Month: August 2024

As part of National Science Week, the ARC Centre of Excellence (OzGrav) and the Centre for Astrophysics and Supercomputing (CAS) at Swinburne University proudly hosted “A Virtual Tour of Einstein’s Universe”, an inspiring public lecture presented by Professor Matthew Bailes, Director of OzGrav. Held on campus, the event attracted a strong turnout of science enthusiasts of all ages eager to learn about the universe’s greatest mysteries—from gravitational waves to black holes and pulsars.

Hosted by Professor Alan Duffy, the evening began with a warm introduction to Professor Bailes, followed by a fascinating journey through space and time. Professor Bailes explained how Einstein’s theories are shaping our understanding of the cosmos today. The audience was captivated by discussions on cutting-edge science, with a lively Q&A session rounding out the event.

The event also featured our National Science Week Ambassador, Dr Sara Webb, who helped create an engaging and educational experience, fostering an exciting atmosphere for learning and exploration during National Science Week.

In addition to the public lecture, OzGrav’s Outreach Ambassadors hosted interactive workshops, providing hands-on activities for attendees of all ages and fostering an exciting atmosphere for learning and exploration.

This successful event wouldn’t have been possible without the dedication of the OzGrav team and the Swinburne outreach staff. Stay tuned for more exciting events from OzGrav and Swinburne!

For those who missed the event, a recording of the lecture is below and you can also explore the gallery to view photos from the event.

We are delighted to share that the Einstein-First project, a groundbreaking science education initiative, has been awarded the Science Engagement Initiative of the Year at the 2024 WA Premier’s Science Awards. This recognition highlights the exceptional impact Einstein-First has made in transforming the way young students, especially girls, engage with and understand modern science.

Einstein-First began as an outreach effort at the Gravity Discovery Centre and has since evolved into a national program that brings Einstein’s 21st-century science to students aged 7 to 15. The program’s innovative approach disrupts traditional teaching paradigms by using toys, songs, and hands-on activities to make complex scientific concepts accessible and engaging.

The program’s success is evident in its rapid expansion. Launched nationally by Prof. David Blair, Prof. Ju Li, Prof. Susan Scott and Prof. Marjan Zadnik, along with others, Einstein-First has already trained 150 teachers across 55 schools, impacting over 10,000 students, including 3,000 First Nations students in Queensland. The train-the-trainer model has been particularly effective, empowering teachers to bring Einstein’s science into classrooms across the country.

OzGrav has been a proud supporter and collaborator of Einstein-First. This partnership is a testament to our shared commitment to advancing public understanding of modern physics and inspiring the next generation of scientists.

We congratulate the entire Einstein-First team for their outstanding achievement and well-deserved recognition and look forward to continuing our collaboration to further science education and engagement across Australia.

About the Western Australia Premier’s Science Awards

Now in its 23rd year, the Western Australia Premier’s Science Awards celebrate the outstanding scientific research and engagement efforts in the region. The Science Engagement Initiative of the Year category specifically recognises initiatives that have made a significant contribution to raising community awareness, interest, and participation in science.

Check out the announcement here!

Neutron stars are extremely dense objects, second only to black holes. A teaspoon of neutron star matter weighs as much as Mt. Everest. Under such high densities, neutron stars possess exotic physics that cannot be reproduced on Earth.

We have been studying a subgroup of neutron stars, namely pulsars, that release their energies mainly through electromagnetic radiation. But these stars are only a fraction of the total neutron star population in the Milky Way Galaxy. We are missing out on other types of neutron stars that may not produce much electromagnetic radiation.

As a neutron star rotates, any mountains on its surface – even if they are just a few millimetres tall – will create ripples in the four-dimensional fabric of space- time. Such ripples are known as continuous gravitational waves, or continuous waves for short. Compared to the gravitational waves that have been detected, continuous waves are fainter but constant – similar to the humming of a fridge, as opposed to a loud bang.

Observing neutron stars through continuous waves provides us with information that is complementary to what can be learnt from pulsars, so that we can paint a more complete picture of the unknown physics that lies within. However, continuous waves from neutron stars are still undetected. To know whether they are detectable, and what we can learn from them, we need to perform simulations to see if our current and future gravitational wave detectors can detect continuous waves.

In this study, we looked at the capabilities of two detectors: LIGO, the first to detect gravitational waves in 2015; and the Einstein Telescope, a next- generation detector that is expected to be constructed in the 2030s. The first step to detecting continuous waves is to make sure that we are looking at the right place. The current catalogue of neutron stars contains only pulsars that may not emit any continuous waves. To get a full picture of the neutron star population in the Galaxy, we also need neutron stars that emit continuous waves. We simulated the entire neutron star population in the Galaxy, which includes continuous wave-emitting neutron stars. These stars have different energies and release different amounts of electromagnetic and continuous waves.

From this population of neutron stars, we then estimated the continuous waves produced by these stars, and how the two detectors respond to them. Using a technique called Bayesian inference, we performed searches on the faint “hums” amidst all the additional noise from the detectors. Being a next- generation detector, the Einstein Telescope is larger and more sensitive than LIGO, so the weak continuous wave signals can be more easily identified – just like how you can hear fainter sounds when you are in a quieter room.

The factor that determines the amount of continuous waves generated, known as the ellipticity, could be measured by the Einstein Telescope with an error of between 5 and 50% with 5 years of observation. This property of the neutron star cannot be determined by other methods. The limiting factor, we found, is the preciseness of our measurement of a quantity called the braking index. This number determines the fraction of a neutron star’s energy that is released as continuous waves. The ability to measure this number directly affects our measurement of ellipticity.

Our study demonstrated that future detectors, such as the Einstein Telescope, can detect continuous waves. Neutron star properties such as ellipticity, which previously could not be determined, can then be measured through the detected continuous waves. Our work provides a new way to probe the physics of neutron stars, and additional motivation to construct the next generation of gravitational wave detectors.

Reference: “Population Synthesis and Parameter Estimation of Neutron Stars with Continuous Gravitational Waves and Third-Generation Detectors”

Yuhan Hua, Karl Wette, Susan M. Scott, Matthew D. Pitkin.

Published on arXiv.