excitations. I will describe how this toy model yields the universal low energy quantum theory of generic charged black holes in asymptotically 3+1 dimensional Minkowski space. I will also discuss how extensions of the SYK model yield a realistic theory of the strange metal phase of correlated electron systems.
Good evening all,
HQI would like to invite you all to a lunch next week Tuesday, October 4, with HQI Special Seminar guest speaker, Prof. Umesh Vazirani. The lunch will be from 12:30pm - 2pm, location TBD. Please RSVP by 12pm tomorrow afternoon if you would like to join the lunch - include any dietary restrictions.
More information about the talk (which will happen on Monday) will be shared as soon as possible.
Thank you,
Ann
------------------
Ann Quaicoe
Harvard Quantum Initiative
Staff Assistant
33 Oxford Street
Cambridge, MA 02138
Maxwell-Dworkin 111
P: (617) 496-2361
------------------
Modified Office Hours:
M-Th: 8:00AM - 6:00PM
F: Offline
HQI Special Seminar - Prof. Umesh Vazirani (UC Berkeley)
Monday, Oct. 3, 2022
4:15 PM - 6:00 PM,
Science and Engineering Complex
Room: LL2.229
Title: Theoretical Reflections on Quantum Supremacy
Abstract:
Google's 2019 experiment and their announcement of quantum supremacy relied on the inability of classical computers to efficiently carry out a task called random quantum circuit sampling (RCS). I will describe recent theoretical developments on the complexity of RCS. I will also describe a different line of work that provides scalable and rigorous proofs of quantumness based on an approach called the cryptographic leash, and the prospects of a concrete experimental challenge based on this approach.
Harvard John A. Paulson School of
Engineering and Applied Sciences
EE SEMINAR
Friday, September 30 at 3:30pm
"Scalable semiconductor classical and quantum photonic systems"
Jelena Vuckovic, Jensen Huang Professor in Global Leadership in the School of Engineering and Professor of Electrical Engineering, Stanford University
Location: SEC LL2.224
Abstract: Despite the great progress in photonics over the past few decades, we are nowhere near the level of integration and complexity in photonic systems that would be comparable to those of electronic circuits, which prevents the use of photonics in many applications. This lag in integration scale is largely a result of how we traditionally design photonics: by combining building blocks from a limited library of known designs and manually tuning a few parameters. Unfortunately, the resulting photonic circuits are very sensitive to errors in manufacturing and to environmental instabilities, bulky, and often inefficient. The departure from this old-fashioned approach can lead to optimal photonic designs that are much better than state of the art on many metrics (smaller, more efficient, more robust). Such a departure is enabled by development of inverse design approach which efficiently searches through all possible combinations of realistic parameters and geometries for photonics using a combination of fast electromagnetic solvers and optimization algorithms.
The inverse design approach can also enable new functionalities for photonics, including compact particle accelerators on chip which are 10000 times smaller than traditional accelerators, chip-to-chip and on-chip optical interconnects with error free communication rates exceeding terabit per second, and scaling of quantum systems (beyond present modest scale demonstrations, such as 3 node quantum networks and two dozens of maximally entangled qubits). In particular, platforms based on color centers in wide band gap semiconductors such as diamond and silicon carbide would be suitable for implementing scalable quantum systems, based on excellent spin quantum memories with direct photonic interfaces, the possibility to perform high speed and high fidelity quantum gates on spin qubits, combined with expertise in scaling semiconductor circuits. However, there are outstanding challenges, including color centers integration into optical structures while preserving their coherence and homogeneity, their spectral and spatial control, and implementation of efficient connections between spin qubits. Novel computational techniques such as photonics inverse design, along with new nanofabrication approaches, play a crucial role in addressing these challenges.
