GARY PADGETT'S MONTHLY GLOBAL TROPICAL CYCLONE SUMMARY JANUARY, 2003 (For general comments about the nature of these summaries, as well as information on how to download the tabular cyclone track files, see the Author's Note at the end of this summary.) ************************************************************************* JANUARY HIGHLIGHTS --> Tropical storm strikes Madagascar --> South Pacific continues active with two intense cyclones --> Fiji experiences devastating cyclone strike --> Monsoon depression surprises Australian forecasters --> First Northwest Pacific tropical storm of year forms ************************************************************************* ***** Feature of the Month for January ***** TROPICAL CYCLONE NAMES for the NORTHWEST PACIFIC BASIN Beginning in 2000, tropical storms and typhoons forming in the North Pacific west of the Dateline have been assigned names by JMA taken from a new list of Asian names contributed by fourteen nations and territories from the western Pacific and eastern Asia. Names are not allocated in alphabetical order and the majority are not personal names. Instead, names of animals, plants, fictional characters, descriptive adjectives, places--even foods--are utilized. The entire list consists of 140 names, and all names will be used before any are repeated. The last name assigned in 2002 was Pongsona in early December while one tropical cyclone has already been named in 2003. The next storm to develop will be named Kujira--the Japanese word for 'whale'. The next 36 names on the list are (** indicates name has already been assigned in 2003): Yanyan ** Etau Melor Mindulle Kujira Vamco Nepartak Tingting Chan-hom Krovanh Lupit Kompasu Linfa Dujuan Sudal Namtheun Nangka Maemi Nida Malou Soudelor Choi-wan Omais Meranti Imbudo Koppu Conson Rananim Koni Ketsana Chanthu Malakas Morakot Parma Dianmu Megi Since 1963 PAGASA has independently named tropical cyclones forming in the Philippines' AOR--from 115E to 135E and from 5N to 25N (except for a portion of the northwestern corner of the above region). Even though the Philippines contributed ten names to the international list of typhoon names, PAGASA still continues to assign their own names for local use within the Philippines. It is felt that familiar names are more easily remembered in the rural areas and that having a PAGASA- assigned name helps to underscore the fact that the cyclone is within PAGASA's AOR and potentially a threat to the Philippines. Another consideration may be PAGASA's desire to assign a name when a system is first classified as a tropical depression. Since tropical and/or monsoon depressions can bring very heavy rainfall to the nation which often results in disastrous flooding, the weather service feels that assigning a name helps to enhance public attention given to a system. Beginning with 2001 PAGASA began using new sets of cyclone names. These do not all end in "ng" as did the older names. Four sets of 25 names will be rotated annually; thus, the set for 2003 will be re-used in 2007. In case more than 25 systems are named in one season, an auxiliary set will be used. PAGASA names for 2003 are (** indicates name has already been assigned in 2003): Amang Juaning Roskas Batibot Kabayan Sikat Chedeng Lakay Tisoy Dodong Manang Ursula Egay Nina Viring Falcon Onyok Wang-wang Gilas Pogi Yoyoy Harurot Quiel Zigzag Ineng In the unlikely event that the list is exhausted, the following names would be allocated as needed: Abe, Berto, Charing, Danggit, Estoy, Fuego, Gening, Hantik, Irog, Joker. **** Index to Feature of the Month Articles for 2002 **** Jan - TROPICAL CYCLONE NAMES for the NORTHWEST PACIFIC BASIN (also Index to Feature of the Month Articles for 2001) Feb - WESTERN HEMISPHERE TROPICAL CYCLONE NAMES for 2002 Mar - TABLES OF MONTHLY NET TROPICAL CYCLONE ACTIVITY (NTC) Apr - ACKNOWLEDGMENT AND THANKS TO MY SUPPORT TEAM (also NOT QUITE "MED-CANES") May - SOME OF MY FRIENDS' OUTSTANDING WEBSITES Jun - PATTERNS OF ATLANTIC INTENSE HURRICANE ACTIVITY Jul - TRACK FORECASTING WITH A KILO-MEMBER ENSEMBLE Aug - A CYCLONE PHASE SPACE DERIVED FROM THERMAL WIND AND THERMAL ASYMMETRY Sep - SOUTHERN HEMISPHERE TROPICAL CYCLONE NAMES 2002 - 2003 SEASON Oct - SOUTHEAST PACIFIC CYCLONE OF APRIL, 2002 Nov - ADVANCED OBJECTIVE DVORAK TECHNIQUE Dec - A CLIMATOLOGY OF INTENSE TROPICAL CYCLONES IN THE SOUTHWEST INDIAN OCEAN *********************************************************************** ACTIVITY BY BASINS ATLANTIC (ATL) - North Atlantic Ocean, Caribbean Sea, Gulf of Mexico Activity for January: No tropical cyclones ************************************************************************* NORTHEAST PACIFIC (NEP) - North Pacific Ocean East of Longitude 180 Activity for January: No tropical cyclones ************************************************************************* NORTHWEST PACIFIC (NWP) - North Pacific Ocean West of Longitude 180 Activity for January: 1 tropical storm Sources of Information ---------------------- Most of the information presented below is based upon tropical cyclone warnings and significant tropical weather outlooks issued by the Joint Typhoon Warning Center of the U. S. Air Force and Navy (JTWC), located at Pearl Harbor, Hawaii. In the companion tropical cyclone tracks file, I normally annotate track coordinates from some of the various Asian warning centers when their center positions differ from JTWC's by usually 40-50 nm or more. All references to sustained winds imply a 1-minute averaging period unless otherwise noted. Michael V. Padua of Naga City in the Philippines, owner of the Typhoon 2000 website, normally sends me cyclone tracks based upon warnings issued by the Japanese Meteorological Agency (JMA) and the Philippines' Atmospheric, Geophysical & Astronomical Services Administration (PAGASA). Also, Huang Chunliang of Fuzhou City, China, sends me each month tracks obtained from warnings issued by the National Meteorological Center of China (NMCC), the Central Weather Bureau of Taiwan (CWBT) and the Hong Kong Observatory (HKO). A very special thanks to Michael and Chunliang for the assistance they so reliably provide. In the title line for each storm I have referenced all the cyclone names/numbers I have available: JTWC's depression number, the JMA-assigned name (if any), JMA's tropical storm numeric designator, and PAGASA's name for systems forming in or passing through their area of warning responsibility. Northwest Pacific Tropical Activity for January ----------------------------------------------- As was the case with 2002, the first Northwest Pacific tropical cyclone of 2003 appeared early, around the middle of January. Tropical Storm Yanyan began intensifying in the Pohnpei/Chuuk region, following a west-northwesterly track ominously similar to that of the destructive Super Typhoon Pongsona in December. Yanyan, however, remained a tropical storm and sharply recurved around 100 nm east-northeast of Guam. The summary for Tropical Storm Yanyan was written by Kevin Boyle of Stoke-on-Trent, UK. A special thanks to Kevin for his assistance. TROPICAL STORM YANYAN (TC-01W / TS 0301) 13 - 21 January ----------------------------------------- Yanyan: contributed by Hong Kong, China, is a fairly common pet name for young girls A. Storm Origins ---------------- Even though tropical cyclones that form in January are labeled as the first of the year, climatologically speaking they are late-season storms. Since 1990, seven years have produced a cyclone during January, five of which (1990, 1992, 1997, 1999 and 2002) became named tropical storms. However, the last January typhoon was Axel (1992) which affected the Caroline Islands. The last major typhoon (>=100 kts) to occur in January was Roy (1988), which rampaged across much of the Northwest Pacific. JTWC began monitoring the pre-Yanyan disturbance at 0600 UTC on 11 January, assessing the development potential as poor. The 12/0600 UTC STWO noted that animated satellite imagery was indicating an exposed LLCC, located near 2.0N, 178.2E, associated with an area of weak convection. Upper-level analysis showed weak vertical wind shear and fair outflow aloft over the area. The MSW and MSLP were estimated at 10-15 kts and 1008 mb, respectively. Development potential was upgraded to fair at 13/0600 UTC. At the same time JMA began classifying the system as a 30-kt (10-min avg) tropical depression (near 2.4N, 173.8E). Synoptic observations from Ebon and Jaluit Atolls