There are no active warnings for this location.
Weather Maps
Daily Forecast
Showers about the coasts of northeast QLD and northeast NSW in gusty onshore winds. A front brings showers & brisk winds over southwest Vic and western & southern TAS. High pressure keeps elsewhere dry & mostly clear whilst directing warmth to WA.
Latest Warnings
AUS
Latest News
Climate Updates
Weather in Business
Latest News
Today, 3:24AM UTC
How common are earthquakes in Australia?
A magnitude 3.9 earthquake occurred in the NSW Southern Highlands on Thursday morning, causing the ground to shake as far away as Orange and Canberra. So, how common are earthquakes in Australia and how did this one compare to our country's largest recorded earthquakes? The ‘quake that shook NSW on Thursday morning had an epicentre around 30 km to the north of Goulburn. It was a relatively small and shallow earthquake, with a magnitude of 3.9 and a depth of 10km, according to Geoscience Australia. Despite only being a relatively small tremor, Geoscience Australia received felt reports from as far away as Orange, Canberra, Sydney and Wollongong. Image: Felt reports from Thursday’s earthquake. Source: Geoscience Australia Fortunately, this earthquake was at the weaker end of the scale and as of late on Thursday morning, there were no reports of damage. What is earthquake magnitude? An earthquake’s magnitude is a measure of the energy it releases, and it is ranked using a logarithmic scale. According to Geoscience Australia, each unit of magnitude is roughly 30 times more powerful than the preceding level. This means a magnitude 3.0 earthquake releases 30 times more energy than a magnitude 2.0 earthquake, while a magnitude 4.0 earthquake releases 900 times more energy than a magnitude 2.0 earthquake (30 x 30). This makes higher magnitude earthquakes far more damaging than lower magnitude events. Earthquakes with a magnitude of less than 3.5 are typically too weak to cause damage on the surface in Australia. Once you start getting above a magnitude of 4.0, some slight structural damage and landslips can occur. The smallest earthquake to cause fatalities in Australia was the magnitude 5.4 event that struck Newcastle in 1989. The 10 largest earthquakes observed in Australia reached magnitudes of 6.0 to 6.6, the largest of which occurred near Tennant Creek, NT in 1988. Much larger earthquakes have been observed outside Australia. For example, the earthquake that caused the 2011 tsunami in Japan had a magnitude of 9.1, making it one of the largest in the world since 1900. How often do we have earthquakes in Australia? Earthquakes in Australia are more common than many people may realise. On average, there are around 100 earthquakes of magnitude 3 or higher every year in Australia. Earthquakes above magnitude 5 only happen about once every one-to-two years, while earthquakes measuring magnitude 6 and above only occur about once per decade. You can find out more information about recent and historical Australian earthquakes on the Geoscience Australia website.
Today, 1:13AM UTC
Record run of May heat in Perth
Perth has never seen a run of May days this warm since records started being kept in 1876. Since May 7, Perth's maximum has reached between 24.9°C and 29.4°C every day. The previous record run of May days with a top of 24°C or higher was in 2018, with 16 consecutive days. As of 9 am Thursday, Perth has just equalled the streak of 16 straight days above 24°C, and as mentioned, each of those days has reached at least 24.9°C. So the city is in record-setting territory for late autumn warmth. For perspective, Perth's average May maximum from 1993 to 2023 was 22.3°C at the city's official Perth Metro site. Prior to 1993, the average May maximum at the old Perth regional Office site from 1876 to 1992 was 20.9°C. The two sites are 4 km apart and at a similar elevation, so the average temperature rise is consstent with climate change. Meanwhile the current streak is not over yet. Image: This chart showing max temp anomalies Australia-wide in the week to May 21 is a snapshot of just how warm it has been in southwest WA. Source: BoM. Perth's warm weather looks set to continue with winter barely a week away, with Thursday's top tipped to reach 27°C, followed by highs of 26°C, 24°C and 25°C through to Sunday before things cool down slightly in the new week. OUR PERTH WEATHER FORECAST IS HERE As ever, even the quickest glance at our synoptic chart reveals the reason for the persistent late May warmth. Stubborn, slow-moving high pressure systems centred over the Great Australian Bight have been pushing warm air from the interior of Western Australia towards the southwest of the state (air circulates anti-clockwise around a high). Those same highs have been winning the atmospheric arm wrestle with the cold fronts, forcing most of them south of the mainland. Like most cold fronts to appear on charts in recent weeks, the one situated southwest of the continent in the chart above will also slide south and only graze the SW corner of the state. The front should pack enough of a punch to generate at least a few showers in coming days in Perth itself and across the Lower West, South West and South Coastal forecast districts, although temperatures will remain warm until an injection of slightly cooler air underly southerly winds in the new week. Even chilly old Albany – the southernmost town in Western Australia – is expected to see maximums of 23°C, 25°C, 23°C and 24°C from today through to Sunday. These mild maximums are expected even with the likelihood of showers. Given that cloudy weather tends to reduce the amount of direct sunlight for warming, it shows just how warm the airmass over the southwest corner of WA is for this time of year. Albany's average maximum in May 2024 to date has been 22.7°C. That’s 3.2 degrees warmer than usual.
