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Madden–Julian oscillation

April 11, 2024

"MJO" redirects here. For other uses, see MJO (disambiguation).

The Madden–Julian oscillation (MJO) is the largest element of the intraseasonal (30- to 90-day) variability in the tropical atmosphere. It was discovered in 1971 by Roland Madden and Paul Julian of the American National Center for Atmospheric Research (NCAR).[1] It is a large-scale coupling between atmospheric circulation and tropical deep atmospheric convection.[2][3] Unlike a standing pattern like the El Niño–Southern Oscillation (ENSO), the Madden–Julian oscillation is a traveling pattern that propagates eastward, at approximately 4 to 8 m/s (14 to 29 km/h; 9 to 18 mph), through the atmosphere above the warm parts of the Indian and Pacific oceans. This overall circulation pattern manifests itself most clearly as anomalous rainfall.

A Hovmöller diagram of the 5-day running mean of outgoing longwave radiation showing the MJO. Time increases from top to bottom in the figure, so contours that are oriented from upper-left to lower-right represent movement from west to east.

The Madden–Julian oscillation is characterized by an eastward progression of large regions of both enhanced and suppressed tropical rainfall, observed mainly over the Indian and Pacific Ocean. The anomalous rainfall is usually first evident over the western Indian Ocean, and remains evident as it propagates over the very warm ocean waters of the western and central tropical Pacific. This pattern of tropical rainfall generally becomes nondescript as it moves over the primarily cooler ocean waters of the eastern Pacific, but reappears when passing over the warmer waters over the Pacific Coast of Central America. The pattern may also occasionally reappear at low amplitude over the tropical Atlantic and higher amplitude over the Indian Ocean. The wet phase of enhanced convection and precipitation is followed by a dry phase where thunderstorm activity is suppressed. Each cycle lasts approximately 30–60 days. Because of this pattern, the Madden–Julian oscillation is also known as the 30- to 60-day oscillation, 30- to 60-day wave, or intraseasonal oscillation.

Behavior edit

 
The structure of the MJO for a period when the enhanced convective phase is centered across the Indian Ocean and the suppressed convective phase is centered over the west-central Pacific Ocean

Distinct patterns of lower-level and upper-level atmospheric circulation anomalies accompany the MJO-related pattern of enhanced or decreased tropical rainfall across the tropics. These circulation features extend around the globe and are not confined to only the eastern hemisphere. The Madden–Julian oscillation moves eastward at between 4 m/s (14 km/h, 9 mph) and 8 m/s (29 km/h, 18 mph) across the tropics, crossing the Earth's tropics in 30 to 60 days—with the active phase of the MJO tracked by the degree of outgoing long wave radiation, which is measured by infrared-sensing geostationary weather satellites. The lower the amount of outgoing long wave radiation, the stronger the thunderstorm complexes, or convection, is within that region.[4]

Enhanced surface (upper level) westerly winds occur near the west (east) side of the active convection.[5] Ocean currents, up to 100 metres (330 ft) in depth from the ocean surface, follow in phase with the east-wind component of the surface winds. In advance, or to the east, of the MJO enhanced activity, winds aloft are westerly. In its wake, or to the west of the enhanced rainfall area, winds aloft are easterly. These wind changes aloft are due to the divergence present over the active thunderstorms during the enhanced phase. Its direct influence can be tracked poleward as far as 30 degrees latitude from the equator in both northern and southern hemispheres, propagating outward from its origin near the equator at around 1 degree latitude, or 111 kilometres (69 mi), per day.[6]

Irregularities edit

The MJO's movement around the globe can occasionally slow or stall during the Northern Hemisphere summer and early autumn, leading to consistently enhanced rainfall for one side of the globe and consistently depressed rainfall for the other side.[7][8][9][10][11][12][13][14] This can also happen early in the year.[10][15][16] The MJO can also go quiet for a period of time, which leads to non-anomalous storm activity in each region of the globe.[17][18][19][13][20][21]

Local effects edit

Connection to the monsoon edit

 
Onset dates and prevailing wind currents of the southwest summer monsoon.
See also: Monsoon and Monsoon trough

During the Northern Hemisphere summer season the MJO-related effects on the Indian and West African summer monsoon are well documented. MJO-related effects on the North American summer monsoon also occur, though they are relatively weaker. MJO-related impacts on the North American summer precipitation patterns are strongly linked to meridional (i.e. north–south) adjustments of the precipitation pattern in the eastern tropical Pacific. A strong relationship between the leading mode of intraseasonal variability of the North American Monsoon System, the MJO and the points of origin of tropical cyclones is also present.

A period of warming sea surface temperatures is found five to ten days prior to a strengthening of MJO-related precipitation across southern Asia. A break in the Asian monsoon, normally during the month of July, has been attributed to the Madden–Julian oscillation after its enhanced phase moves off to the east of the region into the open tropical Pacific Ocean.[22]

Influence on tropical cyclogenesis edit

See also: Tropical cyclogenesis

Tropical cyclones occur throughout the boreal warm season (typically May–November) in both the north Pacific and the north Atlantic basins—but any given year has periods of enhanced or suppressed activity within the season. Evidence suggests that the Madden–Julian oscillation modulates this activity (particularly for the strongest storms) by providing a large-scale environment that is favorable (or unfavorable) for development. MJO-related descending motion is not favorable for tropical storm development. However, MJO-related ascending motion is a favorable pattern for thunderstorm formation within the tropics, which is quite favorable for tropical storm development. As the MJO progresses eastward, the favored region for tropical cyclone activity also shifts eastward from the western Pacific to the eastern Pacific and finally to the Atlantic basin.

