EXTENDED RANGE FORECAST OF ATLANTIC SEASONAL HURRICANE ACTIVITY, INDIVIDUAL MONTHLY ACTIVITY AND U.S. LANDFALL STRIKE PROBABILITY FOR 2006

 

We foresee an active Atlantic basin tropical cyclone season in 2006; however, we have reduced our projection for 2006 hurricane activity from our earlier forecasts.  Landfall probabilities for the 2006 hurricane season are projected to be above their long-period averages for the East Coast and near their long-period averages for the Gulf Coast.

 

(as of 3 August 2006)

 

 

 

By Philip J. Klotzbach[1] and William M. Gray[2]

 

with special assistance from William Thorson[3]

 

 

 

This forecast as well as past forecasts and verifications are available via the World Wide Web at http://hurricane.atmos.colostate.edu/Forecasts

Emily Wilmsen, Colorado State University Media Representative, (970-491-6432) is available to answer various questions about this forecast

 

 

 

Department of Atmospheric Science

Colorado State University

Fort Collins, CO 80523

Email: amie@atmos.colostate.edu

 

ATLANTIC BASIN SEASONAL HURRICANE FORECAST FOR 2006

 

 

 

 

 

 

 

POST 1-AUGUST PROBABILITIES FOR AT LEAST ONE MAJOR (CATEGORY 3-4-5) HURRICANE LANDFALL ON EACH OF THE FOLLOWING COASTAL AREAS:

 

1)      Entire U.S. coastline - 73% (average for last century is 52%)

 

2)      U.S. East Coast Including Peninsula Florida - 64% (average for last century is 31%)

 

3)      Gulf Coast from the Florida Panhandle westward to Brownsville - 26% (average for last century is 30%)

 

4)      Above-average major hurricane landfall risk in the Caribbean

 

Notice of Author Changes

 

By William Gray

 

The order of the authorship of these forecasts has been reversed from Gray and Klotzbach to Klotzbach and Gray.  After 22 years (since 1984) of making these forecasts, it is appropriate that I step back and have Phil Klotzbach assume the primary responsibility for our project’s seasonal, monthly and landfall probability forecasts.  Phil has been a member of my research project for the last five years and has been second author on these forecasts for the last four years.  I have greatly profited and enjoyed our close personal and working relationships.

 

Phil is now devoting more time to the improvement of these forecasts than I am.  I am now giving more of my efforts to the global warming issue and in synthesizing my projects’ many years of hurricane and typhoon studies.

 

Phil Klotzbach is an outstanding young scientist with a superb academic record.  I have been amazed at how far he has come in his knowledge of hurricane prediction since joining my project five years ago.  I foresee an outstanding future for him in the hurricane field.  I expect he will make many new forecast innovations and skill improvements in the coming years.  I plan to continue to be closely involved in the issuing of these forecasts for the next few years. 

 

ABSTRACT

 

Information obtained through July 2006 indicates that the 2006 Atlantic hurricane season will be more active than the average 1950-2000 season; however, we have reduced our prediction from our earlier forecasts.  We estimate that 2006 will have about 7 hurricanes (average is 5.9), 15 named storms (average is 9.6), 75 named storm days (average is 49.1), 35 hurricane days (average is 24.5), 3 intense (Category 3-4-5) hurricanes (average is 2.3) and 8 intense hurricane days (average is 5.0).  The probability of U.S. major hurricane landfall is estimated to be about 40 percent above the long-period average.  Landfall probabilities are based upon our expectation for another active season as well as analysis of our new steering current predictors for the East Coast and Gulf Coast of the United States. 

 

We expect Atlantic basin Net Tropical Cyclone (NTC) activity in 2006 to be about 140 percent of the long-term average.  This early August forecast is based on a newly devised extended range statistical forecast procedure which utilizes 57 years of past global reanalysis data. Analog predictors are also utilized. This 3 August forecast reduces our forecast from our early December 2005, early April 2006 and late May 2006 predictions due to small changes in June-July atmospheric and oceanic fields that indicate conditions are less favorable for tropical cyclone development in the tropical Atlantic.  These changes include above-average tropical Atlantic sea level pressure, above-average tropical Atlantic trade wind strength and a decreasing trend in tropical Atlantic sea surface temperatures.  Sea surface temperatures have also risen slightly in the eastern equatorial Pacific. We expect an active hurricane season for the Atlantic basin, but we do not foresee nearly as active a season as was experienced in 2004 and 2005.  Seasonal updates of our 2006 forecast will be issued on 1 September and 3 October.  A seasonal summary and forecast verification will be issued in late November.

 

 

Acknowledgment

 

We are grateful to the National Science Foundation (NSF) and Lexington Insurance Company (a member of the American International Group (AIG)) for providing partial support for the research necessary to make these forecasts.  We also thank the GeoGraphics Laboratory at Bridgewater State College (MA) for their assistance in developing the Landfalling Hurricane Probability Webpage (available online at http://www.e-transit.org/hurricane).