22 May 2024, 3:46AM UTC
May to become Earth's 14th consecutive month of record ocean warmth
May is on track to become the 14th consecutive month of record-breaking global ocean warmth, despite clear signs of La Niña emerging in the tropical Pacific Ocean. Global sea surface temperatures have broken records in every month since April 2023 and May is now on track to become the 14th consecutive month to set a record for ocean warmth. The graph below shows daily global sea surface temperatures between 1979 and 2024 according to the ECMWF’s highly regarded ERA5 dataset. Image: Daily global sea surface temperatures between 1979 and 2024 using ERA5 data. Source: ECMWF/C3S The thick dark line near the top of the graph is 2024 to date and the orange line below it is 2023. As you can see, all of 2024 and most of 2023 have been warmer than any other similar period on record, by a clear margin. May 2024 is clearly warmer than May 2023 and is on track to become the 14th month in a row to set a new global sea surface temperature record. The map below shows how ocean warmth is currently being distributed across the planet, with orange and red colours showing areas that are warmer than average for this time of year. Blue shading represents areas that are cooler than average for late May. Image: Global sea surface temperature anomaly on May 20, 2024, according to the OISST V2.1 dataset. Source: ClimateReanalyzer.org While there are some broad areas of blue on the map above, the red and orange colours are more dominant and in some places more intense. One of the notable areas of excessive warmth is the North Pacific Ocean between Japan and North America. This broad area of abnormally warm water is associated with a negative phase of the Pacific Decadal Oscillation (PDO). There is also a small tongue of cooler-than-average water in the eastern tropical Pacific Ocean, associated with the early phase of a developing La Niña pattern. While a mature La Niña can noticeably reduce the global ocean temperature, this developing La Niña pattern is currently too small to have a significant influence of global average sea surface temperatures. The reasons for this 14-month run of record-breaking global ocean warmth are an area of active research, although some of the most likely contributing factors include: Ongoing warming due to climate change Additional warming from natural variability (e.g. a negative PDO) Enhanced ocean warming due to reduced air pollution (e.g. reduction in sulphur dioxide emissions from ships) With temperatures currently running above average over so much of the Earth’s oceans, it is possible that this record-breaking run of heat will persist even further into 2024.
Weather in Business
14 May 2024, 3:01AM UTC
Can auroras affect aeroplanes?
Auroras lit up the skies on the weekend amid one of the strongest geomagnetic storms in years, but did this display impact aeroplanes and the aviation industry? The spectacular exhibit was the aurora borealis/australis, or northern and southern lights seen in both hemispheres. Images: Aurora Australis on Saturday, May 11 from Bendleby Ranges, SA (top), source: @bendlebyranges and Ricketts Point, Vic (bottom), source: @dayofthedreamer These lights are typically only seen in the polar latitudes, but this weekend they were spotted in the Southern Hemisphere as far north as Mackay in Queensland. This was caused by the strongest solar flare and storm seen in over 20 years. This auroral display was caused by a solar flare and multiple coronal mass ejections (CMEs) which erupted from the sun over a few days last week. Charged particles were then carried from the sun to earth by a solar wind. When these particles reached earth, they interacted with our planet’s magnetic field and were driven towards the magnetic poles. In the upper layer of the atmosphere called the ionosphere (90km above the surface) the solar wind collides with oxygen and nitrogen in this layer and produces a colorful display. The southern lights typically occur between 50 and 800km above the surface, well above the layer of atmosphere that planes typically fly in. So, do they impact aviation despite occurring well above the flight level? Yes, space weather events like this can impact aviation communications, navigation and surveillance systems. They can also increase the radiation exposure of aircraft in the air. Images: Aurora Australis from Virgin plane cockpit on Saturday, May 11. Source: @shelbytillett The charged particles caused by CMEs can modify the upper layer of earth's atmosphere called the ionosphere, which can impact our technology systems. High frequency radio communication depends on the ionosphere reflecting radio waves back down to earth. Satellite communication, navigation and surveillance rely on the transmission of signals through the ionosphere. According to the Bureau of Meteorology’s space weather department, >Space weather events that modify the density and/or structure of the ionosphere can therefore significantly impact the performance of HF COM, SATCOM and SATNAV systems". While communication and navigation can be impacted by the modification of the ionosphere, the electricity network can also be impacted. The storms can induce currents in power lines, overheating transformers, which can potentially cause power outages. The strongest geomagnetic storm ever recorded occurred during September 1859, called the Carrington Event. This event caused multiple fires of telegraph systems across Europe and North America. There have been no reports of negative major impacts of this solar storm, it was merely a spectacular display that captivated people across the world. Unfortunately, auroras are notoriously difficult to forecast as they need multiple factors to line up for these beautiful lights to occur. Looking ahead, the sun is nearing its solar maximum, which means we could see more sunspots on the sun's surface this year. This could increase our chance of seeing more spectacular displays in the coming months.
