3-year POSTDOC for an observer, computer scientist, or enthusiastic individual who just wants to play with state-of-the-art data from the latest space telescope @NASAWebb
Come join me at Bristol to work on guaranteed observations of #exoplanet atmospheres
https://t.co/ZubtGD2VoT

💰 Applications open for 33 #PhD studentships in applied maths, statistics & machine learning with exciting application areas in @ucddublin @MACSI @MU_Hamilton

Apply directly on our application portal
https://t.co/b5xe239wwr

Closing date Feb 5th 2021
Start date Sept 1st 2021!📈

2020 is almost over, we can get ready for 2021! Apply now for the Spring College on the Physics of Complex Systems: https://t.co/eoXGuCUTdT

#ComplexSystems

Unlocking US vaccine distribution

COVID vaccine distribution in the United States has been hobbled by a web of mismatched technology systems, inconsistent vaccine supplies, under-resourced states and a lack of coordination about getting shots to people once they arrive at local clinics. US President Joe Biden's administration has a goal of delivering 100 million doses in 100 days. To keep that promise, experts say the federal government will need to supply states with better resources and technology. “National coordination will be a game-changer,” says Hana Schank, from the think-tank New America

https://www.technologyreview.com/2021/01/27/1016790/covid-vaccine-distribution-us

Giraffes have a very familiar skin/fur pattern, but you probably never knew that there's more than one and that they are different on a regional and genetic basis [source, read more: https://buff.ly/2TLKoSr]

💉 Let’s talk about where variants ARE coming from and under what circumstances?
Ashish K. Jha, MD, MPH

Variants arise when infections run wild and selection pressures lead to dangerous mutations that can then thrive. Remember, every infection creates opportunities for “errors” – or mutations.

Most mutations are meaningless. They will have no real clinical implications. But every once in a while, a set of mutations will lead the virus to become more contagious, more lethal, or improve its ability to escape our vaccines

🦠 So where are the variants coming from?

UK , South Africa, Brazil –and possibly US (LA variant still being sorted out). Each of these countries had large outbreaks even before their variants took off. So what are implications if we ever want to end this pandemic? We have to bring pandemic under control everywhere.

Letting virus run wild, like US, Brazil did, endangers everyone. Imagine this; Some nations are largely vaccinated but outbreaks are surging elsewhere. What might happen? We might see rise of variants that eventually escape the vaccines. And make everyone vulnerable again.

In a future where US is vaccinated but others are not, we could see rise of variants that can infect, cause outbreaks here and other vaccinated places requiring us to update our vaccines and vaccinate everyone again! It’s the nightmare scenario of a never-ending pandemic.

🦠 There is only one solution to put this nightmare pandemic behind us; Get outbreaks under control everywhere. How?
Put in place virus control policies, get people to wear high quality masks, have more testing AND Vaccinate the world NOW As quickly as possible.

This is what makes herd immunity advocates (remember Great Barrington Declaration?) so naive; They literally advocated for virus to have more chances to mutate and what makes U.S. isolationist policies so naive because we live on one planet and variants travel!

🦠 Want to end the pandemic?

Lets marshal global manufacturing effort to make lots of vaccine quickly and vaccinate everyone! Because large outbreaks anywhere can give rise to variants that can escape vaccines everywhere. At the end of the day, we really are in this together.

https://twitter.com/ashishkjha/status/1354995270619181056

Percolation on complex networks: Theory and application

🔗 arxiv.org/abs/2101.11761

In the last two decades, network science has blossomed and influenced various fields, such as statistical physics, computer science, biology and sociology, from the perspective of the heterogeneous interaction patterns of components composing the complex systems. As a paradigm for random and semi-random connectivity, percolation model plays a key role in the development of network science and its applications. On the one hand, the concepts and analytical methods, such as the emergence of the giant cluster, the finite-size scaling, and the mean-field method, which are intimately related to the percolation theory, are employed to quantify and solve some core problems of networks. On the other hand, the insights into the percolation theory also facilitate the understanding of networked systems, such as robustness, epidemic spreading, vital node identification, and community detection. Meanwhile, network science also brings some new issues to the percolation theory itself, such as percolation of strong heterogeneous systems, topological transition of networks beyond pairwise interactions, and emergence of a giant cluster with mutual connections. So far, the percolation theory has already percolated into the researches of structure analysis and dynamic modeling in network science. Understanding the percolation theory should help the study of many fields in network science, including the still opening questions in the frontiers of networks, such as networks beyond pairwise interactions, temporal networks, and network of networks. The intention of this paper is to offer an overview of these applications, as well as the basic theory of percolation transition on network systems.