at 14/0600 UTC suggested there was at least a weak LLCC associated with this disturbance, but SSM/I imagery was inconclusive. Fair development potential continued through the 14th and was finally upgraded to good at 15/1630 UTC. The first warning soon followed at 15/1800 UTC on Tropical Depres- sion 01W, located near 7.2N, 160.9E, or 160 nm east of Pohnpei with the initial MSW set at 30 kts. Animated water vapor and enhanced infrared satellite imagery indicated cycling but organizing deep convection, although the LLCC was still difficult to locate in infrared satellite imagery. Movement was toward the west-northwest at 15 kts under the influence of a low to mid-level ridge to the north. By 1200 UTC, 16 January, animated multi-spectral satellite imagery showed the deep convection diminishing markedly. The LLCC was fully-exposed at this time and difficult to locate. In fact, synoptic and QuikScat data did not indicate any obvious LLCC. After a brief westward push, TD-01W returned to its original west- northwestward heading at a faster pace of 18-19 kts, reaching a position (at 17/0000 UTC) near 10.0N, 152.9E, or 170 nm north-northeast of Chuuk. (The JMA position at the same time was 11.9N, 151.0E.) During this time, deep convection was on the increase, although the LLCC remained partially-exposed. TD-01W was upgraded to a 35-kt tropical storm at 17/0000 UTC. B. Track and Intensity History ------------------------------ By 1200 UTC, 17 January, deep convective activity had waned again and there was only a single thunderstorm noted over the weak LLCC on micro- wave imagery. In addition, synoptic and QuikScat data showed maximum winds of 25 kts along the northern edge of the system. This led to the subsequent downgrading of TS-01W to a tropical depression. However, this weakening proved to be temporary. A 17/1631 UTC TRMM pass and enhanced infrared imagery showed increasing deep convection over a well-defined LLCC, and shortly afterward, at 17/1800 UTC, TD-01W was upgraded back to tropical storm status. At 18/0000 UTC, TS-01W was located approximately 130 nm east of Guam moving on a northwesterly track with a MSW of 40 kts. Six hours later, JMA upgraded the system to a minimal tropical storm and dubbed it Yanyan. At the same time, NMCC began monitoring the storm in their bulletins (10-min avg MSW of 35 kts). Tropical Storm Yanyan began its forecast northward heading and slowed to a speed of 2 kts, much to the relief of residents of the Mariana Islands who were ravaged by Super Typhoon Pongsona a month earlier. Radar and a SSM/I pass indicated an exposed system with deep convection located in the western and poleward quadrants. However, an 18/1534 UTC TRMM pass and animated satellite imagery depicted redevelopment of deep convection over the LLCC. Tropical Storm Yanyan reached its peak intensity of 50 kts at 0000 UTC on 19 January, based on 50-kt winds near the circulation centre as noted in QuikScat imagery at 18/2223 UTC. (NMCC and JMA held the peak intensity to 45 kts and 35 kts, respectively.) At this time Yanyan was located near 14.4N, 148.1E, or approximately 140 nm east-southeast of Saipan. (JMA's 19/0000 UTC position was 15.2N, 147.7E.) Yanyan had recurved sharply onto an east-northeasterly track by late on the 18th, being influenced by a low to mid-level ridge to the east. This heading was expected to continue for the rest of Yanyan's career, although the storm was moving northeastward at around 12 kts late on the 19th and early 20th. Weakening had already begun with an exposed LLCC (southwest of the sheared-off deep convection) at 20/0000 UTC and the MSW dropping below 35 kts at 20/1200 UTC. (Note: NMCC issued the last bulletin on Yanyan at 20/0600 UTC). However, despite deep convection redeveloping for a time, the system remained in a poorly-organised state until the final advisory was issued by JTWC at 21/0000 UTC. This warning located the centre near 18.3N, 156.5E, or 600 nm west of Wake Island. The decoupled small LLCC drifted toward the east-northeast at a slower speed of 6 kts, controlled by the lower-level surface flow. JMA continued issuing advisories until 21/1800 UTC with the final position relocated to 19.0N, 158.0E. C. Damage and Casualties ------------------------ There have been no reports of damage or casualties associated with Tropical Storm Yanyan. (Report written by Kevin Boyle) ************************************************************************* NORTH INDIAN OCEAN (NIO) - Bay of Bengal and Arabian Sea Activity for January: No tropical cyclones ************************************************************************* SOUTHWEST INDIAN OCEAN (SWI) - South Indian Ocean West of Longitude 90E Activity for January: 1 tropical disturbance 2 severe tropical storms Sources of Information ---------------------- The primary sources of tracking and intensity information for Southwest Indian Ocean tropical cyclones are the warnings issued by the Tropical Cyclone Warning Centre on La Reunion Island, part of Meteo France (MFR), and the Regional Specialised Meteorological Centre for the basin. However, tropical cyclones in this region are named by the sub-regional warning centres on Mauritius and Madagascar with longitude 55E being the demarcation line between their respective areas of warning responsibility. The La Reunion centre only advises these agencies regarding the intensity of tropical systems. References to sustained winds imply a 10-minute averaging period unless otherwise stated. In the companion tropical cyclone tracks file, I occasionally annotate positions from warnings issued by the Joint Typhoon Warning Center (JTWC) of the U. S. Air Force and Navy, located at Pearl Harbor, Hawaii, when they differ from MFR's coordinates by usually 40-50 nm or more. The JTWC warnings are also the source of the 1-minute average maximum sustained wind values included in the tracks file. Additionally, information describing details of satellite imagery and atmospheric circulation features included in the narratives is often gleaned from the JTWC warnings. Southwest Indian Ocean Tropical Activity for January ---------------------------------------------------- As was the case with December, two tropical systems were named in the Southwest Indian Ocean. However, neither reached cyclone (hurricane) intensity. Severe Tropical Storm Ebula formed early in the month well south of Diego Garcia and followed an almost straight south trajectory which took the system into higher latitudes. Late in the month a weak but tenacious disturbance moved west-southwestward from the Central Indian Ocean and intensified quickly into Severe Tropical Storm Fari as it approached southeastern Madagascar. MFR issued warnings on an additional tropical disturbance concurrently with Tropical Storm Ebula. This system, designated as Tropical Disturb- ance 07, developed in the Mozambique Channel, most likely from the remnants of Tropical Storm Delfina which had moved eastward from the African mainland back out over the Channel. The center was located about 300 nm west-southwest of Majunga, Madagascar, at 06/0000 UTC. During the following days the disturbance drifted generally southward, being located about 300 nm west of Tulear, Madagascar, at 08/1200 UTC. Winds near the center of the system were likely never higher than 25 kts, but stronger winds were forecast for the eastern and southern periphery of the LOW. MFR dropped warnings after 10/0600 UTC, but resumed them 12 hours later when storm-force winds to 50 kts were reported well south of the center. The system by then was extratropical and continued to drift southward for another couple of days as it slowly weakened. JTWC assigned a fair development potential to the LOW on the 6th and 7th, but no warnings were issued. TROPICAL STORM EBULA (MFR-08 / TC-09S) 7 - 13 January ---------------------------------------- Ebula: submitted by Swaziland A. Storm Origins ---------------- An area of convection developed and persisted on 6 January roughly 175 nm south-southwest of Diego Garcia. Animated infrared and multi- spectral imagery indicated a developing LLCC. The system was moving west-southwestward out of the equatorial trough, and an upper-level analysis indicated favorable diffluence aloft with weak to moderate vertical shear. The potential for development was assessed as fair. MFR issued their first bulletin on Tropical Disturbance 08 at 1200 UTC on the 7th with maximum winds estimated at 20 kts near the center