Bio: Jelena Vuckovic (PhD Caltech 2002) is the Jensen Huang Professor in Global Leadership in the School of Engineering, and Professor of Electrical Engineering and by courtesy of Applied Physics at Stanford, where she leads the Nanoscale and Quantum Photonics Lab. She is also the Fortinet Founders Chair of the Electrical Engineering Department at Stanford, and was the inaugural director of Q-FARM, the Stanford-SLAC Quantum Science and Engineering Initiative. Vuckovic has received many awards and honors including recently the Vannevar Bush Faculty Fellowship (2022), the Mildred Dresselhaus Lectureship from MIT (2021), the James Gordon Memorial Speakership from the OSA (2020), the IET A. F. Harvey Engineering Research Prize (2019), Distinguished Scholarship of the Max Planck Institute for Quantum Optics (2019), the Hans Fischer Senior Fellowship from the Institute for Advanced Studies in Munich (2013), and Humboldt Prize (2010). She is a Fellow of the APS, of the Optica (OSA), and of the IEEE, and an associate editor of the ACS Photonics.
Host: Marko Loncar
--
Jessica Brenn | Administrative Coordinator for Academic Operations
Applied Math, Computer Science, Electrical Engineering
Harvard John A. Paulson School of Engineering and Applied Sciences
33 Oxford Street, MD 253
Cambridge, MA 02138
Phone: 617-496-7358
------------------
Ann Quaicoe
Harvard Quantum Initiative
Staff Assistant
33 Oxford Street
Cambridge, MA 02138
Maxwell-Dworkin 111
P: (617) 496-2361
------------------
Modified Office Hours:
M-Th: 8:00AM - 6:00PM
F: Offline
Harvard John A. Paulson School of
Engineering and Applied Sciences
EE SEMINAR
Friday, September 30 at 3:30pm
"Scalable semiconductor classical and quantum photonic systems"
Jelena Vuckovic, Jensen Huang Professor in Global Leadership in the School of Engineering and Professor of Electrical Engineering, Stanford University
Location: SEC LL2.224
Abstract: Despite the great progress in photonics over the past few decades, we are nowhere near the level of integration and complexity in photonic systems that would be comparable to those of electronic circuits, which prevents the use of photonics in many applications. This lag in integration scale is largely a result of how we traditionally design photonics: by combining building blocks from a limited library of known designs and manually tuning a few parameters. Unfortunately, the resulting photonic circuits are very sensitive to errors in manufacturing and to environmental instabilities, bulky, and often inefficient. The departure from this old-fashioned approach can lead to optimal photonic designs that are much better than state of the art on many metrics (smaller, more efficient, more robust). Such a departure is enabled by development of inverse design approach which efficiently searches through all possible combinations of realistic parameters and geometries for photonics using a combination of fast electromagnetic solvers and optimization algorithms.
The inverse design approach can also enable new functionalities for photonics, including compact particle accelerators on chip which are 10000 times smaller than traditional accelerators, chip-to-chip and on-chip optical interconnects with error free communication rates exceeding terabit per second, and scaling of quantum systems (beyond present modest scale demonstrations, such as 3 node quantum networks and two dozens of maximally entangled qubits). In particular, platforms based on color centers in wide band gap semiconductors such as diamond and silicon carbide would be suitable for implementing scalable quantum systems, based on excellent spin quantum memories with direct photonic interfaces, the possibility to perform high speed and high fidelity quantum gates on spin qubits, combined with expertise in scaling semiconductor circuits. However, there are outstanding challenges, including color centers integration into optical structures while preserving their coherence and homogeneity, their spectral and spatial control, and implementation of efficient connections between spin qubits. Novel computational techniques such as photonics inverse design, along with new nanofabrication approaches, play a crucial role in addressing these challenges.