Perspective: Foundations of complexity economics. Brian Arthur sketches the ideas of complexity economics and describes how it links to complexity science more broadly.

https://t.co/XU2olGv5Mh

You have until 𝘁𝗵𝗲 𝗲𝗻𝗱 𝗼𝗳 𝘁𝗼𝗱𝗮𝘆 (𝗖𝗘𝗧) to apply for priority applications (BA programs) or if you are applying for financial aid (most CEU programs).

Undergrad ➡️ https://t.co/bV5Ltp5ZhM
Graduate ➡️ https://t.co/qY4Cz7gh6f https://t.co/ioJ6lPAJm5

Nokia BellLabs has open internship positions in:
1. Data Visualization
2. Mobile Sensing and Ubicomp
3. Machine Learning and Data Science

Application deadline is February 6th. More info on the team and on how to
apply can be found under https://t.co/pcHcbOthlS

Latest #coronavirus research:
👉 Scientists engineer an antibody that effectively disables SARS-CoV-2 and closely related coronaviruses.
👉 Death risk for essential workers 20–40% higher than expected.
👉 Moderna vaccine seems to work against new variants.
https://t.co/RLPGImM0P0

Dynamic graphs are a big part of how Twitter does what it does. We use them to model networks that evolve over time. In this post @emaros96 & @mmbronstein discuss a new ML model developed by Twitter to efficiently predict activity in dynamic graphs.

https://t.co/BKk0BBTAk0

💉 نتایج واکسن اسپوتنیک روسی در Lancet منتشر شد. این واکسن ۹۱.۶٪ اثربخشی دارد و هیچ خطر جدی‌ ندارد. #واکسن_روسی #اسپوتنیک

Safety and efficacy of an rAd26 and rAd5 vector-based heterologous prime-boost COVID-19 vaccine: an interim analysis of a randomised controlled phase 3 trial in Russia

Interpretation
This interim analysis of the phase 3 trial of Gam-COVID-Vac showed 91.6% efficacy against COVID-19 and was well tolerated in a large cohort.

https://www.thelancet.com/journals/lancet/article/PIIS0140-6736(21)00234-8/fulltext

Coronavirus is in the air — there’s too much focus on surfaces

Catching the coronavirus from surfaces is rare. The World Health Organization and national public-health agencies need to clarify their advice.

https://www.nature.com/articles/d41586-021-00277-8

Foundations of Temporal Text Networks

Davide Vega & Matteo Magnani

https://appliednetsci.springeropen.com/articles/10.1007/s41109-018-0082-3

Abstract
Three fundamental elements to understand human information networks are the individuals (actors) in the network, the information they exchange, that is often observable online as text content (emails, social media posts, etc.), and the time when these exchanges happen. An extremely large amount of research has addressed some of these aspects either in isolation or as combinations of two of them. There are also more and more works studying systems where all three elements are present, but typically using ad hoc models and algorithms that cannot be easily transfered to other contexts. To address this heterogeneity, in this article we present a simple, expressive and extensible model for temporal text networks, that we claim can be used as a common ground across different types of networks and analysis tasks, and we show how simple procedures to produce views of the model allow the direct application of analysis methods already developed in other domains, from traditional data mining to multilayer network mining.

💉 VACCINE UPDATE:

New study shows that the #OxfordVaccine offers protection of 76% up to 12 weeks after a single dose, with further data supporting a 4-12 week dosing interval.

Further analysis also shows that the #OxfordVaccine may have a substantial effect on coronavirus transmission, with 67% reduction in positive PCR swabs among those who have been vaccinated: https://t.co/7aZAWgFqQH

Two very particular patterns of random movement — Brownian motion and Lévy walks — describe a great many physical phenomena. Recent data hint that Lévy walks may be a default movement pattern for many animal species. https://t.co/U6xAh3Qw2F

Network motifs involving both competition and facilitation predict biodiversity in alpine plant communities [Ecology] https://t.co/ovDA3r1gKU

Updates on Networks 2021: A Joint Sunbelt and NetSci Conference: a thread.

First: the deadline for submissions for #Networks2021 has been extended until Feb 17 at noon EST. Those who have already submitted may continue to edit until that time. https://t.co/TmXcZa8tY4

if you want to sign up for our announcement newsletter list, please visit: https://t.co/NqLHWgKW2O