and up to 25 kts in the southern semicircle well away from the LLCC. JTWC upgraded the development potential to good at 1800 UTC--cycling deep convection had increased and was beginning to wrap into the LLCC in the southwestern quadrant. The disturbance at this time was located approximately 250 nm south-southwest of Diego Garcia. JTWC issued their first warning at 0000 UTC on 8 January, estimating the MSW (1-min avg) at 35 kts. By 1200 UTC the center of TC-09S was located about 335 nm south of Diego Garcia, moving south at 15 kts. MFR upgraded the system to tropical depression status with 30-kt winds at 1800 UTC. JTWC upped their 1-min avg MSW estimate to 50 kts at 09/0000 UTC, based on CI estimates of 45 and 50 kts. Deep convection had continued to increase and wrap into the LLCC, and satellite imagery revealed a well-developed poleward outflow channel. At 09/0600 UTC the Mauritius Meteorological Service named the system Tropical Storm Ebula, then located about 550 nm south-southwest of Diego Garcia. MFR concurrently upped the MSW (10-min avg) to 45 kts. B. Track and Intensity History ------------------------------- Throughout its entire history Tropical Storm Ebula followed a very meridional trajectory, never deviating more than one degree of longi- tude from 70E except as it was becoming extratropical late in its life. By 0000 UTC on 10 January Ebula was centered about 600 nm south of Diego Garcia. JTWC upped the intensity to 65 kts--minimal hurricane intensity --but MFR's peak MSW for Ebula was 60 kts. The storm reached its peak intensity (per MFR) at 10/0600 UTC when located approximately 725 nm south of Diego Garcia. The severe tropical storm maintained a MSW of 60 kts for 18 hours before beginning to slowly weaken. The minimum central pressure estimated by MFR was 975 mb. By 1200 UTC on the 10th, CI estimates had reached 65 and 77 kts, but the system was beginning to experience northwesterly shearing. Ebula was forecast to turn south- eastward after 24 hours as the mid-level ridge to its south propagated eastward. By 0000 UTC on 11 January Tropical Storm Ebula was almost 1000 nm south of Diego Garcia and moving south-southeastward at 15 kts. MFR and JTWC lowered their respective intensity estimates to 55 and 60 kts. Animated water vapor imagery indicated dry air entraining into the system from the west with shearing apparent in the northern semicircle. By 1200 UTC the intensity was down to 50 kts from both warning centers with the deep convection sheared to the south of the LLCC. JTWC issued their final warning at 12/0000 UTC with the MSW (1-min avg) placed at 40 kts, based on a CI estimate of 45 kts and a recent QuikScat pass. The LLCC was partially-exposed with all the deep convection in the southern semi- circle. JTWC forecast Ebula to complete extratropical transition within 12 hours, and MFR declared the system extratropical at 1200 UTC. Winds had weakened to below gale force by the time the final MFR bulletin was issued at 1200 UTC on the 13th. C. Damage and Casualties ------------------------ No damage or casualties are known to have resulted from Severe Tropical Storm Ebula. (Report written by Gary Padgett) TROPICAL STORM FARI (MFR-09 / TC-11S) 23 January - 1 February ------------------------------------------- Fari: contributed by Zimbabwe A. Storm Origins ---------------- An area of convection developed on 20 January, and by 1800 UTC on the 21st was located roughly 600 nm east-southeast of Diego Garcia. Animated multi-spectral satellite imagery and a recent SSM/I pass revealed a partially-exposed LLCC with associated weak deep convection to the south- east of the center. An upper-level analysis indicated good outflow poleward of the system with weak vertical shear over the center, increasing to moderate in the southeastern quadrant. At 0500 UTC on the 22nd the development potential was upgraded to fair based on persistence and improved organization. By 1800 UTC the disturbance was located about 525 nm east-southeast of Diego Garcia. A 22/0639 UTC TRMM pass had depicted a well-defined LLCC north of the deepest convection. MFR initiated bulletins on the system at 0600 UTC on 23 January, numbering it as Tropical Disturbance 09. At 1200 UTC JTWC issued a TCFA for the LOW which was moving west-southwestward at 11 kts. Deep convection had continued to increase as the LLCC's organization gradually improved. A 200-mb analysis showed that the system was near the upper- level ridge axis with weak vertical shear and improving poleward outflow. Two things happened at 1800 UTC: MFR upgraded the disturbance to a 30-kt tropical depression, and JTWC issued their first warning, estimating the MSW (1-min avg) at 35 kts based on CI estimates of 30 and 35 kts and a 35-kt ship report. The center of TC-11S was located some 460 nm south-southeast of Diego Garcia, moving west-southwestward at 11 kts. The fortunes of the fledgling tropical system, however, reversed quite rapidly. At 0600 UTC on the 24th, MFR downgraded the system back to tropical disturbance status with 25-kt winds, and JTWC dropped their 1-min avg MSW to 20 kts and wrote the final warning. Animated satellite imagery and a recent SSM/I pass indicated that the mid-level circulation and associated deep convection had become decoupled from the LLCC and moved approximately 5 degrees to the west. The remnant LOW was then located about 500 nm south of Diego Garcia, and MFR continued to issue bulletins on the weak system as it tracked west-southwestward across the Southwest Indian Ocean. At 25/1800 UTC the LOW was located approximately 765 nm southeast of the Seychelles. Animated multi-spectral imagery indicated that the disturbance consisted of an elongated trough with two LLCCs about 3 degrees apart. A 200-mb analysis indicated favorable diffluence aloft as the system approached a col in the upper-levels. JTWC assessed the potential for redevelopment as fair. MFR maintained the MSW near the center at only 20 kts for a couple of days, but bumped this up to 25 kts at 0600 UTC on 27 January and to 30 kts (tropical depression status) at 1800 UTC. A STWO issued by JTWC at 27/2100 UTC located the disturbance about 225 nm east of the Madagascar coastline and noted that animated imagery indicated deep convection continuing to cycle in intensity. A CDO had formed, and recent SSM/I data depicted the LLCC partially-exposed to the southeast of the deep convection. Further development was anticipated as a 200-mb analysis indicated the depression was situated in a region of weak vertical shear near the ridge axis with favorable upper-level diffluence. B. Track and Intensity History ------------------------------ JTWC resumed issuing warnings on TC-11S at 0000 UTC on 28 January with an initial intensity of 35 kts. The center was located approximately 270 nm east of Antananarivo, Madagascar, moving west-southwestward at 13 kts. Deep convection had consolidated over the LLCC during the previous 12 hours, and the system was forecast to continue tracking southwestward toward a weakness in the low and mid-level ridge. At 1200 UTC the Meteorological Services of Madagascar upgraded the system to tropical storm status and assigned the name Fari. Tropical Storm Fari was then located about 185 nm east of Antananarivo. JTWC had upped the MSW (1-min avg) to 40 kts, although animated satellite imagery indicated some weakening in the convection as the system approached land. MFR increased the intensity to 40 kts at 1800 UTC, and to the peak of 50 kts at 29/0000 UTC with Fari's center on the coast about 30 nm south of Mahanoro, moving westward and inland at 10 kts. (JTWC's peak 1-min avg MSW at 29/0000 UTC was 55 kts--in good agreement with MFR.) The minimum central pressure estimated by MFR was 984 mb. MFR lowered the intensity to 25 kts at 0600 UTC, although the warning noted that stronger winds to 30 kts were occurring over water east of the center. By 1200 UTC Fari's center was located over land approximately 310 km south- southwest of Antananarivo, moving southwestward at 17 kts. With this fairly quick forward motion, the center of Fari had reached the south- west coast of Madagascar by 30/0000 UTC and was moving out into the Mozambique Channel. Some slight re-intensification was forecast, but this never materialized. JTWC issued their final warning at 0000 UTC on 31 January with the 25-kt LOW located about 100 nm west of the southwestern coast of Madagascar. The system was moving southward at 11 kts and