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Lightning Activity and Its Relation to the Intensity of Typhoons over the Northwest Pacific Ocean

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doi: 10.1007/s00376-013-3115-y

  • Data from the World Wide Lightning Location Network (WWLLN) were used to analyze the lightning activity and the relationship between maximum sustained wind and lightning rate in 69 tropical cyclones over the Northwest Pacific Ocean from 2005 to 2009. The minimum lightning density was observed in the category 2 typhoon Kong-Rey (2007), with a value of only 1.15 d-1 (100 km)-2. The maximum lightning density occurred in the category 2 typhoon Mitag (2007), with a value of 510.42 d-1 (100 km)-2. The average lightning density decreased with radius from the typhoon center in both weak (categories 13) and super (categories 45) typhoons. The average lightning density in the inner core of super typhoons was more than twice as large as that for weak typhoons. Both groups of typhoons showed a near-monotonic decrease in lightning density with radius. Results also showed that lightning activity was more active in typhoons that made landfall than in those that did not. The mean correlation coefficient between the accumulated flashes within a 600-km radius and the maximum wind speed in the weak typhoons and super typhoons was 0.81 and 0.74, respectively. For more than 78% (56%) of the super (weak) typhoons, the lightning activity peaked before the maximum sustained wind speed, with the most common leading time being 30 (60) h. The results suggest that, for the Northwest Pacific Ocean, lightning activity might be used as a measurement of the intensification of typhoons.
    摘要: Data from the World Wide Lightning Location Network (WWLLN) were used to analyze the lightning activity and the relationship between maximum sustained wind and lightning rate in 69 tropical cyclones over the Northwest Pacific Ocean from 2005 to 2009. The minimum lightning density was observed in the category 2 typhoon Kong-Rey (2007), with a value of only 1.15 d-1 (100 km)-2. The maximum lightning density occurred in the category 2 typhoon Mitag (2007), with a value of 510.42 d-1 (100 km)-2. The average lightning density decreased with radius from the typhoon center in both weak (categories 1-3) and super (categories 4-5) typhoons. The average lightning density in the inner core of super typhoons was more than twice as large as that for weak typhoons. Both groups of typhoons showed a near-monotonic decrease in lightning density with radius. Results also showed that lightning activity was more active in typhoons that made landfall than in those that did not. The mean correlation coefficient between the accumulated flashes within a 600-km radius and the maximum wind speed in the weak typhoons and super typhoons was 0.81 and 0.74, respectively. For more than 78% (56%) of the super (weak) typhoons, the lightning activity peaked before the maximum sustained wind speed, with the most common leading time being 30 (60) h. The results suggest that, for the Northwest Pacific Ocean, lightning activity might be used as a measurement of the intensification of typhoons.
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  • Abarca, S. F., K. L. Corbosiero, and T. J. Galarneau Jr., 2010: An evaluation of the Worldwide Lightning Location Network (WWLLN) using the National Lightning Detection Network (NLDN) as ground truth. J. Geophys. Res., 115, D18206, doi: 10.1029/2009JD013411.
    Abarca, S. F., K. L. Corbosiero, and D. Vollaro, 2011: The world wide lightning location network and convective activity in tropical cyclones. Mon. Wea. Rev., 139(1),175-191.
    Boccippio, D. J., W. J. Koshak, and R. J. Blakeslee, 2002: Performance assessment of the optical transient detector and lightning imaging sensor. Part I: Predicted diurnal variability. J. Atmos. Oceanic Technol., 19, 1318-1332.
    Cecil, D. J., and E. J. Zipser, 1999: Relationships between tropical cyclone intensity and satellite-based indicators of inner core convection: 85-GHz ice-scattering signature and lightning. Mon. Wea. Rev., 127, 103-123.
    Cecil, D. J., E. J. Zipser, and S. W. Nesbitt, 2002: Reflectivity, ice scattering, and lightning characteristics of hurricane eyewalls and rainbands. Part I: quantitative description. Mon. Wea. Rev., 130(4),769-784.
    Cecil, D. J., and E. J. Zipser, 2002: Reflectivity, ice scattering, and lightning characteristics of hurricane eyewalls and rainbands. Part II: intercomparison of observations. Mon. Wea. Rev., 130(4),785-801.
    Cecil, D. J., D. E.,Buechlera, and R. J. Blakeslee, 2012: Gridded lightning climatology from TRMM-LIS and OTD: Dataset description. Atmospheric Research, doi: 10.1016/j.atmosres.2012.06.028.
    Cummins, K. L., M. J. Murphy, E. A. Bardo, W. L. Hiscox, R. B. Pyle, and A. E. Pifer, 1998: A combined TOA/MDF technololgy upgrade of the US. national lightning detection network. J. Geophys. Res., 103, 9035-9044.
    DeMaria, M., and R. T. DeMaria, 2009: Applications of lightning observations to tropical cyclone intensity forecasting. Preprints, 16th Conference on Satellite Meteorology and Oceanography. A. Z. Phoenix et al., Eds. Amer. Meteor. Soc., 1. 3.
    DeMaria, M., R. T. DeMaria, J. A. Knaff, and D. Molenar, 2012: Tropical cyclone lightning and rapid intensity change. Mon. Wea. Rev., 140, 1828-1842.
    Fierro, A. O., X. M. Shao, T. Hamlin, and J. M. Reisner, 2011: Evolution of eyewall convective events as indicated by intracloud and cloud-to-ground lightning activity during the rapid intensification of hurricanes Rita and Katrina. Mon. Wea. Rev., 139(5),1492-1504.
    Gallina, G. M., and C. S. Velden, 2002: Environmental vertical wind shear and tropical cyclone intensity change utilizing enhanced satellite derived wind information. Extended Abstracts, 25th Conf. on Hurricanes and Tropical Meteorology. San Diego, CA, Amer. Meteor. Soc., 172-173.