An inverse relationship exists between tropical cyclone activity in the western north Pacific basin and the north Atlantic basin, however. When one basin is active, the other is normally quiet, and vice versa. The main reason for this appears to be the phase of the MJO, which is normally in opposite modes between the two basins at any given time.[23] While this relationship appears robust, the MJO is one of many factors that contribute to the development of tropical cyclones. For example, sea surface temperatures must be sufficiently warm and vertical wind shear must be sufficiently weak for tropical disturbances to form and persist.[24] However, the MJO also influences these conditions that facilitate or suppress tropical cyclone formation. The MJO is monitored routinely by both the USA National Hurricane Center and the USA Climate Prediction Center during the Atlantic hurricane (tropical cyclone) season to aid in anticipating periods of relative activity or inactivity.[25]

Influence on African rainfall edit

The MJO signal is well defined in parts of Africa including in the Congo Basin and East Africa. During the major rainy seasons in East Africa (March to May and October to December), rainfall tends to be lower during when the MJO convective core is over the eastern Pacific, and higher when convection peaks over the Indian Ocean.[26][27] During 'wet' phases, the normal easterly winds weaken, while during 'dry' phases, the easterly winds strengthen.[28]

An increase in frequency of MJO phases with convective activity over the eastern Pacific might have contributed to the drying trend seen in the Congo Basin in the last few decades.[29][30]

Downstream effects edit

Link to the El Niño-Southern oscillation edit

See also: El Niño–Southern Oscillation

There is strong year-to-year (interannual) variability in Madden–Julian oscillation activity, with long periods of strong activity followed by periods in which the oscillation is weak or absent. This interannual variability of the MJO is partly linked to the El Niño–Southern Oscillation (ENSO) cycle. In the Pacific, strong MJO activity is often observed 6 to 12 months prior to the onset of an El Niño episode, but is virtually absent during the maxima of some El Niño episodes, while MJO activity is typically greater during a La Niña episode. Strong events in the Madden–Julian oscillation over a series of months in the western Pacific can speed the development of an El Niño or La Niña but usually do not in themselves lead to the onset of a warm or cold ENSO event.[31] However, observations suggest that the 1982-1983 El Niño developed rapidly during July 1982 in direct response to a Kelvin wave triggered by an MJO event during late May.[32] Further, changes in the structure of the MJO with the seasonal cycle and ENSO might facilitate more substantial impacts of the MJO on ENSO. For example, the surface westerly winds associated with active MJO convection are stronger during advancement toward El Niño and the surface easterly winds associated with the suppressed convective phase are stronger during advancement toward La Niña.[33] Globally, the interannual variability of the MJO is most determined by atmospheric internal dynamics, rather than surface conditions.[clarification needed]

North American winter precipitation edit

See also: Effects of the El Niño–Southern Oscillation in the United States and United States rainfall climatology

The strongest impacts of intraseasonal variability on the United States occur during the winter months over the western U.S. During the winter this region receives the bulk of its annual precipitation. Storms in this region can last for several days or more and are often accompanied by persistent atmospheric circulation features. Of particular concern are extreme precipitation events linked to flooding. Strong evidence suggests a link between weather and climate in this region from studies that have related the El Niño Southern Oscillation to regional precipitation variability. In the tropical Pacific, winters with weak-to-moderate cold, or La Niña, episodes or ENSO-neutral conditions are often characterized by enhanced 30- to 60-day Madden–Julian oscillation activity. A recent example is the winter of 1996–1997, which featured heavy flooding in California and in the Pacific Northwest (estimated damage costs of $2.0–3.0 billion at the time of the event) and a very active MJO. Such winters are also characterized by relatively small sea surface temperature anomalies in the tropical Pacific compared to stronger warm and cold episodes. In these winters, there is a stronger link between the MJO events and extreme west coast precipitation events.

Pineapple Express events edit

Main article: Pineapple Express
 
The Pineapple Express, an MJO effect on North American weather patterns.

The typical scenario linking the pattern of tropical rainfall associated with the MJO to extreme precipitation events in the Pacific Northwest features a progressive (i.e. eastward moving) circulation pattern in the tropics and a retrograding (i.e. westward moving) circulation pattern in the mid latitudes of the North Pacific. Typical wintertime weather anomalies preceding heavy precipitation events in the Pacific Northwest are as follows:[34]

  1. 7–10 days prior to the heavy precipitation event: Heavy tropical rainfall associated with the MJO shifts eastward from the eastern Indian Ocean to the western tropical Pacific. A moisture plume extends northeastward from the western tropical Pacific towards the general vicinity of the Hawaiian Islands. A strong blocking anticyclone is located in the Gulf of Alaska with a strong polar jet stream around its northern flank.[34]
  2. 3–5 days prior to the heavy precipitation event: Heavy tropical rainfall shifts eastward towards the date line and begins to diminish. The associated moisture plume extends further to the northeast, often traversing the Hawaiian Islands. The strong blocking high weakens and shifts westward. A split in the North Pacific jet stream develops, characterized by an increase in the amplitude and areal extent of the upper tropospheric westerly zonal winds on the southern flank of the block and a decrease on its northern flank. The tropical and extra tropical circulation patterns begin to "phase", allowing a developing mid latitude trough to tap the moisture plume extending from the deep tropics.[34]
  3. The heavy precipitation event: As the pattern of enhanced tropical rainfall continues to shift further to the east and weaken, the deep tropical moisture plume extends from the subtropical central Pacific into the mid latitude trough now located off the west coast of North America. The jet stream at upper levels extends across the North Pacific with the mean jet position entering North America in the northwestern United States. The deep low pressure located near the Pacific Northwest coast can bring up to several days of heavy rain and possible flooding. These events are often referred to as Pineapple Express events, so named because a significant amount of the deep tropical moisture traverses the Hawaiian Islands on its way towards western North America.[34]