this general motion continued. MFR declared the remnants of Fari extra- tropical at 31/1800 UTC when the system was located about 350 nm south- southeast of Tulear, Madagascar. The extratropical depression continued moving southward with the final MFR bulletin placing it almost 700 nm south of Madagascar at 1200 UTC on 1 February. C. Damage and Casualties ------------------------ A wetter-than-normal summer season had contributed to significant flooding over many sections of Madagascar, including in and around the capital of Antananarivo. Tropical Storm Fari only served to aggravate the situation. The community of Marolambo was isolated due to land- slides on the main national road, while the communes of Masomeloka, Nosy Varika and Mananjary suffered serious damage to their infra- structures (from 12 to 35%). Fari left over 3400 persons homeless with major outbreaks of conjunctivitis and diarrhea reported. The storm flooded 70% of the rice fields in the area where it made land- fall and damaged 99% of banana and other fruit trees. More information can be found at the following website: (Report written by Gary Padgett) ************************************************************************* NORTHWEST AUSTRALIA/SOUTHEAST INDIAN OCEAN (AUW) - From 90E to 135E Activity for January: 1 tropical LOW ** ** - system formed east of 135E and moved westward into Perth's AOR Sources of Information ---------------------- The primary sources of tracking and intensity information for Northwest Australia/Southeast Indian Ocean tropical cyclones are the warnings and advices issued by the Tropical Cyclone Warning Centres at Perth, Western Australia, and Darwin, Northern Territory. References to sustained winds imply a 10-minute averaging period unless otherwise stated. In the companion tropical cyclone tracks file, I occasionally annotate positions from warnings issued by the Joint Typhoon Warning Center (JTWC) of the U. S. Air Force and Navy, located at Pearl Harbor, Hawaii, when they differ from the Australian centres' coor- dinates by usually 40-50 nm or more. The JTWC warnings are also the source of the 1-minute average maximum sustained wind values included in the tracks file. Additionally, information describing details of satellite imagery and atmospheric circulation features included in the narratives is often gleaned from the JTWC warnings. Northwest Australia/Southeast Indian Ocean Tropical Activity for January ------------------------------------------ The only tropical system for which warnings were issued between longitudes 135E and 90E during January was a tropical LOW in the Timor Sea on the 23rd and 24th. This system was a reincarnation of a long- lived, interesting system which had formed in the Arafura Sea very early in the month. The system was not classified operationally as a tropical cyclone, but a post-event analysis concluded that early in its history the LOW had reached tropical cyclone intensity as it moved inland into the Northern Territory across Elcho Island. For the most part the system exhibited monsoon depression characteristics and spent the middle two weeks of January meandering around the Northern Territory. A post-event study by the Perth TCWC has concluded that the LOW became a tropical cyclone for a second time as it made landfall in Western Australia between Port Hedland and Pardoo on the 24th. A report on this system is included in the next section of this summary covering the Northeast Australia/Coral Sea region. ************************************************************************* NORTHEAST AUSTRALIA/CORAL SEA (AUE) - From 135E to 160E Activity for January: 1 tropical LOW (monsoon depression) ** ** - system was ajudged in post-analysis to have reached tropical cyclone intensity at one point Sources of Information ---------------------- The primary sources of tracking and intensity information for Northeast Australia/Coral Sea tropical cyclones are the warnings and advices issued by the Tropical Cyclone Warning Centres at Brisbane, Queensland, and Darwin, Northern Territory, and on very infrequent occasions, by the centre at Port Moresby, Papua New Guinea. References to sustained winds imply a 10-minute averaging period unless otherwise stated. In the companion tropical cyclone tracks file, I occasionally annotate positions from warnings issued by the Joint Typhoon Warning Center (JTWC) of the U. S. Air Force and Navy, located at Pearl Harbor, Hawaii, when they differ from the Australian centres' coor- dinates by usually 40-50 nm or more. The JTWC warnings are also the source of the 1-minute average maximum sustained wind values included in the tracks file. Additionally, information describing details of satellite imagery and atmospheric circulation features included in the narratives is often gleaned from the JTWC warnings. Northeast Australia/Coral Sea Tropical Activity for January ----------------------------- No tropical cyclones were declared operationally east of longitude 135E during January. The main highlight of the month was a very long- lived monsoon depression which formed in the Arafura Sea very early in the month and lasted for almost three weeks. A damage survey and examination of AWS data from Elcho Island indicated that the system had developed into a small tropical cyclone of storm intensity on the 4th and 5th as it moved across the island. The system later parked itself over or near the western Gulf of Carpentaria for several days where it spawned very heavy rainfall which led to major flooding in some areas. After spending several days moving slowly westward across Arnhem Land, the LOW eventually emerged into the Timor Sea and underwent some strengthening once more, reaching tropical cyclone intensity a second time as it came ashore in Western Australia. A report on this system follows. Long-lived Monsoon Depression and Elcho Island Tropical Cyclone ----------------------------- A. System History ----------------- A long-lived monsoon LOW formed in the Arafura Sea on 4 January. The system moved southward and inland along the Top End of the Northern Territory on the 5th. Some non-tropical cyclone-style gale warnings were issued by Darwin, but the system was not considered a tropical cyclone by Darwin nor by JTWC. The LOW hung around for several days and by 10 January was near the coastline in the southwestern Gulf of Carpentaria region. Darwin issued tropical cyclone advices on the 11th and 12th in the anticipation that the LOW might develop into a tropical cyclone in the Gulf. By around 1300 UTC on the 11th the center was out over the Gulf south-southeast of Groote Eylandt, but further development did not take place and the LOW subsequently began moving westward. By early on the 14th the system was well inland over the Northern Territory. The weak system spent roughly the next week moving very slowly westward across northern Australia, being more of a diffuse trough of low pressure than a closed LOW. By the 21st a tropical LOW had formed in the Timor Sea north of the Western Australian coast. Perth began issuing gale warnings for this LOW on 23 January in the anticipation that it would develop into a tropical cyclone. The LOW drifted westward, thence recurving southwestward and southward, finally moving inland just west of Pardoo around 1900 UTC on the 24th. There was initially some uncertainty if the Timor Sea tropical LOW was a redevelopment of the earlier Arafura Sea/Gulf of Carpentaria system. Mark Kersemakers of the Darwin TCWC indicated that they were separate system, and therefore I treated them as separate systems in the January tracks file. However, Mark later informed me that after reviewing the data later, the consensus of opinion was that the two were one and the same system. Although the surface circulation had been very difficult to keep tabs on, it appeared that the mid-level circulation was the same. B. Tropical Cyclone #1 ---------------------- During the time the system was initially developing north of the Top End coastline, forecasters at the Darwin TCWC analyzed it as a very broad circulation with bands of gales at wide radii from the center (out to 180 nm to the north and east). The LOW was expected to move over land early on 5 January, but remained over water longer than expected, coming inland near Elcho Island around 0900 UTC (1830 local time--Australian Central Standard Time). Gales began on Elcho Island at 1850 CST and lasted until 2000 CST. A secondary maximum with