    Gray, W. M., 1968: Global view of the origin of tropical disturbances and storms. Mon. Wea. Rev., 96, 669-700.
    Jacobson, A. R., R. Holzworth, J. Harlin, R. Dowden, and E. Lay, 2006: Performance assessment of the World Wide Lightning Location Network (WWLLN), using the Los Alamos Sferic Array (LASA) array as ground-truth. J. Atmos. Oceanic Tech., 23, 1082-1092.
    Lang, T. J., and S. A. Rutledge, 2008: Kinematic, microphysical, and electrical aspects of an asymmetric bow-echo mesoscale convective system observed during STEPS 2000. J. Geophys. Res., 113(D08213), doi: 10.1029/2006JD007709.
    Lay, E. H., R. H. Holzworth, C. J. Rodger, J. N. Thomas, O. Pinto Jr., and R. L. Dowden, 2004: WWLL global lightning detection system: Regional validation study in Brazil. Geophys. Res. Lett., 31, L03102, doi: 10.1029/2003GL018882.
    Liu, D. X., X. S. Qie, Y. J. Xiong, and G. L. Feng, 2011: Evolution of the total lightning activity in a leading-line and trailing stratiform mesoscale convective system over Beijing. Adv. Atmos. Sci., 28(4),866-878, doi: 10.1007/s00376-010-0001-8.
    Lyons, W. A., and C. S. Keen, 1994: Observations of lightning in convective supercells within tropical storms and hurricanes. Mon. Wea. Rev., 122(8),1897-1916.
    Molinari, J., P. K., Moore, V. P., Idone, R. W., Henderson, and A. B.,Saljoughy, 1994: Cloud-to-ground lightning in Hurricane Andrew. J. Geophys. Res., 99(D8),16 665-16 676.
    Molinari, J., P. K. Moore, and V. P. Idone, 1999: Convective structure of hurricanes as revealed by lightning locations. Mon. Wea. Rev., 127(4),520-534.
    Pan, L. X., X. S. Qie, D. X. Liu, D. F. Wang, and J. Yang, 2010: The lightning activities in super typhoons over the Northwest Pacific. Science China: Earth Sciences, 53, 1241-1248, doi: 10.1007/s11430-010-3034-z.
    Price, C., M. Asfur, and Y. Yair, 2009: Maximum hurricane intensity preceded by increase in lightning frequency. Nature Geoscience, 2(5),329-332.
    Qie, X. S., 2012: Progresses in the atmospheric electricity researches in China during 2006-2010. Adv. Atmos. Sci., 29(5),993-1005, doi: 10.1007/s00376-011-1195-0.
    Qie, X. S., R. Toumi, and Y. J. Zhou, 2003: Lightning activity on the central Tibetan Plateau and its response to convective available potential energy. Chinese Science Bullutin, 48(4),296-299.
    Qie, X. S., Q. L., Zhang, T., Yuan, and T. L.,Zhang, 2013: Lightning Physics. Science Press, 297pp. (in Chinese)
    Rodger, C. J., J. B. Brundell, R. L. Dowden, and N. R. Thomson, 2004: Location accuracy of long-distance VLF lightning location network. Ann. Geophys., 22, 747-758.
    Rodger, C. J., J. B. Brundell, and R. L. Dowden, 2005: Location accuracy of VLF World Wide Lightning Location (WWLL) network: Postalgorithm upgrade. Ann. Geophys., 23, 277-290.
    Rodger, C. J., S. W. Werner, J. B. Brundell, N. R. Thomson, E. H. Lay, R. H. Holzworth, and R. L. Dowden, 2006: Detection efficiency of the VLF World-Wide Lightning Location Network (WWLLN): Initial case study. Ann. Geophys., 24, 3197-3214.
    Rodger, C. J., J. B. Brundell, R. H. Holzworth, and E. H. Lay, 2009: Growing detection efficiency of the World Wide Lightning Location Network. AIP Conf. Proc. 1118,118, 15-20, doi: 10.1063/1.3137706.
    Rogers, R. R., and M. K. Yau, 1989: A short course in cloud physics. Vol. 113, International Series in Natural Philosophy, Pergamon Press, 293 pp.
    Shao, X. M., and Coauthors, 2005: Katrina and Rita were lit up with lightning. EOS, 86, 398-399.
    Shao, X. M., M. Stanley, A. Regan, J. Harlin, M. Pongratz, and M. Stock, 2006: Total lightning observations with the new and improved Los Alamos Sferic Array (LASA). J. Atmos. Oceanic Technol., 23, 1273-1288.
    Schultz, C. J., W. A. Petersen, and L. D. Carey, 2009: Preliminary development and evaluation of lightning jump algorithms for the real-time detection of severe weather. J. Appl. Meteor. Climatol., 48, 2543-2563.
    Solorzano, N. N., J. N. Thomas, and R. H. Holzworth, 2008: Global studies of tropical cyclones using the World Wide Lightning Location Network. Third Conference on Meteorological Applications of Lightning Data, 5 pp. [Available online at http://library.cma.gov.cn:8087/ams_data/AMS2008_/134367.pdf.]
    Squires, K., and S. Businger, 2008: The morphology of eyewall lightning outbreaks in two category 5 hurricanes. Mon. Wea. Rev., 136(5),1706-1726.
    Thomas, J. N., N. N. Solorzano, S. A. Cummer, and R. H. Holzworth, 2010: Polarity and energetics of inner core lightning in three intense North Atlantic hurricanes. J. Geophys. Res., 115, A00E15, doi: 10.1029/2009JA014777.
    Williams, E., and S. Stanfill, 2002: The physical origin of the land-ocean contrast in lightning activity. Comptes Rendus Physique, 3, 1277-1292.
    Yang, M. R., T. Yuan, X. S. Qie, and L. X. Pan, 2011: An analysis of the characteristics of lightning activities, radar reflectivity and ice scattering for tropical cyclones over the western North Pacific. Acta Meteorologica Sinica, 69(2),370-380. (in Chinese)
    Yuan, T., and X. S. Qie, 2008: Study on lightning activity and precipitation characteristics before and after the onset of the South China Sea summer monsoon. J. Geophys. Res., 2008, 113, D14101, doi: 10.1029/2007JD009382
    Zhang, W. J., Y. J. Zhang, D. Zheng, and X. J. Zhou, 2012: Lightning distribution and eyewall outbreaks in tropical cyclones during landfall. Mon. Wea. Rev., 140, 3573-3586.
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Manuscript received: 31 May 2013
Manuscript revised: 25 October 2013
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Lightning Activity and Its Relation to the Intensity of Typhoons over the Northwest Pacific Ocean

