Postgraduate Study Live Q&A
Join us for a live Q&A with our student support teams to learn more about postgraduate funding, research opportunities, application support from our admissions team. Plus, ask your questions to current students
Join us for a live Q&A with our student support teams to learn more about postgraduate funding, research opportunities, application support from our admissions team. Plus, ask your questions to current students
The Environmental Sustainability and Energy Team at LJMU have received funding from Cycling UK to carry out a number of events for the Big Bike Revival.
The Environmental Sustainability and Energy Team at LJMU have received funding from Cycling UK to carry out a number of events for the Big Bike Revival.
The Environmental Sustainability and Energy Team at LJMU have received funding from Cycling UK to carry out a number of events for the Big Bike Revival.
The Environmental Sustainability and Energy Team at LJMU have received funding from Cycling UK to carry out a number of events for the Big Bike Revival.
The Environmental Sustainability and Energy Team at LJMU have received funding from Cycling UK to carry out a number of events for the Big Bike Revival.
The Environmental Sustainability and Energy Team at LJMU have received funding from Cycling UK to carry out a number of events for the Big Bike Revival.
The Environmental Sustainability and Energy Team at LJMU have received funding from Cycling UK to carry out a number of events for the Big Bike Revival.
The Environmental Sustainability and Energy Team at LJMU have received funding from Cycling UK to carry out a number of events for the Big Bike Revival.
A neutron star binary merges somewhere in the Universe approximately every 10 to 1000 seconds, creating violent explosions potentially observable in gravitational waves and across the electromagnetic spectrum. The transformative coincident gravitational wave and electromagnetic observations of the binary neutron star merger GW170817 gave invaluable insights into these cataclysmic collisions and fundamental astrophysics. However, despite our high expectations, we have failed to see any other event like it. In this talk, I will highlight what we can learn from other observations of mergers seen directly in gravitational waves or indirectly as a gamma-ray burst and/or kilonova. I will also discuss the diversity in electromagnetic and gravitational-wave emission we can expect for future mergers and showcase tools to help maximally extract physics from existing and future observations.