near gale-force winds of 32 kts occurred at 2230 CST. At 1920 CST sustained winds reached 50 kts with peak gusts of 62 kts, accompanied by a MSLP of 991.7 mb. The minimum MSLP reading of 989.8 mb occurred at 2010 CST. A damage survey was conducted on Elcho Island several days later. Extensive tree damage was noted, mainly from southerly or westerly winds. There was also some damage to buildings and vehicles, largely due to falling trees. An extensive post-event analysis has concluded that the system reached tropical cyclone strength around 04/2100 UTC, and with the benefit of hindsight, a Dvorak CI of around 3.0 to 3.5 can be assigned at the time of landfall. Images from the Gove radar showed a C-shaped structure with a radius of around 10 nm which persisted for many hours, and can be associated with the band of maximum winds. It is estimated that the radius of gales in the core region was around 15 nm. Fortunately, there were no injuries. The main human impact on Elcho Island was panic and confusion with people running or driving around in dangerous conditions. The inhabitants of the island were not expecting a tropical cyclone since no warnings had been issued, and apparently the people there had not heard nor understood the gale warnings that were in force for Arnhem Land. The asymmetry of the winds around the system are particularly inter- esting. Winds were much stronger in southerly (offshore) flow on the west side of the center--the same side as the C-shaped structure on radar--than in the northerly flow east of the center. On the eastern side the wind field consisted of a more broad area of gales which persisted for another twelve hours while the system rapidly moved off to the west-southwest--a feature more consistent with the monsoon LOW structure analyzed in real time. It's possible that the system was a hybrid, with a small tropical cyclone developing within a broader, annular system. C. Best Track ------------- Following is the post-event analysis best track for the Elcho Island portion of the system's history. This was sent to me by Peter Otto--a special thanks to Peter for forwarding it to me. I will include this track in the March tropical cyclone tracks file as an addendum. Date Time Lat Lon Cent MSW MSW Remarks (GMT) Press 1-min 10-min (mb) (kts) (kts) ------------------------------------------------------------------------- 03 JAN 04 0000 10.0 S 135.5 E 1004 15 03 JAN 04 0300 10.2 S 136.0 E 1002 15 03 JAN 04 0600 10.4 S 136.3 E 1000 20 03 JAN 04 0900 10.7 S 136.4 E 999 20 03 JAN 04 1200 11.2 S 136.3 E 998 25 03 JAN 04 1500 11.3 S 135.9 E 996 30 03 JAN 04 1800 11.4 S 135.7 E 994 30 03 JAN 04 2100 11.4 S 135.6 E 992 35 03 JAN 05 0000 11.4 S 135.4 E 991 35 03 JAN 05 0300 11.5 S 135.5 E 990 40 03 JAN 05 0600 11.6 S 135.8 E 989 45 03 JAN 05 0900 11.9 S 135.8 E 988 50 03 JAN 05 1200 12.1 S 135.5 E 988 50 03 JAN 05 1500 12.3 S 135.0 E 990 40 03 JAN 05 1800 12.4 S 134.9 E 993 35 03 JAN 06 0000 12.6 S 134.7 E 997 30 D. Meteorological Observations ------------------------------ The folks at the Darwin TCWC prepared a summary of observations in and around the Gulf of Carpentaria during the time the monsoon LOW was affecting that region. I'm not sure just who sent it to me (I saved only the attachment and not the e-mail message), but I'd like to thank whomever it was. The maximum wind gust recorded was 52 kts at Sweers Island (17.1S, 139.6E) on 16 January. Centre Island (15.7S, 136.8E) recorded a peak gust of 47 kts on the 14th while the Mornington Island AWS (16.7S, 139.2E) recorded a peak gust of 37 kts at 0900 UTC on the 16th. (This last observation is thought to be closer to a 10-minute average value due to the AWS being surrounded by large trees and close to a building.) Some of the more significant 24-hour rainfall totals include: Location Period Ending Amount (mm) ----------------------------------------------------------------------- Sweers Island 10 Jan/2300 UTC 138 " 11 Jan/2300 UTC 162 Mornington Island 10 Jan/2300 UTC 172 " 11 Jan/2300 UTC 298 " 16 Jan/2300 UTC 210 Centre Island 14 Jan/2300 UTC 159 Boroloola 07 Jan/2300 UTC 164 " 08 Jan/2300 UTC 102 " 09 Jan/2300 UTC 179 " 13 Jan/2300 UTC 103 Groote Eylandt 05 Jan/2300 UTC 140 Gove 14 Jan/2300 UTC 100 Several localities had 24-hour rainfall totals in the 80-100 mm range. Moderate to major flooding occurred in the Nicholson River catchment. Rainfall accumulations in or near the catchment over the period 07 Jan/2300 UTC to 22 Jan/2300 UTC include: Redbank Mine 1103 mm Woologorang 880 mm Westmorland 889 mm E. Possible Tropical Cyclone #2 ------------------------------- As mentioned earlier, the remnants of the monsoon LOW/tropical cyclone eventually emerged into the Timor Sea off Western Australia and developed into a tropical depression. The system was forecast to intensify into a tropical cyclone and precautionary gale warnings were issued by the Perth TCWC, but the system did not strengthen. Or so was thought. According to an e-mail from Barry Hanstrum of the Perth TCWC, off the Western Australian coast the LOW's structure was monsoonal and multi- centered as it had been in the Arafura Sea. However, during the period around landfall just to the east of Port Hedland, a region of strong gales was observed in the offshore flow immediately to the west of and north of the LOW--very similar to the situation at Elcho Island. The Perth office will be performing a careful analysis of the system and there is a possibility it may be later upgraded to tropical cyclone status a second time. UPDATE: I have learned from Mark Kersemakers that a post-analysis study of this system has determined that it did reach tropical cyclone intensity shortly before moving ashore in Western Australia. If and when I receive a tabular "best track" for this portion of the system, I will include it in a future summary. (Report written by Gary Padgett) ************************************************************************* SOUTH PACIFIC (SPA) - South Pacific Ocean East of Longitude 160E Activity for January: 1 tropical cyclone of gale intensity 2 tropical cyclones of hurricane intensity Sources of Information ---------------------- The primary sources of tracking and intensity information for South Pacific tropical cyclones are the warnings and advisories issued by the Tropical Cyclone Warning Centres at Nadi, Fiji (for waters north of latitude 25S), and Wellington, New Zealand (for waters south of latitude 25S). References to sustained winds imply a 10-minute averaging period unless otherwise stated. In the companion tropical cyclone tracks file, I occasionally annotate positions from warnings issued by the Joint Typhoon Warning Center (JTWC) of the U. S. Air Force and Navy, located at Pearl Harbor, Hawaii, when they differ from the Southern Hemisphere centres' coordinates by usually 40-50 nm or more. The JTWC warnings are also the source of the 1-minute average maximum sustained wind values included in the tracks file. Additionally, information describing details of satellite imagery and atmospheric circulation features included in the narratives is often gleaned from the JTWC warnings. South Pacific Tropical Activity for January ------------------------------------------- Three tropical cyclones formed in the South Pacific Ocean east of 160E during January. One of these systems, Cilla, was of minimal tropical cyclone intensity and of little consequence. The other two, however, became quite intense and one was very destructive to Fiji. Tropical Cyclone Ami cut a destructive swath across the Northern and Eastern Divisions of Fiji, resulting in total losses possibly exceeding $100 million in Fijian dollars and claiming 14 lives. Later, Tropical Cyclone Beni became even more intense and caused some damage in the Solomons and Vanuatu as it passed near those island groups, but fortunately no loss of life is known to have resulted. Beni weakened to a tropical depression southwest of New Caledonia, but the remnant LOW moved westward and briefly regained tropical cyclone status off the Queensland coast in early February. The reports on Tropical Cyclones Ami and Beni were written by Simon Clarke of Cleveland, Queensland, and these were based in part on storm reports received from Alipate Waqaicelua, Chief Forecaster at the Nadi TCWC. A special thanks to Simon and Alipate for their assistance. TROPICAL CYCLONE AMI (TD-05F / TC-10P) 9 - 15 January ---------------------------------------- A. Storm Origins ---------------- Ami was the third tropical cyclone to form in the RSMC Nadi's area of responsibility during the 2002-2003 South Pacific Tropical Cyclone Season. A tropical depression (TD-05F) was first identified as an embedded system in an active monsoon trough to the east of Tuvalu, or about 240 nautical miles east of Funafuti at around 09/2100 UTC. The system steadily moved southwestward to lie close to Niulakita early on the 12th, with development greatly affected by diurnal variations and relatively strong vertical wind shear. Overnight on 11 January, the central convection increased and became much better organised over the LLCC. Under favourable diffluent air conditions aloft and with low to moderate vertical wind shear, TD-05F underwent steady development and subsequently was named Tropical Cyclone Ami around 0000 UTC on 12 January. Ami was located just east of Niulakita at the time and moving steadily southwestward with maximum 10-minute mean winds estimated at 40 knots. B. Track and Intensity History ------------------------------ Initially, Ami moved toward the southwest at approximately 6 knots and intensified rapidly with banding wrapping into the southern semi- circle of the low-level circulation. Ami slowly turned toward the south and reached storm intensity (50 knots) around 12/1200 UTC. Around 13/0600 UTC, Ami attained hurricane intensity whilst accelerating toward the south at 12 knots. Ami exhibited good outflow in all quadrants as a deepening upper-level trough southwest of the cyclone increased the outflow above the system. A ragged eye had become visible in satellite imagery, and the storm's centre was then located (by radar) about 140 nautical miles north-northeast of Labasa or about 130 nautical miles north-northwest of Udu Point. The centre of the cyclone made landfall near Dogotuki, Vanua Levu, slightly after 13/1500 UTC. At this time, Ami had a MSW of 75 knots (or 90 knots MSW 1-minute average per JTWC) close to the centre and a central pressure estimated at 960 hPa. The centre of the cyclone passed over the western tip of Taveuni after 13/1700 UTC before accelerating through the Lau Group, curving southeastward as it did so. At 14/0600 UTC Ami reached its peak intensity of 80 knots (or 110 knots 1-minute average per JTWC) with an estimated central pressure of 950 hPa. The centre was located about 60 nautical miles south-southwest of Lakeba, or about 100 nautical miles north-northwest of Ono-i-Lau. (Editor's Note: JTWC based its estimated peak 1-minute average MSW of 110 kts on CI estimates of 102 and 115 kts, or T5.5 and T6.0. Fiji's analysis yielded a final T-number of 5.5, but the CI was held to 5.0--90 kts 1-minute or 80 kts 10-minute average. So whether or not Ami became an intense tropical cyclone (100 kts 1-minute/ 90 kts 10-minute) isn't quite such a clear-cut issue as with the other intense South Pacific cyclones this season.) Ami maintained its southeasterly track and accelerated further to between 30 and 35 knots as it moved out of RSMC Nadi's area of warning responsibility. By this time Ami was tracking poleward of the upper- level ridge axis and encountering increasing vertical wind sheer and cooler sea surface temperatures. Ami began to interact with a frontal boundary to its immediate southwest and underwent complete extratropical transition by 15/1200 UTC whilst inside the RSMC Wellington's area of responsibility. The remains of Ami were last seen tracking toward the east about 600 nautical miles south-southeast of Rarotonga. C. Damage and Casualties ------------------------ Ami was a relatively intense tropical cyclone with maximum (10- minute average) winds of about 80 knots and momentary gusts of 110 knots at its peak intensity. The cyclone caused destructive to very destructive storm and hurricane-force winds over Fiji's Northern and Central Divisions, and damaging gale-force winds over Tonga and Tuvalu. Damage was extensive and severe, especially to roads, infrastructure, buildings, houses, crops (particularly hard-hit being the sugar industry) and vegetation over Macuata, Cakaudrove and Lau Provinces in Fiji's Northern and Eastern Divisions. Fiji's Disaster Management Centre declared the northern island of Vanua Levu a natural disaster zone. Communication to and within the Northern and Eastern Divisions was severed for several days after the passage of Ami. Severe flooding in Labasa from its river took a heavy toll on the township's residents and caused serious health and environmental risks. Water supplies in the Northern Division were severely disrupted, leaving residents without clean drinking water for several days and forcing the Government to cart fresh water from mainland Viti Levu to the affected areas. Torrential rains also caused landslides. High waves and a heavy surge generated by Ami caused coastal and inland inundation in many areas along its path, some quite severe. The following figures from the Government of Fiji show the extent of the damage: Housing: -> In Lau and Lomaiviti, but mostly in Lau - 237 houses were partially damaged and 158 completely destroyed; the total estimated cost was $2.2 million. -> In Macuata, Cakaudrove and Bua, and mostly in Macuata and Cakaudrove - 5300 houses were partially damaged and 2287 completely destroyed; total estimated cost was $11.6 million. Health Facilities: -> The Visoqo Nursing Station was completely destroyed, with structural damage sustained to the Labasa and Savusavu hospitals and various health centres and nursing stations. Infrastructure: -> Damage to roads, bridges and jetties estimated at $2.7 million -> Damage to water and sewerage systems of $79,300 -> Damage to rural water supply systems of $1 million -> Damage to Government buildings of $101,000 -> Damage to electricity infrastructure of $3.4 million Agriculture: -> Damage assessment by the Ministry estimates the cost of rehabilitation at $1 million for the non-sugar sector. -> For the cane and sugar sector, the 2003 cane is estimated to suffer a reduction of 15% on the 2003 forecast of 800,000 tonnes. This means an estimated loss of $8 million with $6 million required for the heavy damage sustained to the Labasa Mill. -> Widespread damage sustained to coconut plantations with an estimated three to five year period required for the trees to be productive again. The extent of damage requiring immediate Government attention has been valued at $F60 million. However, the socio-economic loss is likely to exceed $F100 million. Fiji's National Emergency Operational Centre confirmed the total number of fatalities to be fourteen. Preliminary information provided by the Tonga Meteorological Service reveals that damage suffered in Tonga was mainly to fruit bearing trees. The inter-island ferry MV Olovaha was left stranded on a reef in Tongatapu. Nuku'alofa reported a maximum sustained wind of 40 knots with gusts to 60 knots. Some pictures of Tropical Cyclone Ami's brush with Tonga may be found on Geoff Mackley's website: Additional articles on the effects of Tropical Cyclone Ami in Fiji can be found at the following URL: (Report written by Simon Clarke with contributions by Alipate Waqaicelua, Chief Forecaster at the Nadi TCWC) TROPICAL CYCLONE BENI (TD-06F / TC-12P) 19 January - 5 February 2003 ------------------------------------------------ A. Storm Origins ---------------- Beni was the fourth tropical cyclone of the 2002-2003 South Pacific Tropical Cyclone Season, and the first of the season to cross over into the Queensland Tropical Cyclone Warning Centre's area of warning responsibility. Beni was first identified at 19/1800 UTC as a broad circulation embedded in the monsoon trough to the northeast of the Santa Cruz Islands and moving towards the west-southwest at about 5 knots. At the time, the disturbance was located in a favourable outflow environment with minimal shear and a SST of approximately 30 C. The system was upgraded to Tropical Depression 06F after 24 hours while steadily travelling towards the west, being located at 20/2100 UTC about 200 nm northeast of Rennell Island in the Solomons. However, from 22 January through 23 January, further development was suppressed by strengthening vertical wind shear which exposed the LLCC to the east of the deepest convection. After 23/2100 UTC, TD-06F returned to a favourable environment for development consisting of high SSTs, decreasing vertical wind shear, and a position beneath an upper-level ridge axis with fair and improving