    Corresponding author: QIE Xiushu; 
    Corresponding author: WANG Dongfang, qiex@mail.iap.ac.cn
  • 1. Key Laboratory of the Middle Atmosphere and Global Environment Observation, Institute of Atmospheric Physics, Chinese Academy of Sciences, Beijing 100029 ; 
  • 2. Collaborative Innovation Center on Forecast and Evaluation of Meteorological Disasters, Nanjing University of Information Science & Technology, Nanjing 210044
Fund Project:  This research was supported by the National Natural Science Foundation of China (Grant Nos. 41005004 and 40930949) and the One-Hundred Talents Project of the Chinese Academy of Sciences. The authors wish to thank the World Wide Lightning Location Network (http://wwlln.net), a collaboration of over 50 universities and institutions, for providing the lightning location data used in this paper. Special thanks are also extended to Washington University for providing the lightning dataset. The authors would like to thank the two anonymous reviewers for their constructive suggestions, which helped improve the quality of the paper.

Abstract: Data from the World Wide Lightning Location Network (WWLLN) were used to analyze the lightning activity and the relationship between maximum sustained wind and lightning rate in 69 tropical cyclones over the Northwest Pacific Ocean from 2005 to 2009. The minimum lightning density was observed in the category 2 typhoon Kong-Rey (2007), with a value of only 1.15 d-1 (100 km)-2. The maximum lightning density occurred in the category 2 typhoon Mitag (2007), with a value of 510.42 d-1 (100 km)-2. The average lightning density decreased with radius from the typhoon center in both weak (categories 13) and super (categories 45) typhoons. The average lightning density in the inner core of super typhoons was more than twice as large as that for weak typhoons. Both groups of typhoons showed a near-monotonic decrease in lightning density with radius. Results also showed that lightning activity was more active in typhoons that made landfall than in those that did not. The mean correlation coefficient between the accumulated flashes within a 600-km radius and the maximum wind speed in the weak typhoons and super typhoons was 0.81 and 0.74, respectively. For more than 78% (56%) of the super (weak) typhoons, the lightning activity peaked before the maximum sustained wind speed, with the most common leading time being 30 (60) h. The results suggest that, for the Northwest Pacific Ocean, lightning activity might be used as a measurement of the intensification of typhoons.

摘要: Data from the World Wide Lightning Location Network (WWLLN) were used to analyze the lightning activity and the relationship between maximum sustained wind and lightning rate in 69 tropical cyclones over the Northwest Pacific Ocean from 2005 to 2009. The minimum lightning density was observed in the category 2 typhoon Kong-Rey (2007), with a value of only 1.15 d-1 (100 km)-2. The maximum lightning density occurred in the category 2 typhoon Mitag (2007), with a value of 510.42 d-1 (100 km)-2. The average lightning density decreased with radius from the typhoon center in both weak (categories 1-3) and super (categories 4-5) typhoons. The average lightning density in the inner core of super typhoons was more than twice as large as that for weak typhoons. Both groups of typhoons showed a near-monotonic decrease in lightning density with radius. Results also showed that lightning activity was more active in typhoons that made landfall than in those that did not. The mean correlation coefficient between the accumulated flashes within a 600-km radius and the maximum wind speed in the weak typhoons and super typhoons was 0.81 and 0.74, respectively. For more than 78% (56%) of the super (weak) typhoons, the lightning activity peaked before the maximum sustained wind speed, with the most common leading time being 30 (60) h. The results suggest that, for the Northwest Pacific Ocean, lightning activity might be used as a measurement of the intensification of typhoons.