07 May 2024, 11:23PM UTC
How severe thunderstorms impact energy infrastructure
Earlier this year destructive thunderstorms and winds equivalent to a category two cyclone lashed Victoria, bending towers and toppling trees and poles. So, how can thunderstorms damage energy infrastructure, and are these events getting worse? This event occurred during mid-February 2024, when a strong cold front generated severe thunderstorms and localised wind gusts of 130km/h after a prolonged period of extreme heat. The image below shows a squall line around 1,500km long causing lightning across four states in February. Image: Himawari-9 satellite image, lightning and radar on Tuesday, February 13 at 3pm AEDT. The destructive winds were caused by microbursts, which bent towers and toppled trees and poles in Vic, leaving thousands without power. Image: Damaged transmission towers at Anakie, Source: AAP Microbursts are a localised column of sinking air (downdraft) within a thunderstorm and is usually less than 4km wide. The cold, heavy air within this downdraft descends rapidly to the surface and then spreads out in all directions as it hits the ground. The image below shows how wind gusts are produced in thunderstorms. Microbursts can be destructive and cause wind gusts above 100 km/h, which can be a risk for power infrastructure. The force applied to the structure is roughly proportional to the speed squared. Fierce wind gusts from thunderstorms can: Knock down trees, which can fall onto power lines Topple poles Knock out transmission towers. Microbursts typically occur during the warmer months of the year and, unfortunately, they can develop rapidly and last for only a short period of time, making them difficult to predict and warn communities about. Have these thunderstorm events become more severe in Victoria? The severe thunderstorm season across southern Australia occurs during the warmer months of the year, between November and April. While thunderstorms are more common across northern Australia, Qld, and NSW, they do occur frequently in the summer months. The map below shows the annual average lightning density in Vic between July 2014 and June 2023, with the most lightning occurring in the northeast high country each year. Image: Weatherzone’s Total Lightning Network Annual lightning density mean between July 2014 and June 2023. You can see in the map above that lightning is common to the north of Ballarat near Learmonth and Miners Rest, with the region seeing 37.7 pulses per year. The high country near Benalla and Whitfield recorded an average of 28.1 pulses, Thorpdale in Gippsland saw 24.5 pulses, and Melbourne only 8.2 pulses per year. Research has shown that the warming climate is increasing the risk of heatwaves and bushfires, which can impact energy infrastructure. Unfortunately, it is unknown how global warming will affect thunderstorms and their associated destructive winds. To research climate change's impact on thunderstorms, we would need quality data that dates back well into history. Unfortunately, detecting lightning is a fairly new phenomena, so a solid climate base to compare data to is not currently existent. According to the University of Melbourne researchers and Watt Clarity, ‘The evidence we do have suggests continued climate change may potentially increase the risk of extreme winds from thunderstorms. This is partly due to more moist and unstable air, which are essential for thunderstorms to form. We think these conditions could occur more often with climate change, in part because warmer air can hold more moisture.’ Indeed, much of Australia had an unusually stormy summer 2023/24, with Melbourne, Canberra and Brisbane all seeing 5 to 6 extra storm days a season. The map below shows that an unusually high number of thunder days were seen over most of Qld, NSW, SA, Vic, the ACT and Tas during the summer of 2023/24 compared to the average of the most recent nine years. Image: Thunder day anomalies for summer 2023-24 versus the average thunder days for the nation’s nine most recent summers (2014/15 to 2022/23).
