Tropical monitoring and outlooks
Madden-Julian Oscillation (MJO)
The Madden-Julian Oscillation (MJO) is the major fluctuation in tropical weather on weekly to monthly timescales. The MJO can be characterised as an eastward moving 'pulse' of cloud and rainfall near the equator that typically recurs every 30 to 60 days.
Forecast MJO location and strength
The chart shows the strength and progression of the MJO through 8 different areas along the equator around the globe.
Area 3 is north west of Australia, 4 and 5 are to the north (the Maritime Continent), and 6 is to the north east.
RMM1 and RMM2 are mathematical methods that combine cloud amount and winds at upper and lower levels of the atmosphere to provide a measure of the strength and location of the MJO. When this index is within the centre circle the MJO is considered weak. Outside of this circle the index is stronger and will usually move in an anti-clockwise direction as the MJO moves from west to east.
Tropical atmospheric waves
About tropical atmospheric waves
MJO
The Madden–Julian Oscillation (MJO) is the major fluctuation in tropical weather on weekly to monthly timescales. It can be characterised as an eastward moving pulse or wave of cloud and rainfall near the equator that typically recurs every 30 to 60 days.
Other tropical waves in the atmosphere
In addition to the MJO, other large-scale atmospheric waves also occur in the tropics. The main ones are the convectively-coupled Kelvin wave (KW), equatorial Rossby wave (ER), and mixed Rossby-Gravity wave (MRG). They can provide further insight into the current tropical weather, such as the location and development of tropical cyclones, and what may occur over the coming days to weeks. These waves occur year-round, but typically have a greater influence on tropical weather in the Australian region during the wet-season months of October to April.
Kelvin wave (KW)
Equatorial Kelvin waves are alternating low and high pressure centres along the equator that move from west to east. For consistency with the theoretical structure of Kelvin waves, convection (leading to cloudiness and rainfall) near the equator should be on the western side of the low pressure regions. In contrast, clear conditions should be found on the eastern side of the low pressure. Like other atmospheric tropical waves, alternating zones of cloudiness and clear weather can be seen on satellite imagery in association with an active Kelvin wave. The waves move in the same direction as the Madden–Julian Oscillation, from west to east, but typically 2 to 3 times faster.
Equatorial Rossby (ER) wave
In theory there are several different equatorial Rossby waves. The most commonly seen atmospheric ER wave, and the one we discuss here, has high and low pressure regions centred at latitudes about 10 degrees north and south of the equator. To be consistent with theory, the lows and highs should form a symmetric pattern about the equator. Due to the wind flow around these high and low pressure regions, some regions along the equatorial zone favour cloud and rain formation, while other regions favour stable, clear conditions. On satellite imagery equatorial Rossby waves can often be identified due to the presence of cloud systems at similar longitudes on both sides of the equator. These cloud systems, in conjunction with the off-equatorial low pressure, can be the precursors to tropical cyclones on either side of the equator. While equatorial Rossby waves move at a speed close to that of a typical Madden–Julian Oscillation pulse, they move in the opposite direction—from east to west.
Mixed Rossby-Gravity (MRG) wave
Like equatorial Rossby waves, mixed Rossby-Gravity waves also move towards the west, but MRG waves have their pressure centres arranged anti-symmetrically on either side of the equator. This means a low pressure centre on one side of the equator will be opposite a high pressure centre in the other hemisphere. Satellite analysis of mixed Rossby-Gravity waves shows favoured zones for deep convection, often with thunderstorm clusters, in an antisymmetric arrangement about the equator. Their speed of movement to the west is faster than that of an ER wave.
Images are from The COMET® Program, from Introduction to Tropical Meteorology.
The COMET® Website is at http://meted.ucar.edu/ of the University Corporation for Atmospheric Research (UCAR), sponsored in part through cooperative agreement(s) with the National Oceanic and Atmospheric Administration (NOAA), U.S. Department of Commerce (DOC). © 1997–2021 University Corporation for Atmospheric Research. All Rights Reserved.
MJO location and strength
These graphs show the strength and progression of the MJO through 8 different areas along the equator around the globe.
Area 3 is north west of Australia, 4 and 5 are to the north (the Maritime Continent), and 6 is to the north east.