1. Introduction
  • Lightning has been used to study the structure and changes in intensity of tropical cyclones over the last two decades by using various lightning networks. Using data from the ground-based National Lightning Detection Network (NLDN), (Molinari et al., 1994) studied the spatial and temporal distribution of cloud-to-ground (CG) lightning in hurricane Andrew in 1992 and found that the lightning radial distribution was consistent with the convective structure of mature hurricanes. They also found that eyewall lightning tended to be episodic, occurring prior to and during periods of intensification of the storm. (Lyons and Keen, 1994) described lightning variations in four tropical storms, and found that two of the storms showed significant outbreaks of lightning near the center before or during their intensification. (Molinari et al., 1999) examined nine Atlantic basin hurricanes and the results showed that the outbreaks of eyewall flashes over water always occurred at the beginning of, or during times of, intensification. Their study, however, was limited to storms sampled within a distance of 400 km of the US coastline.

    (Squires and Businger, 2008) used the Long-Range Lightning Detection Network (LLDN) and Tropical Rainfall Measuring Mission (TRMM) dataset to examine the morphology of lightning outbreaks in the eyewall of two hurricanes. Their study showed that outbreaks of eyewall lightning occur during the period of the most rapid intensification, during the eyewall replacement cycles, and during the time period that encompasses the maximum intensity for each hurricane. (Shao et al., 2005) found that the eyewall lightning rate was higher during the transition stage from lower to higher hurricane classification categories in both hurricanes Katrina and Rita on the basis of the data from the Los Alamos Sferics Array (LASA). (DeMaria et al., 2012) studied the relationship between the spatial evolution of lightning density and tropical cyclone intensity in the Atlantic and East Pacific basins. (Zhang et al., 2012) studied the lighting distribution in 33 Northwest Pacific tropical cyclones during the period of landfall in China and found that lightning outbreaks connect the relationship of eyewall flashes to the changes of structure and intensity of tropical cyclones.

    Observations from the World Wide Lightning Location Network (WWLLN) have also been successfully used to study the lightning activity in tropical cyclones. (Solorzano et al., 2008) studied two Atlantic hurricanes and three western Pacific typhoons and found that eyewall lightning outbreaks occur prior to or during most major intensity changes for all storms. (Price et al., 2009) analyzed lightning frequency and the maximum sustained winds of 56 category 4-5 hurricanes around the globe and found that, in all of these hurricanes, lightning frequency and maximum sustained winds were significantly correlated, where the maximum sustained wind and minimum pressure in hurricanes were preceded by increases in lightning activity approximately one day before the peak wind. (Pan et al., 2010) studied seven super typhoons over the western Pacific from 2005-08. Their results indicated that there were three distinct lightning flash regions in mature typhoons. Each typhoon produced eyewall lightning outbreaks during the periods of its intensification, usually several hours prior to its maximum intensity. (Thomas et al., 2010) studied the polarity and energetics of inner core lightning in three intense North Atlantic hurricanes, and found episodic inner-core lightning outbreaks prior to and during the most changes of the storm's intensity. A new finding from their results is that positive CG lightning in the inner core increased prior to and during the periods of storm weakening. (Abarca et al., 2011) studied 24 Atlantic tropical cyclones (TCs) and suggested that flash density in the inner core was a parameter with potential to distinguish between intensifying versus non-intensifying TCs, particularly in the weaker storm stage when flash density was the largest.

    Figure 1.  Cloud top brightness temperature distribution from the MTSAT-1R satellite of typhoons Kujira (2009) and Linfa (2009) and the distribution of flashes (pink dots) within one hour around the time (UTC) of the image; three circles from the inside to outside of radii represent 600 km, 800 km and 1000 km, respectively.

    Satellite-based lightning datasets have also been used to study the lightning activity in tropical storms. (Cecil and Zipser, 1999) and (Yang et al., 2011) used data from TRMM, and found no clear relationship between lightning rate and TC intensification. (Cecil et al., 2002) and (Cecil and Zipser, 2002) studied 45 hurricanes, and showed that lightning density maxima were in the eyewall and outer rainband regions, with a lightning density minimum in the inner rainband regions.

    Previous studies have shown that there is a significant relationship between inner-core lightning activity and hurricane intensity. Most of these studies, however, were mainly focused on hurricanes over the Atlantic Ocean. Accordingly, the goal of this study is to examine lightning activity in different categories of typhoons, and the relationship between total lightning activity and typhoon intensity of all the typhoons ranging from category 1-5 on the Saffir Simpson scale that occurred over the Northwest Pacific from 2005-09. Lightning that occurred at #cod#60;100 km from the center is defined as inner-core lightning (or eyewall lightning); #cod#60;600 km is defined as total typhoon lightning; and 100-600 km is defined as outer rainband lightning (refer to section 3). First, the lightning activity in weak typhoons against super typhoons was compared. Then, the relationship between lightning rate and typhoon intensity was analyzed.