Throughout this evolution, retrogression of the large-scale atmospheric circulation features is observed in the eastern Pacific–North American sector. Many of these events are characterized by the progression of the heaviest precipitation from south to north along the Pacific Northwest coast over a period of several days to more than one week. However, it is important to differentiate the individual synoptic-scale storms, which generally move west to east, from the overall large-scale pattern, which exhibits retrogression.[34]

A coherent simultaneous relationship exists between the longitudinal position of maximum MJO-related rainfall and the location of extreme west coast precipitation events. Extreme events in the Pacific Northwest are accompanied by enhanced precipitation over the western tropical Pacific and the region of Southeast Asia called by meteorologists the Maritime Continent, with suppressed precipitation over the Indian Ocean and the central Pacific. As the region of interest shifts from the Pacific Northwest to California, the region of enhanced tropical precipitation shifts further to the east. For example, extreme rainfall events in southern California are typically accompanied by enhanced precipitation near 170°E. However, it is important to note that the overall link between the MJO and extreme west coast precipitation events weakens as the region of interest shifts southward along the west coast of the United States.[34]

There is case-to-case variability in the amplitude and longitudinal extent of the MJO-related precipitation, so this should be viewed as a general relationship only.[34]

Explaining MJO's dynamics with equatorial modons and equatorial adjustment edit

Eastward propagating structure of barotropic equatorial modon edit

See also: modon

In 2019, Rostami and Zeitlin[35] reported a discovery of steady, long-living, slowly eastward-moving large-scale coherent twin cyclones, so-called equatorial modons, by means of a moist-convective rotating shallow water model. Crudest barotropic features of MJO such as eastward propagation along the equator, slow phase speed, hydro-dynamical coherent structure, the convergent zone of moist-convection, are captured by Rostami and Zeitlin's modon. Having an exact solution of streamlines for internal and external regions of equatorial asymptotic modon is another feature of this structure. It is shown that such eastward-moving coherent dipolar structures can be produced during geostrophic adjustment of localized large-scale pressure anomalies in the diabatic moist-convective environment on the equator.[36]

Generation of MJO-like structure by geostrophic adjustment in the lower troposphere edit

In 2020, a study showed that the process of relaxation (adjustment) of localized large-scale pressure anomalies in the lower equatorial troposphere,[37] generates structures strongly resembling the Madden Julian Oscillation (MJO) events, as seen in vorticity, pressure, and moisture fields. Indeed, it is demonstrated that baroclinicity and moist convection substantially change the scenario of the quasi-barotropic "dry" adjustment, which was established in the framework of one-layer shallow water model and consists, in the long-wave sector, in the emission of equatorial Rossby waves, with dipolar meridional structure, to the West, and of equatorial Kelvin waves, to the East. If moist convection is strong enough, a dipolar cyclonic structure, which appears in the process of adjustment as a Rossby-wave response to the perturbation, transforms into a coherent modon-like structure in the lower layer, which couples with a baroclinic Kelvin wave through a zone of enhanced convection and produces, at initial stages of the process, a self-sustained slowly eastward-propagating zonally- dissymmetrical quadrupolar vorticity pattern.

In 2022, Rostami et al [38] advanced their theory. By means of a new multi-layer pseudo-spectral moist-convective Thermal Rotating Shallow Water (mcTRSW) model in a full sphere, they presented a possible equatorial adjustment beyond Gill's mechanism for the genesis and dynamics of the MJO. According to this theory, an eastward propagating MJO-like structure can be generated in a self-sustained and self-propelled manner due to nonlinear relaxation (adjustment) of a large-scale positive buoyancy anomaly, depressed anomaly, or a combination of them, as soon as this anomaly reaches a critical threshold in the presence of moist-convection at the equator. This MJO-like episode possesses a convectively coupled “hybrid structure” that consists of a “quasi equatorial modon”, with an enhanced vortex pair, and a convectively coupled baroclinic Kelvin wave (BKW), with greater phase speed than that of dipolar structure on the intraseasonal time scale. Interaction of the BKW, after circumnavigating all around the equator, with a new large-scale buoyancy anomaly may contribute to excitation of a recurrent generation of the next cycle of MJO-like structure. Overall, the generated "hybrid structure” captures a few of the crudest features of the MJO, including its quadrupolar structure, convective activity, condensation patterns, vorticity field, phase speed, and westerly and easterly inflows in the lower and upper troposphere. Although the moisture-fed convection is a necessary condition for the ``hybrid structure” to be excited and maintained in the proposed theory in this theory, it is fundamentally different from the moisture-mode ones. Because the barotropic equatorial modon and BKW also exist in “dry” environments, while there are no similar “dry” dynamical basic structures in the moisture-mode theories. The proposed theory can be a possible mechanism to explain the genesis and backbone structure of the MJO and to converge some theories that previously seemed divergent.