 

The second author gratefully acknowledges valuable input to his CSU research project over many years by former graduate students and now colleagues Chris Landsea, John Knaff and Eric Blake.  We also thank Professors Paul Mielke and Ken Berry of Colorado State University for much statistical analysis and advice over many years. 

 

DEFINITIONS

1        Introduction

 

This is the 23^rd year in which the CSU Tropical Meteorology Project has made forecasts of the upcoming season’s Atlantic basin hurricane activity.  Our forecast team has shown that a sizable portion of the year-to-year variability of Atlantic tropical cyclone (TC) activity can be hindcast with skill exceeding climatology.  These forecasts are based on a statistical methodology derived from 57 years of past data and a separate study of analog years which have similar precursor circulation features to the current season.  Qualitative adjustments are added to accommodate additional processes which may not be explicitly represented by our statistical analyses.  These evolving forecast techniques are based on a variety of climate-related global and regional predictors previously shown to be associated with the forthcoming seasonal Atlantic basin tropical cyclone activity and landfall probability.  We believe that seasonal forecasts must be based on methods that show significant hindcast skill in application to long periods of prior data.  It is only through hindcast skill that one can demonstrate that seasonal forecast skill is possible.  This is a valid methodology provided that the atmosphere continues to behave in the future as it has in the past. 

A variety of atmosphere-ocean conditions interact with each other to cause year-to-year and month-to-month hurricane variability.  The interactive physical linkages between these many physical parameters and hurricane variability are complicated and cannot be well elucidated to the satisfaction of the typical forecaster making short range (1-5 days) predictions where changes in the momentum fields are the crucial factors.  Seasonal and monthly forecasts, unfortunately, must deal with the much more complicated interaction of the energy-moisture fields with the momentum fields. 

We find that there is a rather high (50-60 percent) degree of year-to-year hurricane forecast potential if one combines 4-5 semi-independent atmospheric-oceanic parameters together.  The best predictors (out of a group of 4-5) do not necessarily have the best individual correlations with hurricane activity.  The best forecast parameters are those that explain the portion of the variance of seasonal hurricane activity that is not associated with the other variables.  It is possible for an important hurricane forecast parameter to show little direct relationship to a predictand by itself but to have an important influence when included with a set of 4-5 other predictors. 

In a five-predictor empirical forecast model, the contribution of each predictor to the net forecast skill can only be determined by the separate elimination of each parameter from the full five predictor model while noting the hindcast skill degradation.  When taken from the full set of predictors, one parameter may degrade the forecast skill by 25-30 percent, while another degrades the forecast skill by only 10-15 percent.  An individual parameter that, through elimination from the forecast, degrades a forecast by as much as 25-30 percent may, in fact, by itself, show much less direct correlation with the predictand.  A direct correlation of a forecast parameter may not be the best measure of the importance of this predictor to the skill of a 4-5 parameter forecast model.  This is the nature of the seasonal or climate forecast problem where one is dealing with a very complicated atmospheric-oceanic system that is highly non-linear.  There is a maze of changing physical linkages between the many variables.  These linkages can undergo unknown changes from weekly to decadal time scales.  It is impossible to understand how all these processes interact with each other.  It follows that any seasonal or climate forecast scheme showing significant hindcast skill must be empirically derived.  No one can completely understand the full complexity of the atmosphere-ocean system or develop a reliable scheme for forecasting the myriad non-linear interactions in the full-ocean atmosphere system.

 

 

2        Newly-Developed 1 August Forecast Scheme

We have recently developed a new 1 August statistical seasonal forecast scheme for prediction of Net Tropical Cyclone (NTC) activity.  This scheme was developed on NOAA/NCEP reanalysis data from 1949-1989. It was then tested on independent data from 1990-2005 to insure that the forecast shows similar skill in this later forecast period.  As a rule, predictors were only added to the scheme if they explained an additional three percent of the variance of NTC in both the dependent period (1949-1989) and the independent period (1990-2005)

The pool of four predictors for this new extended range forecast is given and defined in Table 1. The location of each of these new predictors is shown in Fig. 1. Strong statistical relationships can be extracted via combinations of these predictive parameters (which are available by the end of July), and quite skillful Atlantic basin forecasts of NTC activity for the season can be made if the atmosphere and ocean continue to behave in the future as they have during the hindcast period of 1949-2005.  Sixty percent of the variance in NTC is explained over the 1949-2005 period, and on independent data (1900-1948), using the same equations and predictors, 49 percent of the variance is explained.  This is comparable to what would be expected with independent data as a jackknife regression technique on the 1949-2005 period indicated 52 percent of the variance could be explained.   This gives us increased confidence that the new statistical scheme should be of considerable value in the future. 

Our statistical forecast for the other predictors (i.e., named storms, hurricanes) is then adjusted by the predicted statistical value of NTC.  For example, if a typical season has 10 named storms and the predicted NTC value is 120%, the predicted number of named storms for the season would be 12 (10 * 120%).

 

Figure 1: Location of predictors for the 1 August forecast for the 2006 hurricane season.