2. Data and analysis methods
  • The lightning data used in this study are from the WWLLN over a 5-yr period from 2005-09. The WWLLN provides almost real-time lightning locations by measuring the very low frequency (VLF) radiation (3-30 kHz) emanating from lightning discharges (Rodger et al., 2004). The efficiency and location accuracy of the WWLLN has been estimated for some regions by comparison to regional ground-based lightning detection systems (Lay et al., 2004; Rodger et al., 2004, 2005, 2006, 2009; Jacobson et al., 2006; Abarca et al., 2010). The WWLLN has been improved over the years and its detection efficiency is increasing. The initial work by (Lay et al., 2004) found that the detection efficiency for ground flashes was only 0.3% when comparing the WWLLN with the Brazil Integrated Network (BIN). Rodger et al. (2004, 2005) compared the WWLLN with the Kattron in Australia during 2003 and 2004, and found that the detection efficiency was 1% and 13%, respectively. (Rodger et al., 2006) also estimated the detection efficiency with the New Zealand Detection Network and found that 10% of the flashes were detected by the WWLLN. The NLDN (Cummins et al., 1998) and LASA (Shao et al., 2005, 2006) data were also used as the ground truth (Jacobson et al., 2006) to estimate the WWLLN detection efficiency and showed a detection efficiency of about 4%. (Rodger et al., 2009) pointed out that the new algorithm in their study has led to WWLLN detection efficiency improvements of 63%. The most recent study found that the detection efficiency was greater than 10% for peak currents larger than #cod#177; 35 kA, 35% for currents larger than -130 kA, and #cod#8764; 2% for peak currents between 0 and -10 kA (Abarca et al., 2010). The location accuracy was different for different azimuths, with average location errors of 4.03 km in the north-south and 4.98 km in the east-west directions, respectively. The above studies have shown that WWLLN station coverage and detection efficiency have varied from year to year. Therefore, a method is needed to account for this variation. The long-term global lightning density climatology from the Optical Transient Detector (OTD) and Lightning Imaging Sensor (LIS) was used to adjust the detection efficiency of the WWLLN. The flash detection efficiency of the LIS was estimated to be about 90% and 70% for night and noon by (Boccippio et al., 2002), which can provide an accurate estimate of the annual mean total typhoon lightning density over the Northwest Pacific. The LIS/OTD High Resolution Full Climatology (HRFC) lightning dataset with a grid resolution of 0.5#cod#x000b0;#cod#215; 0.5#cod#x000b0; was obtained from the Global Hydrology and Climate Lightning Research Team at National Aeronautics and Space Administration (NASA)'s Marshall Space Flight Center, which included OTD data from 1995-2000 and LIS data from 1998-2010 (Cecil et al., 2012).

  • The time, location, maximum sustained wind and minimum central pressure of typhoons at 6-h intervals were obtained from the "best-track" data produced by the Joint Typhoon Warning Center. The resolution of 6-h "best-track" data was linearly interpolated to 1-h resolution for convenience of the representations. The radii of the typhoons studied herein varied from 600 to 1300 km according to the MTSAT-1R satellite IR images (Fig. 1) during the maximum intensity of typhoons. Eighty percent of radii of the typhoons within our sample were about 600 km. Therefore, nominal radius values of 600 km were selected to properly represent the size range of typhoons in the sample considered in this study. The lightning data within a 600 km radius were summed with a 30-min period centered at the time of each storm position estimate from the best track.

  • The annual mean lightning density climatology from LIS/OTD in units of strikes per square kilometer per year was used for adjustment (or correction) of the WWLLN detection efficiency. The annual average lightning density from the WWLLN was calculated for each year over the Northwest Pacific domain (0#cod#x000b0;-45#cod#x000b0;N, 135#cod#x000b0;-180#cod#x000b0;E). These values were compared to the value of mean lightning density climatology from LIS/OTD over the same domain. Table 1 shows the amount of lightning flashes and the adjustment factors needed to make the WWLLN average lightning density equal to that from the LIS/OTD.

3. Results and discussion
  • A total of 133 TCs were observed in the Northwest Pacific from 2005-09, 69 of which developed into typhoons. Among them, Typhoon Ioke (2006) initially formed in the eastern Pacific. The typhoons were divided into two different groups according to their intensity based on the Saffir-Simpson scale. During the period considered, 32 weak typhoons (categories 1-3) and 37 super typhoons (categories 4-5) were observed. More than 80% of the 69 typhoons formed between May and November in the Northwestern Pacific. (Qie et al., 2013) once briefly introduced the relationship between lightning flashes and the maximum wind speed in typhoons. In the following sections, we will discuss in detail the lightning activity and its relationship with the intensity of the two groups of typhoons.

  • Tables 2 and 3 present a summary of flash rate and lightning intensity within 100 km from the center and the outer rainband (100-600 km) for the weak and super typhoons, respectively. The tables also include typhoon information such as name, year, category and sustained hours. The lightning data in Tables 2 and 3 were adjusted according to the adjustment factors shown in Table 1. The average flash rate means the number of flashes that occurred per day during the whole life of one typhoon. The lightning density in Tables 2 and 3 is defined as the number of flashes occurring over unit area in unit time, and expressed as the number of flashes per 100 km2 per day [in a unit of d-1 (100 km)-2]. It can be seen from the two tables that the average flash rate and lightning density varied significantly from one typhoon to another. The maximum lightning density occurred in the category 2 typhoon Mitag (2007), with a value of 510.42 d-1 (100 km)-2. The minimum was observed in the category 2 typhoon Kong-Rey (2007), with a value of only 1.15 d-1 (100 km)-2.