Impact of climate change on MJO edit

The MJO travels a stretch of 12,000–20,000 km over the tropical oceans, mainly over the Indo-Pacific warm pool, which has ocean temperatures generally warmer than 28 °C. This Indo-Pacific warm pool has been warming rapidly, altering the residence time of MJO over the tropical oceans. While the total lifespan of MJO remains in the 30–60 day timescale, its residence time has shortened over the Indian Ocean by 3–4 days (from an average of 19 days to 15 days) and increased by 5–6 days over the West Pacific (from an average of 18 days to 23 days).[39] This change in the residence time of MJO has altered the rainfall patterns across the globe.[39][40]

References edit

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External links edit

 
Wikimedia Commons has media related to Madden-Julian Oscillation.
  • "Daily Madden–Julian Oscillation Indices". National Weather Service Climate Prediction Center. Retrieved March 29, 2005.
  • . Agricultural Production Systems Research Unit. Archived from the original on June 12, 2007. Retrieved July 13, 2007.
  • "The influence of intraseasonal variations of tropical convection on sea surface temperatures at the onset of the 1997–98 El Niño". NOAA-CIRES Climate Diagnostics Center Climate Research Spotlight. Retrieved March 29, 2005.
  • Lin, J.; Kiladis, G.N.; Mapes, B.E.; Weickmann, K.M.; Sperber, K.R.; Lin, W.; Wheeler, M.C.; Schubert, S.D.; Del Genio, A.; Donner, L.J.; Emori, S.; Gueremy, J.; Hourdin, F.; Rasch, P.J.; Roeckner, E.; Scinocca, J.F. (2006). "Tropical Intraseasonal Variability in 14 IPCC AR4 Climate Models. Part I: Convective Signals". Journal of Climate. 19 (12): 2665–90. Bibcode:2006JCli...19.2665L. doi:10.1175/JCLI3735.1. hdl:11858/00-001M-0000-0011-FC85-9.
  • Kim, J.; Ho, C.; Kim, H.; Sui, C.; Park, S.K. (2008). "Systematic Variation of Summertime Tropical Cyclone Activity in the Western North Pacific in Relation to the Madden–Julian Oscillation". J. Climate. 21 (6): 1171–91. Bibcode:2008JCli...21.1171K. doi:10.1175/2007JCLI1493.1.
  • Ho, C.-H.; Kim, J.-H.; Jeong, J.-H.; Kim, H.-S.; Chen, D. (2006). "Variation of tropical cyclone activity in the South Indian Ocean: El Niño–Southern Oscillation and Madden–Julian Oscillation effects". Journal of Geophysical Research. 111 (D22): D22101. Bibcode:2006JGRD..11122101H. doi:10.1029/2006JD007289.