outflow in all quadrants. Accordingly, convection erupted over the LLCC during the night whilst cooling significantly. The first international marine warning on TD-06F was then issued at 24/2155 UTC, mentioning winds reaching gale force within 60 nautical miles of the centre in the next 12 to 24 hours. TD-06F was subsequently upgraded and named Tropical Cyclone Beni at 25/0000 UTC. B. Track and Intensity History ------------------------------ At the time of naming, the slow-moving Beni was located about 90 nautical miles southeast of Rennell Island in the Solomon Island chain. For the ensuing 24 to 48 hours, Beni underwent a slow clockwise loop while remaining to the southeast of Rennell Island. This motion was partly a consequence of a strong surface ridge to the south of the LLCC. Again, under fluctuating environmental conditions primarily as a consequence of its position north of the strongly diffluent flow on the northern side of the upper-level ridge axis, Beni exhibited a partially-exposed LLCC and broken feeder bands with the best areal coverage of convection on its western flank. By 26/0600 UTC, Beni began to adopt a more definite but slow path towards the south-southwest and was set to embark into a region of increasingly favourable conditions for development. Steady intensification was the result. By 28/0600 UTC Beni was beginning to recurve towards the southeast under the increasing influence of a low to mid-level equatorial ridge to the east-northeast of the system and as the ridge anchored to the southwest weakened due to a passing mid-latitude trough. At this time Beni attained hurricane intensity (> 63 knots), and by 28/1800 UTC, the cyclone was estimated to have 10-minute average winds of 90 knots close to the centre. A ragged eye appeared on infrared satellite imagery and became increasingly well-defined while shrinking in size. Beni slowly accelerated towards the southeast while intensifying. Beni reached its peak intensity around 29/0600 UTC with the MSW estimated at 110 knots (or approximately 125 knots 1-minute average) close to the centre. At its peak Beni possessed an estimated central pressure of 920 hPa and was located at 17.0S, 163.7E, or approximately 120 nautical miles to the north of the northwestern tip of New Caledonia. This position was also roughly 275 nautical miles west of Port Vila, Vanuatu. Gales extended outward from the centre 120 nm in all quadrants, and the radius of 50-kt winds was estimated to be on the order of 50 nm. Warm air intrusion, increasing wind shear and anomalously cool SSTs caused Beni to weaken from 29/1200 UTC onward. Within 24 hours after its peak, Beni, with winds of 85 knots was causing gales and storm-force winds in parts of central Vanuatu as it passed between that nation and New Caledonia. By 30/2000 UTC, a strengthening ridge to the south of Beni had turned the system to a southerly and eventually southwesterly path around the southeastern tip of New Caledonia. By this time increasing vertical wind shear of 30 to 40 knots had blown away Beni's CDO, exposing the LLCC. At 30/1800 UTC, Beni was downgraded to a 55-knot storm, and 24 hours later Beni was downgraded to a tropical depression while located roughly 240 nautical miles west-southwest of the southern tip of New Caledonia, moving towards the west. The remains of Beni progressed at approximately 10 to 15 knots firstly westward, then in a west-northwesterly, and finally a north- westerly path across the southern Coral Sea. Periodic peripheral gales persisted between the remnant depression and the low-level ridge to the south. By 2 February 2003, these peripheral gales had begun to affect the southeastern Queensland Coast between Sandy Cape and Coolangatta, and gale warnings were issued by the Bureau of Meteorology, Queensland. With increasing sea surface temperatures, Beni managed to regain deep convection to the southeast of the LLCC and the storm reformed into a tropical cyclone at 0100 UTC on 4 February 2003 approximately 135 nautical miles east of Mackay at 20.9S, 151.6E. Beni was moving towards the west at 8 knots at the time with the central pressure estimated at 995 hPa. Re-classification as a cyclone was to be brief, however, and Beni was downgraded to a tropical depression within 12 hours. By the early hours of 5 February 2003 the depression had drifted ashore near Mackay. C. Meteorological Observations and Analysis ------------------------------------------- In post-analysis, Jeff Callaghan of the Queensland Bureau of Meteorology provided this insight into ex-Tropical Cyclone Beni following its initial demise south of New Caledonia: "From 1200 UTC, 29 January 2003 to 31 January 2003, a 500 hPa to 200 hPa LOW developed just to the west of New Caledonia and Beni was moving beneath 40-knot vertical wind shear (CIMSS data) to the east of this system at 1200 UTC, 30 January 2003. Beni was consequently weakening rapidly. The LOW was part of an anticyclonic involution, and ridging developed south of Beni, steering it westward. The ridging developed first at low levels while ridging was delayed at 500 hPa south of Beni as a weakening trough system passed to the south at 1200 UTC, 1 February 2003. This had the effect of displacing the 500 hPa centre of Beni to the southeast of the low-level circulation. "By 1200 UTC, 2 February 2003, a new anticyclonic involution had developed over eastern Australia, culminating in a new 500 hPa LOW southwest of Beni. "This southwest slope of the circulation resulted in a large area of warm air advection on the eastern flank of the system. We diagnosed the warm air advection from the EC 850 hPa, 700 hPa and 500 hPa winds which of course were backing with height in the warm air advection region. The convective blow up around 1200 UTC, 3 February 2003 happened when the warm air advection area reached the strong low-level circulation of Beni. There were 40 to 50-knot northwest winds at 200 hPa over the top of Beni, which kept the convection away from the centre. "Gannet Cay AWS (WMO 94379) was in the convective region and recorded gales from 1300 UTC, 3 February 2003 to 0600 UTC, 4 February 2003 with a maximum 10-minute mean wind of 41 knots. "By 1200 UTC, 4 February 2003 there were 70-knot northwest winds at 200 hPa over the system and the low-level centre got further displaced from the warm air advection and gales. A QuikScat image shows a low-level centre at 0711 UTC, 4 February 2003 near 19S, 151E, while a band of gales to 50 knots were located between 21S and 23S to the south and southeast of the centre. (This gale area was also in the area of strongest warm air advection based on the 1200 UTC, 4 February 2003 EC winds). "The isolated low-level circulation then weakened; however, the warm air advection region came on to the coast and produced very heavy rain." D. Damage and Casualties ------------------------ Whilst Beni was stationary over the Rennell and Bellona group, the estimated 2,000 inhabitants were taking shelter in caves on the island in a similar fashion to the residents of the island of Tikopia (approximately 600 km to the east), which was severely battered by Tropical Cyclone Zoe late in December. Winds gusted to between 50 and 60 knots at the town of Bellona as the cyclone passed by, along with a 48-hour period of heavy rains. Contact with the islands was lost during the storm. Beni was rather destructive to vegetation on the islands, knocking over extensive food-bearing plants including pawpaw (papaya), banana and coconut trees. Salt-water inundation damaged some garden plots, and about 85 buildings constructed of semi-permanent materials were damaged. Preliminary reports from the Vanuatu Meteorological Service mentioned strong winds to marginal gales over central Vanuatu. Over the southern parts, gale-force winds were experienced with gusts to 50 knots. Heavy swells and waves were reported from most islands in New Caledonia and Vanuatu. Inland sea inundation also occurred in some areas during the passage of Beni between the two countries. In Australia, some of the best rains seen in many years affected regions primarily in the coastal zone and hinterland of south-central Queensland south from around Mackay in association with ex-Tropical Cyclone Beni. Some areas in and around Gladstone received in excess of 500 mm of rain during the event. However, much of this rain to the south of Beni was induced in conjunction with an upper-level LOW over southeastern Queensland at