    Table 2 shows that, in the weak typhoon, the outer rainband lightning rate ranged from 22 to 55 393 d-1, and the flash rate within the inner core ranged from 15 to 5578 fl d-1. The outer rainband lightning density ranged from 0.25 to 503.77 d-1 (100 km)-2 and the inner-core lightning density ranged from 3.52 to 1776.80 d-1 (100 km)-2. The geometric mean lightning density was 105.18 d-1 (100 km)-2 and 150.77 d-1 (100 km)-2 in the outer rainband and the inner core, respectively. The median lightning density was 159.89 d-1 (100 km)-2 and 134.87 d-1 (100 km)-2 in the outer rainband and the inner core, respectively.

    Table 3 shows that, in the super typhoon, the outer rainband lightning rate ranged from 835 to 49 502 d-1 and the flash rate within the inner core ranged from 89 to 13 579 d-1. The outer rainband lightning density ranged from 7.60 to 450.12 d-1 (100 km)-2 and the inner-core lightning density ranged from 27.79 to 4322.72 d-1 (100 km)-2. The geometric mean lightning density was 70.45 d-1 (100 km)-2 and 230.25 d-1 (100 km)-2 in the outer rainband and the inner core, respectively. The median lightning density was 57.70 d-1 (100 km)-2 and 269.76 d-1 (100 km)-2 in the outer rainband and the inner core, respectively.

    The significant difference in these two groups is that the geometric mean and median lightning density in the inner core of super typhoons is greater than that of weak typhoons. On the contrary, the outer rainband lightning activity shows a reverse tendency.

    Figure 2 shows the average lightning density as a function of radius for 37 super typhoons and 32 weak typhoons. A total of 195 and 316 samples (days) in weak typhoons and super typhoons were chosen for this study, respectively. This figure shows that the average lightning density in the inner core of super typhoons is more than twice as large as that for weak typhoons. It also shows a near-monotonic decrease in lightning density with radius in both groups of typhoon. A similar structure was shown in the Atlantic and East Pacific by (DeMaria et al., 2012). However, the individual case studies show that there is a minimum lightning density region between the inner core and the outer rainband, which was also confirmed by (Molinari et al., 1999) and (Pan et al., 2010).

    Two examples of cloud IR satellite images and flash distribution within #cod#177;0.5 h of the image time for typhoons Linfa (2009) (category 1; Fig. 1a) and Kujira (2009) (category 4; Fig. 1b) are shown in Fig. 1. Most of the flashes were located within the cloud region, although a few were located outside the cloud region because of the typhoon's motion (including individual azimuthal cloud motion coupled with the storm forward translation speed) and detection errors. Lightning occurred in deep convective clouds and clustered in outer spiral rainbands in both typhoons. In Typhoon Linfa (2009), lightning was detected in the outer rainband but not in the eyewall region, which illustrates why previous studies have used eyewall lightning to evaluate hurricane intensity (e.g., Molinari et al., 1994, 1999; Squires and Businger, 2008; Pan et al., 2010; Thomas et al., 2010). Similar to the finding of (Fierro et al., 2011), lightning in the TCs is associated with deep convective clouds. Those results are very similar to those found by (DeMaria et al., 2012). The amount of flashes that occurred within the inner core was very small for a number of samples. Therefore, total typhoon lightning (#cod#60; 600 km) was used to study typhoon intensity in this work.

    Figure 2.  Mean lightning density as a function of radius from the typhoon center in the two groups of typhoons.

  • Figures 3-5 show the evolution of maximum sustained winds and total typhoon lightning frequency within 600 km at 6-h intervals for typhoons Usagi (2007) (Fig. 3), Roke (2005) (Fig. 4), and Pabuk (2007) (Fig. 5). Lightning flash counts accumulated over 12-h and 24-h intervals are also shown.

    The evolutions of 6-h, 12-h, and 24-h maximum sustained wind and accumulated flashes within 600 km of the typhoon center are shown for the entire lifetime of Typhoon Usagi (2007) in Fig. 3. Usagi (2007) attained its maximum intensity at 0000 UTC 1 August 2007 with a maximum sustained surface wind of 61.7 m s-1. The peaks of 6-h and 12-h total typhoon lightning within 600 km peaked at 0000 UTC 30 July, 48 h prior to the wind maximum. However, the peak of 24-h lightning preceded that of maximum wind by three days rather than two days. The linear correlation coefficients (r) between 6-h, 12-h, and 24-h accumulated total typhoon lightning activity and the maximum sustained winds 48 h later are 0.76, 0.85, and 0.92, respectively. The minimum surface pressure within Typhoon Usagi (2007) dropped abruptly by 31 hPa between 0000 UTC 28 July and 0000 UTC 30 July. The hourly flash rate soared during this intensification stage, suggesting that vigorous convective activity during this period produced multiple lightning events.

    Figure 3.  Evolution of 6-h (top), 12-h (middle), and 24-h (bottom) maximum sustained winds (dashed curve) and accumulated lightning flashes within 600 km (curve with asterisks) observed for Typhoon Usagi (2007).