Bio: Jelena Vuckovic (PhD Caltech 2002) is the Jensen Huang Professor in Global Leadership in the School of Engineering, and Professor of Electrical Engineering and by courtesy of Applied Physics at Stanford, where she leads the Nanoscale and Quantum Photonics Lab. She is also the Fortinet Founders Chair of the Electrical Engineering Department at Stanford, and was the inaugural director of Q-FARM, the Stanford-SLAC Quantum Science and Engineering Initiative. Vuckovic has received many awards and honors including recently the Vannevar Bush Faculty Fellowship (2022), the Mildred Dresselhaus Lectureship from MIT (2021), the James Gordon Memorial Speakership from the OSA (2020), the IET A. F. Harvey Engineering Research Prize (2019), Distinguished Scholarship of the Max Planck Institute for Quantum Optics (2019), the Hans Fischer Senior Fellowship from the Institute for Advanced Studies in Munich (2013), and Humboldt Prize (2010). She is a Fellow of the APS, of the Optica (OSA), and of the IEEE, and an associate editor of the ACS Photonics.
Host: Marko Loncar
--
Jessica Brenn | Administrative Coordinator for Academic Operations
Applied Math, Computer Science, Electrical Engineering
Harvard John A. Paulson School of Engineering and Applied Sciences
33 Oxford Street, MD 253
Cambridge, MA 02138
Phone: 617-496-7358
------------------
Ann Quaicoe
Harvard Quantum Initiative
Staff Assistant
33 Oxford Street
Cambridge, MA 02138
Maxwell-Dworkin 111
P: (617) 496-2361
------------------
Modified Office Hours:
M-Th: 8:00AM - 6:00PM
F: Offline
Hi all,
Please see below for a talk that might be of interest.
From: "Cotler, Jordan Saul" <jcotler(a)fas.harvard.edu>
Dear all,
This week will be the first "Harvard Quantum Information Group Meeting", which will be held on Thursday, September 29th at 4:30 pm in Jefferson 250.
The meeting is open to everyone at Harvard interested in quantum information, including those in condensed matter physics, AMO physics, high energy physics, computer science, chemistry, etc. The format includes weekly tutorials (by both external and internal speakers) of contemporary topics in quantum information and quantum computing, aimed for a broad scientific audience.
We will also try to foster connections between different groups at Harvard which are interested in or involved with quantum information, and build a broader community.
This week, I will give a brief, panoramic overview of quantum information and quantum computation, and preview topics that will be discussed over the semester. I will be followed by our first speaker, Thomas Schuster from Berkeley, who will talk on "Many-body quantum teleportation via quantum information dynamics".
Hope to see you all there. If you would like to join the mailing list for this meeting, please e-mail harvardqimeeting(a)gmail.com which will add you.
Good morning everyone,
Please see below for an invitation to register for a Quantum lecture series hosted by the Brookhaven National Lab. The weekly lecture series begins today at 12:00 pm.
If you’re interested, please register using the link provided.
Best,
Ann
________________________________
From: C2QA-Info <c2qa-info(a)bnl.gov>
Sent: Friday, September 16, 2022 10:13 AM
Subject: Announcement | C2QA Quantum Thursday Lecture Series
[Timeline Description automatically generated]
[cid:image002.png@01D8C9B4.D4DE14D0]
Donna M. Cusa
Co-Design Center for Quantum Advantage (C2QA)
_______________________________________________________________________________________________________________________________________________________________________________________________________________________________
40 Brookhaven Ave, Bldg. 460, Upton, NY 11973 - 5000
C: 646-369-2356 | E: dcusa(a)bnl.gov<mailto:dcusa@bnl.gov>
Hello everyone,
as you all may know, each QSE PhD candidate is required to complete laboratory rotations (2) in both science and engineering to gain first-hand exposure to new techniques and questions. To submit your proposed lab rotation for review by program leadership, please complete the Lab Rotation Application<https://forms.gle/kHwZCKJmT9wa2dWe8>. Please submit your application by October 1, 2022.
Feel free to email me or your academic advisor if you have any questions!
Best,
Ann
------------------
Ann Quaicoe
Harvard Quantum Initiative
Staff Assistant
33 Oxford Street
Cambridge, MA 02138
Maxwell-Dworkin 111
P: (617) 496-2361
------------------
Modified Office Hours:
M-Th: 8:00AM - 6:00PM
F: Offline