April 11, 2024
madden, julian, oscillation, redirects, here, other, uses, disambiguation, largest, element, intraseasonal, variability, tropical, atmosphere, discovered, 1971, roland, madden, paul, julian, american, national, center, atmospheric, research, ncar, large, scale. MJO redirects here For other uses see MJO disambiguation The Madden Julian oscillation MJO is the largest element of the intraseasonal 30 to 90 day variability in the tropical atmosphere It was discovered in 1971 by Roland Madden and Paul Julian of the American National Center for Atmospheric Research NCAR 1 It is a large scale coupling between atmospheric circulation and tropical deep atmospheric convection 2 3 Unlike a standing pattern like the El Nino Southern Oscillation ENSO the Madden Julian oscillation is a traveling pattern that propagates eastward at approximately 4 to 8 m s 14 to 29 km h 9 to 18 mph through the atmosphere above the warm parts of the Indian and Pacific oceans This overall circulation pattern manifests itself most clearly as anomalous rainfall A Hovmoller diagram of the 5 day running mean of outgoing longwave radiation showing the MJO Time increases from top to bottom in the figure so contours that are oriented from upper left to lower right represent movement from west to east The Madden Julian oscillation is characterized by an eastward progression of large regions of both enhanced and suppressed tropical rainfall observed mainly over the Indian and Pacific Ocean The anomalous rainfall is usually first evident over the western Indian Ocean and remains evident as it propagates over the very warm ocean waters of the western and central tropical Pacific This pattern of tropical rainfall generally becomes nondescript as it moves over the primarily cooler ocean waters of the eastern Pacific but reappears when passing over the warmer waters over the Pacific Coast of Central America The pattern may also occasionally reappear at low amplitude over the tropical Atlantic and higher amplitude over the Indian Ocean The wet phase of enhanced convection and precipitation is followed by a dry phase where thunderstorm activity is suppressed Each cycle lasts approximately 30 60 days Because of this pattern the Madden Julian oscillation is also known as the 30 to 60 day oscillation 30 to 60 day wave or intraseasonal oscillation Contents 1 Behavior 1 1 Irregularities 2 Local effects 2 1 Connection to the monsoon 2 2 Influence on tropical cyclogenesis 2 3 Influence on African rainfall 3 Downstream effects 3 1 Link to the El Nino Southern oscillation 3 2 North American winter precipitation 3 2 1 Pineapple Express events 4 Explaining MJO s dynamics with equatorial modons and equatorial adjustment 4 1 Eastward propagating structure of barotropic equatorial modon 4 2 Generation of MJO like structure by geostrophic adjustment in the lower troposphere 5 Impact of climate change on MJO 6 References 7 External linksBehavior edit nbsp The structure of the MJO for a period when the enhanced convective phase is centered across the Indian Ocean and the suppressed convective phase is centered over the west central Pacific OceanDistinct patterns of lower level and upper level atmospheric circulation anomalies accompany the MJO related pattern of enhanced or decreased tropical rainfall across the tropics These circulation features extend around the globe and are not confined to only the eastern hemisphere The Madden Julian oscillation moves eastward at between 4 m s 14 km h 9 mph and 8 m s 29 km h 18 mph across the tropics crossing the Earth s tropics in 30 to 60 days with the active phase of the MJO tracked by the degree of outgoing long wave radiation which is measured by infrared sensing geostationary weather satellites The lower the amount of outgoing long wave radiation the stronger the thunderstorm complexes or convection is within that region 4 Enhanced surface upper level westerly winds occur near the west east side of the active convection 5 Ocean currents up to 100 metres 330 ft in depth from the ocean surface follow in phase with the east wind component of the surface winds In advance or to the east of the MJO enhanced activity winds aloft are westerly In its wake or to the west of the enhanced rainfall area winds aloft are easterly These wind changes aloft are due to the divergence present over the active thunderstorms during the enhanced phase Its direct influence can be tracked poleward as far as 30 degrees latitude from the equator in both northern and southern hemispheres propagating outward from its origin near the equator at around 1 degree latitude or 111 kilometres 69 mi per day 6 Irregularities edit The MJO s movement around the globe can occasionally slow or stall during the Northern Hemisphere summer and early autumn leading to consistently enhanced rainfall for one side of the globe and consistently depressed rainfall for the other side 7 8 9 10 11 12 13 14 This can also happen early in the year 10 15 16 The MJO can also go quiet for a period of time which leads to non anomalous storm activity in each region of the globe 17 18 19 13 20 21 Local effects editConnection to the monsoon edit nbsp Onset dates and prevailing wind currents of the southwest summer monsoon See also Monsoon and Monsoon trough During the Northern Hemisphere summer season the MJO related effects on the Indian and West African summer monsoon are well documented MJO related effects on the North American summer monsoon also occur though they are relatively weaker MJO related impacts on the North American summer precipitation patterns are strongly linked to meridional i e north south adjustments of the precipitation pattern in the eastern tropical Pacific A strong relationship between the leading mode of intraseasonal variability of the North American Monsoon System the MJO and the points of origin of tropical cyclones is also present A period of warming sea surface temperatures is found five to ten days prior to a strengthening of MJO related precipitation across southern Asia A break in the Asian monsoon normally during the month of July has been attributed to the Madden Julian oscillation after its enhanced phase moves off to the east of the region into the open tropical Pacific Ocean 22 Influence on tropical cyclogenesis edit See also Tropical cyclogenesis Tropical cyclones occur throughout the boreal warm season typically May November in both the north Pacific and the north Atlantic basins but any given year has periods of enhanced or suppressed activity within the season Evidence suggests that the Madden Julian oscillation modulates this activity particularly for the strongest storms by providing a large scale environment that is favorable or unfavorable for development MJO related descending motion is not favorable for tropical storm development However MJO related ascending motion is a favorable pattern for thunderstorm formation within the tropics which is quite favorable for tropical storm development As the MJO progresses eastward the favored region for tropical cyclone activity also