RMM1 and RMM2 are mathematical methods that combine cloud amount and winds at upper and lower levels of the atmosphere to provide a measure of the strength and location of the MJO. When this index is within the centre circle the MJO is considered weak. Outside of this circle the index is stronger and will usually move in an anti-clockwise direction as the MJO moves from west to east.
Download data: RMM Data
*Note: There are missing satellite observations from 16/3/1978 to 31/12/1978.
Methodology: Until the end of 2013 we use the exact method of Wheeler and Hendon (2004, https://doi.org/10.1175/1520-0493(2004)132%3C1917:AARMMI%3E2.0.CO;2) and from 2014 we use the modified method of Gottschalck et al. (2010, https://doi.org/10.1175/2010BAMS2816.1).
Average weekly rainfall probabilities
These maps show average weekly rainfall probabilities for each of the 8 MJO phases. Green shades indicate higher than normal expected rainfall, while brown shades indicates lower than normal expected rainfall.
Select the 'Wind' checkbox to also show the expected 850 hPa (approximately 1.5 km above sea level) wind anomalies. The direction and length of the arrows indicate the direction and strength of the wind anomaly. The darker the arrow, the more reliable the information is.
The relationship of the MJO with global weather patterns changes with the season.
Read more: The Combined Influence of the Madden–Julian Oscillation and El Niño–Southern Oscillation on Australian Rainfall.
These maps show average minimum or maximum temperature anomalies for each of the 8 MJO phases. Red-yellow colours indicate higher than normal temperature, while blue colours indicate lower than normal temperature.
Select the 'Wind' checkbox to also show the expected 850 hPa (approximately 1.5 km above sea level) wind anomalies. The direction and length of the arrows indicate the direction and strength of the wind anomaly. The darker the arrow, the more reliable the information is.
The relationship of the MJO with global weather patterns changes with the season.
Outgoing longwave radiation (OLR) is often used as a way to identify tall, thick, convective rain clouds. These maps show the difference from expected cloudiness based on the position of the MJO. The violet and blue shading indicates higher than normal, active or enhanced tropical weather, while orange shading indicates lower than normal cloud or suppressed conditions.
Select the 'Wind' checkbox to also show the expected 850 hPa (approximately 1.5 km above sea level) wind anomalies. The direction and length of the arrows indicate the direction and strength of the wind anomaly. The darker the arrow, the more reliable the information is.
The relationship of the MJO with global weather patterns changes with the season
These maps show the atmospheric troughs and ridges (in blue and red, respectively) associated with the different phases of the MJO at the 500hPa level. The 500 hPa level is approximately 5500 m above sea level and is about the middle of the troposphere. Colour shading is only used where the geopotential height anomalies are determined to be statistically-significant at the 5% level.
Select the 'Wind' checkbox to also show the expected 850 hPa (approximately 1.5 km above sea level) wind anomalies. The direction and length of the arrows indicate the direction and strength of the wind anomaly. The darker the arrow, the more reliable the information is.
The relationship of the MJO with global weather patterns changes with the season
Global maps of outgoing longwave radiation (OLR)
Global maps of outgoing longwave radiation (OLR) highlight regions experiencing more or less cloudiness. The top panel is the total OLR in Watts per square metre (W/m²) and the bottom panel is the anomaly (current minus the 1979-1998 climate average), in W/m². In the bottom panel, negative values (blue shading) represent above normal cloudiness while positive values (brown shading) represent below normal cloudiness.
OLR totals over the dateline
Regional maps of outgoing longwave radiation (OLR)
The graphs linked to this map show the OLRs for the different regions within the Darwin RSMC area. The horizontal dashed line represents what is normal for that time of year (based on the 1979 to 1998 period). The coloured curve is the 3-day moving average OLR in W/m². Below normal OLR indicates cloudier than normal conditions in this particular area, and is shown in blue shading. Above normal OLR indicates less cloudy conditions and is shown in yellow shading.
Time longitude plots
Time longitude plots of daily averaged OLR anomalies (left) and 850 hPa (approximately 1.5 km above sea level) westerly wind anomalies (right) are useful for indicating the movement of the MJO.
How to read the Time longitude plots
The vertical axis represents time with the most distant past on the top and becoming more recent as you move down the chart. The Horizontal axis represents longitude.
Eastward movement of a strong MJO event would be seen as a diagonal line of violet (downward from left to right) in the OLR diagram, and a corresponding diagonal line of purple in the wind diagram. These diagonal lines would most likely fall between 60°E and 150°E and they would be repeated nearly every 1 to 2 months.