    The maximum sustained wind speed of Typhoon Roke (2005) (Fig. 4) peaked at 41.2 m s-1 at 0000 UTC 16 July 2005 and persisted through 1200 UTC 16 July. The 6-h, 12-h, and 24-h 600-km lightning activity peaked simultaneously with the maximum wind speed. The correlation coefficients between 600-km lightning activity and simultaneous maximum wind are 0.64 at 6-h, 0.76 at 12-h, and 0.95 at 24-h intervals. The minimum surface pressure in Typhoon Roke (2005) dropped only 6 hPa between 0000 UTC 12 March and 0000 UTC 14 March. Lightning activity was weak during this period, and remained weak relative to the intensification period of other observed typhoons.

    Figure 4.  The same as Fig. 3, but for Typhoon Roke (2005).

    Figure 5 shows the evolution of lightning activity and maximum wind in Typhoon Pabuk (2007). The maximum wind peaked at 36 m s-1 at 1200 UTC 7 August 2007. The 6-h total typhoon lightning activity peak occurred 18 h after the maximum wind peak. The peaks of 12-h and 24-h 600-km lightning activity also lagged behind that of maximum wind, by 12 h and 24 h, respectively. The lag correlation coefficients between 600-km lightning activity and maximum wind are 0.69 at 6-h (18-h lag), 0.71 at 12-h (12-h lag), and 0.82 at 24-h (24-h lag). There were no lightning outbreaks during the intensification stage of Typhoon Pabuk (2007), but a lightning outbreak occurred during the dissipation stage.

    Recent studies have shown that eyewall lightning bursts often occur prior to hurricane intensification (e.g., Molinari et al., 1994, 1999; Shao et al., 2005; Squires and Businger, 2008). On the basis of WWLLN observations, (DeMaria and DeMaria, 2009) suggested that lightning outbreaks in the outer rainband might be a better proxy for hurricane intensity than lightning outbreaks in the eyewall. Our results show that total typhoon lightning activity is strongly correlated to lightning outbreaks during periods of dramatic change in typhoon intensity.

    Typhoon Kirogi (2005) (Fig. 6) also experienced lightning outbreaks during periods of dramatic changes in intensity. Lightning activity in Typhoon Kirogi (2005) was weak from 0000 UTC 13 October to 0000 UTC 15 October 2005, when the maximum sustained wind speed was roughly constant. By contrast, lightning activity was strong during periods when the maximum wind speed was changing. The evolution of lightning activity during Typhoon Fitow (2007) (Fig. 7) was similar: the number of lightning flashes soared during the intensification period (0000 UTC 28 August to 0000 UTC 30 August, 2007), but the lightning activity was weak for several days as the intensity of the typhoon remained roughly constant.

    Figure 5.  The same as Fig. 3, but for Typhoon Pabuk (2007).

    (Price et al., 2009) performed a correlation analysis for 56 super hurricanes and reported a mean correlation between lightning activity and wind speed of 0.82. This study used a similar method. Figure 8 shows distributions of the lag time between maximum lightning activity and maximum sustained winds for weak (category 1-3) typhoons and super (category 4-5) typhoons (Fig. 8). These lag times were obtained by identifying the maximum lag correlation between the two datasets. Lag correlations were calculated by shifting the lightning activity time series relative to that of maximum sustained wind by 12-h increments within the range from -4 to +3.5 days. A positive lag time indicates that lightning activity peaked prior to the maximum wind intensity, while a negative lag time indicates that lightning activity peaked after the maximum wind intensity.

    Figure 6.  Evolution of total accumulated lightning within 600 km over 24 h (solid curve) and maximum sustained winds (dashed curve) during Typhoon Kirogi (2005).

    Figure 7.  The same as Fig. 6 but for Typhoon Fitow (2007).

    Figure 8.  Distributions of lag times between maximum lightning activity and maximum sustained winds in 32 weak typhoons and 37 super typhoons.

    Lightning activity peaked before maximum wind intensity in nearly 56% of the weak typhoons, with an average lag of 60 h (geometric mean). Lightning activity peaked before maximum wind intensity in 78% of super typhoons, with a geometric mean lag of 30 h.

    Lightning activity peaked after maximum sustained winds in about 15% of weak typhoons. This result seems to be related to intensification of convection after landfall in these storms. Table 4 provides a statistical summary of 10 weak typhoons that made landfall; as expected, peak lightning activity generally occurred within one day of typhoon landfall.

    Table 5 provides additional information on these 10 landfall weak storms and 11 storms that did not make landfall and that were consistently located far from land. Of the 11 typhoons that did not make landfall, 10 of them had peak lightning activity that preceded the maximum wind speed, while only one typhoon had peak lightning activity that lagged behind the maximum sustained wind speed. The mean correlation coefficient is 0.77. Table 5 also shows that lightning activity is typically substantially greater in landfalling typhoons than in typhoons that do not make landfall. This difference was observed in both the inner cores and within 600 km of the storm centers. A number of factors are responsible for the different lightning activity between landfall and no-landfall typhoons. One possible reason is the amount of cloud condensation nuclei (CCN), which greatly increases close to land, and influences the microphysics and drop size distribution greatly by favoring the nucleation of more small drops. This can also enhance the production (through riming on frozen drops) of ice pellets and graupel aloft compared to fewer larger drops over water produced via efficient coalescence (Rogers and Yau, 1989; Williams and Stanfill, 2002), as fewer CCN compete for an abundant supply of moisture. Another possible reason is the east-west SST gradients in the western Pacific, which will enhance the lightning activity during the landfall of typhoons. And the third possible reason is the orographic forcing of clouds and the lifting due to topography and the convective available potential energy (Qie et al., 2003) as the storms make landfall.