shifts eastward from the western Pacific to the eastern Pacific and finally to the Atlantic basin An inverse relationship exists between tropical cyclone activity in the western north Pacific basin and the north Atlantic basin however When one basin is active the other is normally quiet and vice versa The main reason for this appears to be the phase of the MJO which is normally in opposite modes between the two basins at any given time 23 While this relationship appears robust the MJO is one of many factors that contribute to the development of tropical cyclones For example sea surface temperatures must be sufficiently warm and vertical wind shear must be sufficiently weak for tropical disturbances to form and persist 24 However the MJO also influences these conditions that facilitate or suppress tropical cyclone formation The MJO is monitored routinely by both the USA National Hurricane Center and the USA Climate Prediction Center during the Atlantic hurricane tropical cyclone season to aid in anticipating periods of relative activity or inactivity 25 Influence on African rainfall edit The MJO signal is well defined in parts of Africa including in the Congo Basin and East Africa During the major rainy seasons in East Africa March to May and October to December rainfall tends to be lower during when the MJO convective core is over the eastern Pacific and higher when convection peaks over the Indian Ocean 26 27 During wet phases the normal easterly winds weaken while during dry phases the easterly winds strengthen 28 An increase in frequency of MJO phases with convective activity over the eastern Pacific might have contributed to the drying trend seen in the Congo Basin in the last few decades 29 30 Downstream effects editLink to the El Nino Southern oscillation edit See also El Nino Southern Oscillation There is strong year to year interannual variability in Madden Julian oscillation activity with long periods of strong activity followed by periods in which the oscillation is weak or absent This interannual variability of the MJO is partly linked to the El Nino Southern Oscillation ENSO cycle In the Pacific strong MJO activity is often observed 6 to 12 months prior to the onset of an El Nino episode but is virtually absent during the maxima of some El Nino episodes while MJO activity is typically greater during a La Nina episode Strong events in the Madden Julian oscillation over a series of months in the western Pacific can speed the development of an El Nino or La Nina but usually do not in themselves lead to the onset of a warm or cold ENSO event 31 However observations suggest that the 1982 1983 El Nino developed rapidly during July 1982 in direct response to a Kelvin wave triggered by an MJO event during late May 32 Further changes in the structure of the MJO with the seasonal cycle and ENSO might facilitate more substantial impacts of the MJO on ENSO For example the surface westerly winds associated with active MJO convection are stronger during advancement toward El Nino and the surface easterly winds associated with the suppressed convective phase are stronger during advancement toward La Nina 33 Globally the interannual variability of the MJO is most determined by atmospheric internal dynamics rather than surface conditions clarification needed North American winter precipitation edit See also Effects of the El Nino Southern Oscillation in the United States and United States rainfall climatology The strongest impacts of intraseasonal variability on the United States occur during the winter months over the western U S During the winter this region receives the bulk of its annual precipitation Storms in this region can last for several days or more and are often accompanied by persistent atmospheric circulation features Of particular concern are extreme precipitation events linked to flooding Strong evidence suggests a link between weather and climate in this region from studies that have related the El Nino Southern Oscillation to regional precipitation variability In the tropical Pacific winters with weak to moderate cold or La Nina episodes or ENSO neutral conditions are often characterized by enhanced 30 to 60 day Madden Julian oscillation activity A recent example is the winter of 1996 1997 which featured heavy flooding in California and in the Pacific Northwest estimated damage costs of 2 0 3 0 billion at the time of the event and a very active MJO Such winters are also characterized by relatively small sea surface temperature anomalies in the tropical Pacific compared to stronger warm and cold episodes In these winters there is a stronger link between the MJO events and extreme west coast precipitation events Pineapple Express events edit Main article Pineapple Express nbsp The Pineapple Express an MJO effect on North American weather patterns The typical scenario linking the pattern of tropical rainfall associated with the MJO to extreme precipitation events in the Pacific Northwest features a progressive i e eastward moving circulation pattern in the tropics and a retrograding i e westward moving circulation pattern in the mid latitudes of the North Pacific Typical wintertime weather anomalies preceding heavy precipitation events in the Pacific Northwest are as follows 34 7 10 days prior to the heavy precipitation event Heavy tropical rainfall associated with the MJO shifts eastward from the eastern Indian Ocean to the western tropical Pacific A moisture plume extends northeastward from the western tropical Pacific towards the general vicinity of the Hawaiian Islands A strong blocking anticyclone is located in the Gulf of Alaska with a strong polar jet stream around its northern flank 34 3 5 days prior to the heavy precipitation event Heavy tropical rainfall shifts eastward towards the date line and begins to diminish The associated moisture plume extends further to the northeast often traversing the Hawaiian Islands The strong blocking high weakens and shifts westward A split in the North Pacific jet stream develops characterized by an increase in the amplitude and areal extent of the upper tropospheric westerly zonal winds on the southern flank of the block and a decrease on its northern flank The tropical and extra tropical circulation patterns begin to phase allowing a developing mid latitude trough to tap the moisture plume extending from the deep tropics 34 The heavy precipitation event As the pattern of enhanced tropical rainfall continues to shift further to the east and weaken the deep tropical moisture plume extends from the subtropical central Pacific into the mid latitude trough now located off the west coast of North America The jet stream at upper levels extends across the North Pacific with the mean jet position entering North America in the northwestern United States The deep low pressure located near the Pacific Northwest coast can bring up to several days of heavy rain and possible flooding These events are often referred to as Pineapple Express events so named because a significant amount of the deep tropical moisture