Daily averaged OLR anomalies
Westerly wind anomalies
Recent conditions
The past week has seen the monsoon trough and several embedded tropical lows bring heavy rainfall, thunderstorms and flooding to northern Australia, most significantly impacting northern Queensland and the Northern Territory. In the later part of the week, a trough brought moist tropical air to parts of central and south-east Queensland, resulting in heavy rainfall and flooding.
A tropical low has persisted across the Northern Territory's Top End, and together with a low pressure trough, has brought widespread showers, thunderstorms and heavy falls to the region. For the week ending 9 March, weekly totals exceeding 200 mm were recorded across much of the western and southern Top End, with some locations exceeding 500 mm for the week. Heavy rainfall also impacted the northern Kimberley with weekly totals between 50 and 300 mm for the region. There were several March daily rainfall site records set across the Top End from 5 March, including an annual daily rainfall record at Upper Fergusson River (31 years of data) of 218.8 mm in the 24 hours to 9am 6 March, surpassing the previous record of 169.6 mm set on 3 March 1997.
Flooding impacted the Daly and Katherine rivers, with flooding at Katherine, peaking at around 19.21 m on 7 March, similar to flooding during April 2006 peaking at 19.17 m. Communities were evacuated across the Daly and Katherine catchments, with many residents impacted by power outages, school closures and the closure of Katherine Hospital. Major flood warnings continue for the Daly and Katherine rivers.
Heavy rainfall impacted northern Queensland as tropical low 29U crossed the north Queensland coast near Tully and Innisfail. The system tracked south-west and rapidly weakened once crossing the coast. Daily rainfall peaked on 7 and 8 March, with highest falls around the Wide Bay and Burnett regions in excess of 100 mm across the two days. Over this period, several March and annual daily site records were broken including annual record of 252.6 mm at Dunollie (77 years of data) in the 24 hours to 9 am on 9 March
A trough brought moist tropical air to southern and eastern Queensland resulting in showers and thunderstorms across parts of southern Queensland and eastern New South Wales. For the week ending 9 March, rainfall totals in excess of 200 mm have been recorded across south-eastern and central Queensland, the Central Coast, Gulf Country and North Tropical Coast including in excess of 400 mm in the Cairns region. Heavy rainfall and flooding have resulted in extensive and ongoing road closures across Queensland, particularly across central and eastern areas.
There are currently many moderate to major flood warnings across eastern and central Queensland. These include forecast rapid river rise for the Burnett River, with the potential for flooding close to December 2010 levels at Bundaberg. For the latest flood advice, please visit warnings and alerts page.
Rainfall and temperature forecast
The active monsoon period is expected to continue across northern Australia with showers and thunderstorms expected during the coming week. A tropical low is expected to linger over the Top End during the coming days, bringing further rainfall and flooding.
The forecast for the fortnight of 14 to 27 March, issued 9 March, shows rainfall is likely to be above average across most of the tropical north. There is at least a 60% chance of rainfall being unusually high (amongst the wettest 20% of fortnights for this time of year) for parts of the central Top End and northern Cape York Peninsula. For parts of the Pilbara, Gascoyne and Interior districts of Western Australia, rainfall is likely to be below average for the fortnight.
Maximum temperatures are likely to be below average across most of northern Australia. There is at least a 60% chance of unusually low maximum temperatures (amongst the coldest 20% of fortnights for this time of year) for central Queensland during the fortnight. Minimum temperatures are likely to be above average across most of eastern and northern Queensland, the eastern Top End and most of northern Western Australia.
There are currently no tropical cyclones forecast for the week beginning 10 March. Please refer to the Tropical Cyclone 7-Day Forecast for the latest tropical cyclone forecast in the Australian region.
Madden–Julian Oscillation
A weak to moderate pulse of the Madden-Julian Oscillation (MJO) is currently located in the Maritime Continent. The majority of models show the MJO is likely to progress into the Western Pacific, before weakening later in March. When in the Maritime Continent or Western Pacific, the MJO can increase rainfall over northern Australia, particularly northern Queensland.
Product code: IDCKGEW000
ACKNOWLEDGEMENT: Interpolated OLR data provided by the NOAA/OAR/ESRL PSD, Boulder, Colorado, USA.
Product Code: IDCKGEM000