    Figure 9 shows correlation coefficients between lightning activity and maximum sustained wind speed for 32 weak typhoons (Fig. 9a) and 37 super typhoons (Fig. 9b), taking into account the lag times identified for each storm. The names of the typhoons are shown along the x-axis and the correlation coefficients are shown using different symbols to represent different levels of statistical significance. The mean correlation between lightning activity and maximum sustained winds is stronger for weak typhoons (0.81) than for super typhoons (0.74). The correlation in this study for the super typhoons is lower than the value (r=0.82) calculated by (Price et al., 2009) because we used 12-h accumulated total typhoon lightning activity within 600 km instead of mean daily lightning activity. If we instead consider a fixed lag time of 24 h between the lightning activity peak and the maximum wind speed peak in all typhoons, 37 out of 69% (54%) of the typhoons show a positive correlation among them, with a mean correlation of 0.72.

    The intensity of a tropical storm is controlled by many factors, and in many cases it is difficult to isolate the effects of one factor from those of another. Changes in TC intensity are governed mainly by internal dynamics (e.g., eyewall contraction, eyewall replacement cycles, and interactions between the inner core and outer rainband) and environmental conditions (e.g., vertical wind shear, moisture distributions, sea surface temperature, and ocean mixed layer temperature and depth). (Fierro et al., 2011) showed the relation between lightning bursts and the existence of deep convective clouds in mature hurricanes using in-situ tail Dopper radar data from aircraft reconnaissance. The results from (DeMaria et al., 2012) suggested that the rainband lightning flash rate could be a better proxy for imminent TC intensification while eyewall lightning bursts were essentially more correlated with the end of an intensification cycle. They also found that TC intensification would be expected via axisymmetrization of convective heat from a newly formed vertical hot tower around the eyewall. (Gallina and Velden, 2002) noted time lags between changes in the vertical wind shear and changes in TC intensity. The detrimental effect that vertical wind shear exerts on a TC has been explained as "ventilation" (Gray, 1968): the wind shear advects upper-level warm air away from the low-level center. The low-level moisture inflow provides moisture to the upper-level. If the upper-level outflow is too strong, ice and snow will be taken away from upper-level regions and consume the supercooled water in the mixed phase region. Lightning is related to the vertical wind shear, which modifies TC intensity through its influence on microphysical processes within the storm.

4. Summary and conclusions
  • The lightning activity in 69 typhoons over the Northwest Pacific during 2005-09 was investigated, with particular focus on the relationships between lightning frequency and typhoon intensity. The 69 typhoons were classified into weak and super typhoons according to their intensity based on the Saffir-Simpson scale, and 32 weak typhoons (categories 1-3) and 37 super typhoons (categories 4-5) were observed. The average flash rate and lightning density varied significantly from one typhoon to another. The maximum lightning density occurred in the category 2 Typhoon Mitag (2007), with a value of 510.42 d-1 (100 km)-2. The minimum was observed in the category 2 typhoon Kong-Rey (2007) with a value of only 1.15 d-1 (100 km)-2. The average lightning density in the inner core of super typhoons is more than twice as large as that for weak typhoons. Both groups of typhoons showed a near-monotonic decrease in lightning density with radius. There was a significant difference between these two groups insofar as that the geometric mean and median lightning density in the inner core of super typhoons were greater than those of weak typhoons. On the contrary, the outer rainband lightning activity showed a reverse tendency. The average lightning density decreased with radius from the typhoon center. Lightning activity was more active in typhoons that made landfall than in those did not.

    Figure 9.  Correlation coefficients between maximum sustained winds and lightning activity. Each point represents one typhoon, and different symbols represent different levels of statistical significance.

    Comparisons of correlations between lightning activity accumulated over 6-h, 12-h, and 24-h intervals and corresponding maximum wind speeds revealed that correlations were stronger at longer time intervals (i.e., 24-h); however, 12-h 600-km correlation coefficients were found to be capable of truly representing the relationship between lightning activity and maximum sustained winds. Mean correlation coefficients between 12-h accumulated flashes within 600 km of the storm center were 0.81 for weak typhoons and 0.74 for super typhoons. Lightning activity peaked before maximum wind intensities in more than 78% (56%) of super(weak) typhoons with a geometric mean lag of 30 (60) h. Thirty-seven out of 69% (54%) of the typhoons showed a positive correlation between lightning activity peak and the maximum wind speed peek with a constant lag time of 24 h, and with a mean correlation of 0.72. Due to the physical relationship between the lightning flashes and updraft, ice particles, and supercooled water within a convective storm (Lang and Rutledge, 2008; Yuan and Qie, 2008; Liu et al., 2011), lightning information could be used as an early indicator of a strengthening updraft within a thunderstorm (Schultz et al., 2009; Qie, 2012), and hence the intensity of typhoon. Regional ground-based total lightning networks [e.g., NLDN, Lightning Detection and Ranging (LDAR) etc.], while highly accurate and useful in terms of regional observation, are limited in range and have very minimal coverage over oceanic regions. Therefore, the WWLLN data, together with the ongoing Geostationary Lightning Mapper (GLM) aboard future geostationary satellite platforms, will help to advance understanding of the lightning activity in TCs, and could be used as an early warning system for the strengthening of typhoons.

Reference

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