traverses the Hawaiian Islands on its way towards western North America 34 Throughout this evolution retrogression of the large scale atmospheric circulation features is observed in the eastern Pacific North American sector Many of these events are characterized by the progression of the heaviest precipitation from south to north along the Pacific Northwest coast over a period of several days to more than one week However it is important to differentiate the individual synoptic scale storms which generally move west to east from the overall large scale pattern which exhibits retrogression 34 A coherent simultaneous relationship exists between the longitudinal position of maximum MJO related rainfall and the location of extreme west coast precipitation events Extreme events in the Pacific Northwest are accompanied by enhanced precipitation over the western tropical Pacific and the region of Southeast Asia called by meteorologists the Maritime Continent with suppressed precipitation over the Indian Ocean and the central Pacific As the region of interest shifts from the Pacific Northwest to California the region of enhanced tropical precipitation shifts further to the east For example extreme rainfall events in southern California are typically accompanied by enhanced precipitation near 170 E However it is important to note that the overall link between the MJO and extreme west coast precipitation events weakens as the region of interest shifts southward along the west coast of the United States 34 There is case to case variability in the amplitude and longitudinal extent of the MJO related precipitation so this should be viewed as a general relationship only 34 Explaining MJO s dynamics with equatorial modons and equatorial adjustment editEastward propagating structure of barotropic equatorial modon edit See also modon In 2019 Rostami and Zeitlin 35 reported a discovery of steady long living slowly eastward moving large scale coherent twin cyclones so called equatorial modons by means of a moist convective rotating shallow water model Crudest barotropic features of MJO such as eastward propagation along the equator slow phase speed hydro dynamical coherent structure the convergent zone of moist convection are captured by Rostami and Zeitlin s modon Having an exact solution of streamlines for internal and external regions of equatorial asymptotic modon is another feature of this structure It is shown that such eastward moving coherent dipolar structures can be produced during geostrophic adjustment of localized large scale pressure anomalies in the diabatic moist convective environment on the equator 36 Generation of MJO like structure by geostrophic adjustment in the lower troposphere edit In 2020 a study showed that the process of relaxation adjustment of localized large scale pressure anomalies in the lower equatorial troposphere 37 generates structures strongly resembling the Madden Julian Oscillation MJO events as seen in vorticity pressure and moisture fields Indeed it is demonstrated that baroclinicity and moist convection substantially change the scenario of the quasi barotropic dry adjustment which was established in the framework of one layer shallow water model and consists in the long wave sector in the emission of equatorial Rossby waves with dipolar meridional structure to the West and of equatorial Kelvin waves to the East If moist convection is strong enough a dipolar cyclonic structure which appears in the process of adjustment as a Rossby wave response to the perturbation transforms into a coherent modon like structure in the lower layer which couples with a baroclinic Kelvin wave through a zone of enhanced convection and produces at initial stages of the process a self sustained slowly eastward propagating zonally dissymmetrical quadrupolar vorticity pattern In 2022 Rostami et al 38 advanced their theory By means of a new multi layer pseudo spectral moist convective Thermal Rotating Shallow Water mcTRSW model in a full sphere they presented a possible equatorial adjustment beyond Gill s mechanism for the genesis and dynamics of the MJO According to this theory an eastward propagating MJO like structure can be generated in a self sustained and self propelled manner due to nonlinear relaxation adjustment of a large scale positive buoyancy anomaly depressed anomaly or a combination of them as soon as this anomaly reaches a critical threshold in the presence of moist convection at the equator This MJO like episode possesses a convectively coupled hybrid structure that consists of a quasi equatorial modon with an enhanced vortex pair and a convectively coupled baroclinic Kelvin wave BKW with greater phase speed than that of dipolar structure on the intraseasonal time scale Interaction of the BKW after circumnavigating all around the equator with a new large scale buoyancy anomaly may contribute to excitation of a recurrent generation of the next cycle of MJO like structure Overall the generated hybrid structure captures a few of the crudest features of the MJO including its quadrupolar structure convective activity condensation patterns vorticity field phase speed and westerly and easterly inflows in the lower and upper troposphere Although the moisture fed convection is a necessary condition for the hybrid structure to be excited and maintained in the proposed theory in this theory it is fundamentally different from the moisture mode ones Because the barotropic equatorial modon and BKW also exist in dry environments while there are no similar dry dynamical basic structures in the moisture mode theories The proposed theory can be a possible mechanism to explain the genesis and backbone structure of the MJO and to converge some theories that previously seemed divergent Impact of climate change on MJO editThe MJO travels a stretch of 12 000 20 000 km over the tropical oceans mainly over the Indo Pacific warm pool which has ocean temperatures generally warmer than 28 C This Indo Pacific warm pool has been warming rapidly altering the residence time of MJO over the tropical oceans While the total lifespan of MJO remains in the 30 60 day timescale its residence time has shortened over the Indian Ocean by 3 4 days from an average of 19 days to 15 days and increased by 5 6 days over the West Pacific from an average of 18 days to 23 days 39 This change in the residence time of MJO has altered the rainfall patterns across the globe 39 40 References edit Madden Roland A Julian Paul R 1971 07 01 Detection of a 40 50 Day Oscillation in the Zonal Wind in the Tropical Pacific Journal of the Atmospheric Sciences 28 5 702 708 Bibcode 1971JAtS 28 702M doi 10 1175 1520 0469 1971 028 lt 0702 DOADOI gt 2 0 CO 2 ISSN 0022 4928 Zhang Chidong 2005 Madden Julian Oscillation Rev Geophys 43 2 RG2003 Bibcode 2005RvGeo 43 2003Z CiteSeerX 10 1 1 546 5531 doi 10 1029 2004RG000158 S2CID 33003839 Madden Julian oscillation forecast research University of East Anglia Archived from the original on 9 March 2012 Retrieved 22 February 2012 Takmeng Wong G Louis Smith amp T Dale Bess