the time. There are no known official casualties as a direct result of Beni. Some pictures of Tropical Cyclone Beni's approach to New Caledonia may be found on Geoff Mackley's website: Additional articles on the effects of Beni in the Solomons can be found at the following URL: (Report written by Simon Clarke with contributions by Alipate Waqaicelua, Chief Forecaster of the Nadi TCWC, and Jeff Callaghan of the Brisbane TCWC) TROPICAL CYCLONE CILLA (TD-07F / TC-13P) 25 - 30 January ------------------------------------------ A. Storm Origins ---------------- An area of convection appeared early on 25 January approximately 325 nm west-northwest of Fiji, and by 1900 UTC was located about 240 nm west-northwest of Suva. Animated enhanced infrared imagery revealed increasing deep convection near a LLCC while a 200-mb analysis indicated favorable outflow aloft associated with the western quadrant of an upper- level ridge. The system was embedded in the monsoon trough and was fore- cast to drift southeastward along the trough axis. The Nadi TCWC gave the disturbance a moderate to high chance of developing into a tropical cyclone during the next 24-36 hours. Nadi classified the system as Tropical Depression 07F at 2100 UTC, locating the center about 200 nm northwest of Fiji with 30-kt maximum winds. The depression was embedded in an active monsoon trough linking up with Tropical Cyclone Beni to the northwest. Early on the 26th the LLCC was difficult to locate in satellite imagery. Radar from Nadi showed some circulation, but the center was difficult to pinpoint since the system was on the edge of the radar's range. There was a large area of convection with the deeper convection located mostly to the southeast and north of the depression's center. CIMSS data showed low shear over the LLCC. At 26/1300 UTC JTWC issued a TCFA for the system with deep convection cycling over a partially-exposed center. Around 1800 UTC radar animation showed several small eddies with the main LLCC located about 150 nm east-northeast of Fiji. Most of the deepest convection was confined to the northeastern quadrant of the system at this time. B. Track and Intensity History ------------------------------ By 27/0000 UTC the LLCC had moved beneath a small convective cluster and Nadi upgraded the depression to Tropical Cyclone Cilla. The newly- christened cyclone was located about 275 nm east of Fiji and moving east-southeastward. The MSW was estimated at 35 kts. Convection gradually became better established as the day progressed. CIMSS data revealed 10-20 kts of shear to the south of Cilla, but the shear was forecast to decrease with time. JTWC wrote their final warning on Cilla at 2100 UTC, stating that SSM/I data indicated the mid and upper- level circulations had begun to decouple from the LLCC and that water vapor imagery indicated the system was rapidly becoming extratropical. Nadi's warning at 28/0000 UTC, however, indicated that convective organization had continued to improve. Cilla's intensity was bumped up to the peak of 40 kts at 0600 UTC with the center located approximately 440 nm south-southeast of Pago Pago, still moving east-southeastward in excess of 20 kts. The 1200 UTC advisory from Fiji indicated that the storm had begun to display some baroclinic characteristics; thus, Cilla may have become somewhat hybrid in nature by this juncture. By 1800 UTC the LLCC had become partially-exposed but was still under deep convection which appeared to be struggling against shearing conditions. The cyclone's forward motion had slowed considerably to 10 kts by this time. By 0000 UTC on 29 January the LLCC had once more slipped under the deep convection, and recent satellite images indicated a banding pattern. CIMSS data showed the system to be located in a region of light vertical shear, and Fiji's Dvorak analysis yielded a final T-number of 3.0. The 0600 UTC advisory, however, noted that deep convection had weakened once more, and the latest CIMSS analysis showed that Cilla was located in 30 kts of shear. (JTWC issued a STWO which assigned a fair potential for redevelopment to Cilla's "remnants".) The storm began to weaken quickly thereafter and was downgraded to a tropical depression by Nadi at 29/1200 UTC when located about 360 nm west of Rarotonga. Winds near the center were analyzed to be less than gale force, but gales to 35 kts were occurring within 100 nm of the center in the southern semicircle. The deep convection was sheared well to the southeast of the LLCC. By 1100 UTC on the 30th the depression had become extratropical about 375 nm southwest of Rarotonga. C. Damage and Casualties ------------------------ No damage or casualties are known to have resulted from Tropical Cyclone Cilla. (Report written by Gary Padgett) ************************************************************************* EXTRA FEATURE In order to shorten the amount of typing in preparing the narrative material, I have been in the habit of freely using abbreviations and acronyms. I have tried to define most of these with the first usage in a given summary, but I may have missed one now and then. Most of these are probably understood by a majority of readers but perhaps a few aren't clear to some. To remedy this I developed a Glossary of Abbreviations and Acronyms which I first included in the July, 1998 summary. I don't normally include the Glossary in most months in order to help keep them from being too long. If anyone would like to receive a copy of the Glossary, please e-mail me and I'll be happy to send them a copy. ************************************************************************* AUTHOR'S NOTE: This summary should be considered a very preliminary overview of the tropical cyclones that occur in each month. The cyclone tracks (provided separately) will generally be based upon operational warnings issued by the various tropical cyclone warning centers. The information contained therein may differ somewhat from the tracking and intensity information obtained from a "best-track" file which is based on a detailed post-seasonal analysis of all available data. Information on where to find official "best-track" files from the various warning centers will be passed along from time to time. The track files are not being sent via e-mail. They can be retrieved from the archive sites listed below. (Note: I do have a limited e-mail distribution list for the track files. If anyone wishes to receive these via e-mail, please send me a message.) Both the summaries and the track files are standard text files created in DOS editor. Download to disk and use a viewer such as Notepad or DOS editor to view the files. The first summary in this series covered the month of October, 1997. Back issues can be obtained from the following websites (courtesy of Michael Bath, Michael V. Padua, Michael Pitt, and Chris Landsea): OR Another website where much information about tropical cyclones may be found is the website for the UK Meteorological Office. Their site contains a lot of statistical information about tropical cyclones globally on a monthly basis. The URL is: TROPICAL CYCLONE REPORTS AVAILABLE JTWC now has available on its website the complete Annual Tropical Cyclone Report (ATCR) for 2001 (2000-2001 season for the Southern Hemisphere). ATCRs for earlier years are available also. Recently added was the report for the Southern Hemisphere 2001-2002 season. The URL is: Also, TPC/NHC has available on its webpage nice "technicolor" tracking charts for the 2001 Atlantic and Eastern North Pacific tropical cyclones; also, preliminary storm reports for all the 2001 Atlantic and Eastern North Pacific cyclones are now available, as well as track charts and reports on storms from earlier years. The URL is: A special thanks to Michael Bath of McLeans Ridges, New South Wales, Australia, for assisting me with proofreading the summaries. PREPARED BY Gary Padgett E-mail: garyp@alaweb.com Phone: 334-222-5327 John Wallace (Eastern North Pacific, North Indian Ocean, Western Gulf of Mexico) E-mail: dosidicus@aol.com Kevin Boyle (Eastern Atlantic, Western Northwest Pacific, South China Sea) E-mail: newchapelobservatory@btinternet.com Simon Clarke (Northeast Australia/Coral Sea, South Pacific) E-mail: saclarke@iprimus.com.au ************************************************************************* ************************************************************************* >> Uploaded: 04-01-03 / Typhoon2000.com / Typhoon2000.ph