P1 38 Radiative Energy Budget of African Monsoons NASA Ceres Observations Versus NOAA NCEP Reanalysis 2 Data PDF Retrieved 2009 11 06 Geerts B Wheeler M May 1998 The Madden Julian oscillation University of Wyoming Retrieved 2009 11 06 Roland A Madden amp Paul R Julian May 1994 Observations of the 40 50 Day Tropical Oscillation A Review Monthly Weather Review 122 5 814 837 Bibcode 1994MWRv 122 814M doi 10 1175 1520 0493 1994 122 lt 0814 OOTDTO gt 2 0 CO 2 5 day Running Mean www cpc ncep noaa gov Retrieved 29 September 2018 2015 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 2010 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 a b 1998 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 1997 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 1995 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 a b 1988 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 1982 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 1984 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 1983 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 2011 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 2003 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 1990 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 1985 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 1980 3 pentad Running Mean www cpc ncep noaa gov Retrieved 28 September 2018 Goddard Space Flight Center 2002 11 06 Ocean Temperatures Affect Intensity of the South Asian Monsoon and Rainfall NASA GSFC National Aeronautics and Space Administration Archived from the original on 2009 07 30 Retrieved 2009 11 06 Maloney E D Hartmann D L September 2001 The Madden Julian Oscillation Barotropic Dynamics and North Pacific Tropical Cyclone Formation Part I Observations Monthly Weather Review 58 17 2545 58 Bibcode 2001JAtS 58 2545M CiteSeerX 10 1 1 583 3789 doi 10 1175 1520 0469 2001 058 lt 2545 tmjobd gt 2 0 co 2 S2CID 35852730 Chris Landsea 2009 02 06 Subject A15 How do tropical cyclones form Atlantic Oceanographic and Meteorological Laboratory Retrieved 2008 06 08 Climate Prediction Center 2004 07 08 Monitoring Intraseasonal Oscillations National Oceanic and Atmospheric Administration Retrieved 2009 11 06 Maybee B Ward N Hirons L C amp Marsham J H 2023 Importance of Madden Julian oscillation phase to the interannual variability of East African rainfall Atmospheric Science Letters 24 5 e1148 https doi org 10 1002 asl 1148 MacLeod D A and Coauthors 2021 Drivers and Subseasonal Predictability of Heavy Rainfall in Equatorial East Africa and Relationship with Flood Risk J Hydrometeor 22 887 903 https doi org 10 1175 JHM D 20 0211 1 Pohl B and P Camberlin 2006 Influence of the Madden Julian Oscillation on East African rainfall Part I Intraseasonal variability and regional dependency Part II March May season extremes and interannual variability Quart J Roy Meteorol Soc 132 2521 2560 Raghavendra Ajay Zhou Liming Roundy Paul E Jiang Yan Milrad Shawn M Hua Wenjian Xia Geng 2020 The MJO s impact on rainfall trends over the Congo rainforest Climate Dynamics 54 5 6 2683 2695 Bibcode 2020ClDy 54 2683R doi 10 1007 s00382 020 05133 5 S2CID 210925845 Cook K H Liu Y amp Vizy E K Congo Basin drying associated with poleward shifts of the African thermal lows Clim Dyn 54 863 883 2020 https doi org 10 1007 s00382 019 05033 3 Jon Gottschalck amp Wayne Higgins 2008 02 16 Madden Julian Oscillation Impacts PDF Climate Prediction Center Retrieved 2009 07 17 Roundy P E Kiladis G N 2007 Analysis of a Reconstructed Oceanic Kelvin Wave Dynamic Height Dataset for the Period 1974 2005 J Climate 20 17 4341 55 Bibcode 2007JCli 20 4341R doi 10 1175 JCLI4249 1 Roundy P E Kravitz J R 2009 The Association of the Evolution of Intraseasonal Oscillations to ENSO Phase J Climate 22 2 381 395 Bibcode 2009JCli 22 381R doi 10 1175 2008JCLI2389 1 a b c d e f g Climate Prediction Center 2002 08 29 What are the impacts of intraseasonal oscillations on the U S When do they occur National Oceanic and Atmospheric Administration Archived from the original on 2009 05 01 Retrieved 2009 11 06 Rostami M Zeitlin V 2019 Eastward moving convection enhanced modons in shallow water in the equatorial tangent plane PDF Physics of Fluids 31 2 021701 Bibcode 2019PhFl 31b1701R doi 10 1063 1 5080415 S2CID 127460777 Rostami M Zeitlin V 2019 Geostrophic adjustment on the equatorial beta plane revisited PDF Physics of Fluids 31 8 081702 Bibcode 2019PhFl 31h1702R doi 10 1063 1 5110441 S2CID 202128329 Rostami M Zeitlin V 2020 Can geostrophic adjustment of baroclinic disturbances in tropical atmosphere explain MJO events PDF Quarterly Journal of the Royal Meteorological Society 146 733 3998 4013 Bibcode 2020QJRMS 146 3998R doi 10 1002 qj 3884 S2CID 221664141 Rostami M Zhao B Petri S 2022 On the genesis and dynamics of Madden Julian oscillation like structure formed by equatorial adjustment of localized heating Quarterly Journal of the Royal Meteorological Society 148 749 3788 3813 Bibcode 2022QJRMS 148 3788R doi 10 1002 qj 4388 S2CID 252958634 a b Roxy M K Dasgupta Panini McPhaden Michael J Suematsu Tamaki Zhang Chidong Kim Daehyun November 2019 Twofold expansion of the Indo Pacific warm pool warps the MJO life cycle Nature 575 7784 647 651 Bibcode 2019Natur 575 647R doi 10 1038 s41586 019 1764 4 ISSN 1476 4687 OSTI 1659516 PMID 31776488 S2CID 208329374 Warm pool expansion warps MJO Climate Research Lab CCCR IITM Retrieved 2019 11 29 External links edit nbsp Wikimedia Commons has media related to Madden Julian Oscillation Daily Madden Julian Oscillation Indices National Weather Service Climate Prediction Center Retrieved March 29 2005 MJO Homepage Agricultural Production Systems Research Unit Archived from the original on June 12 2007 Retrieved July 13 2007 The influence of intraseasonal variations of tropical convection on sea surface temperatures at the onset of the 1997 98 El Nino NOAA CIRES Climate Diagnostics Center Climate Research Spotlight Retrieved March 29 2005 Lin J Kiladis G N Mapes B E Weickmann K M Sperber K R Lin W Wheeler M C Schubert S D Del Genio A Donner L J Emori S Gueremy J Hourdin F Rasch P J Roeckner E Scinocca J F 2006 Tropical Intraseasonal Variability in 14 IPCC AR4 Climate Models Part I Convective Signals Journal of Climate 19 12 2665 90 Bibcode 2006JCli 19 2665L doi 10 1175 JCLI3735 1 hdl 11858 00 001M 0000 0011 FC85 9 Kim J Ho C Kim H Sui C Park S K 2008 Systematic Variation of Summertime Tropical Cyclone Activity in the Western North Pacific in Relation to the Madden Julian Oscillation J Climate 21 6 1171 91 Bibcode 2008JCli 21 1171K doi 10 1175 2007JCLI1493 1 Ho C H Kim J H Jeong J H Kim H S Chen D 2006 Variation of tropical cyclone activity in the South Indian Ocean El Nino Southern Oscillation and Madden Julian Oscillation effects Journal of Geophysical Research 111 D22 D22101 Bibcode 2006JGRD 11122101H doi 10 1029 2006JD007289 Retrieved from https en wikipedia org w index php title Madden Julian oscillation amp oldid 1193498736, wikipedia, wiki, book, books, library,

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