 

 

 

Table 1: Listing of 1 August 2006 predictors for this year’s hurricane activity.  A plus (+) means that positive values of the parameter indicate increased hurricane activity this year, and a minus (-) means that positive values of the parameter indicate decreased hurricane activity this year.  The combination of these four predictors calls for about an average hurricane season.

 

 

 

Table 2 shows our statistical forecast for the 2006 hurricane season and the comparison of this forecast with climatology (average season between 1950-2000). Our statistical forecast is calling for about average activity this year, which adds additional support for the reduction of our forecast from our previous early-season predictions.

 

Table 2: 1 August statistical forecast for 2006.

 

 

 

2.1     Physical Associations among Predictors Listed in Table 1

 

Brief descriptions of our 1 August predictors follow:

 

Predictor 1.  June-July SST in the Northeastern Subtropical Atlantic (+)

 

(20°-40°N, 15-35°W)

 

Warm sea surface temperatures in this area in June-July correlate very strongly with anomalously warm sea surface temperatures in the tropical Atlantic throughout the upcoming hurricane season.  Anomalously warm sea surface temperatures are important for development and intensification of tropical cyclones by infusing more latent heat into the system (Goldenberg and Shapiro 1998).  In addition, associated with anomalously warm June-July SSTS are weaker trade winds.  Weaker trade winds cause less evaporation and upwelling of the sea surface which therefore feeds back into keeping the tropical Atlantic warm.  In addition, weaker trade winds imply that there is less vertical wind shear across the tropical Atlantic.  Weak wind shear is favorable for tropical cyclone development and intensification (Gray 1968, Gray 1984a, Goldenberg and Shapiro 1996, Knaff et al. 2004).  Lastly, there is a strong positive correlation (~0.5) between anomalously warm June-July SSTs in the subtropical northeastern Atlantic and low sea level pressures in the tropical Atlantic and Caribbean during the heart of the hurricane season.  Low sea level pressures imply decreased subsidence and enhanced mid-level moisture.  Both of these conditions are favorable for tropical cyclogenesis and intensification (Knaff 1997).

 

 

Predictor 2.  June-July SLP in the Tropical Atlantic (-)

 

(10-25°N, 10-60°W)

 

Low sea level pressure in the tropical Atlantic in June-July implies that early summer conditions in the tropical Atlantic are favorable for an active tropical cyclone season with increased vertical motion, decreased stability and enhanced mid-level moisture.  There is a strong auto-correlation (r > 0.5) between June-July sea level pressure anomalies and August-October sea level pressure anomalies in the tropical Atlantic.  Low sea level pressure in the tropical Atlantic also correlates quite strongly (r > 0.5) with reduced trade winds (weaker easterlies) and anomalously easterly upper-level winds (weaker westerlies).  The combination of these two features implies weaker vertical wind shear and therefore more favorable conditions for tropical cyclone development in the Atlantic (Gray 1968, Gray 1984a, Goldenberg and Shapiro 1996). 

 

Predictor 3.  June-July Nino3 Index (-)

 

(5°S-5°N, 90-150°W)

 

Cool sea surface temperatures in the Nino3 region during June-July imply that a La Niña event is currently present.  In general, positive or negative anomalies in the Nino3 region during the early summer persist throughout the remainder of the summer and fall.  El Niño conditions shift the center of the Walker Circulation eastward which causes increased convection over the central and eastern tropical Pacific.  This increased convection in the central and eastern Pacific manifests itself in anomalous upper-level westerlies across the Caribbean and tropical Atlantic, thereby increasing vertical wind shear and reducing Atlantic basin hurricane activity.  The relationship between ENSO and Atlantic hurricane activity has been well-documented in the literature (e.g., Gray 1984a, Goldenberg and Shapiro 1996, Elsner 2003, Bell and Chelliah 2006). 

 

 

Predictor 4.  Named Storm Days South of 23.5°N, East of 75°W (+)

 

Most years do not have named storm formations in June and July in the tropical Atlantic; however, if deep tropical formations do occur, it indicates that a very active hurricane season is likely.  For example, the six years with the most named storm days in the deep tropics in June and July (since 1949) are 1966, 1969, 1995, 1996, 1998 and 2005.  All six of these seasons were very active.  When storms form in the deep tropics in the early part of the hurricane season, it indicates that conditions are already very favorable for TC development.  In general, the start of the hurricane season is restricted by thermodynamics (warm SSTs, unstable lapse rates), and therefore deep tropical activity early in the hurricane season implies that the thermodynamics are already quite favorable for TC development.  Also, this predictor’s correlation with seasonal NTC is 0.53 over the 1949-2005 period, and when tested on independent data (1900-1948), the correlation actually improves to 0.63, which gives us increased confidence in its use as a seasonal predictor. 

 

 

2.2     Hindcast Skill

 

Table 3 shows the degree of hindcast variance (r²) explained by our new 1 June forecast scheme based on our 41-year developmental dataset (1949-1989), our skill on the independent dataset (1990-2005), and our skill over the entire dataset (1949-2005). Note that the scheme generally shows improved skill in the independent dataset, which lends increased confidence in its use.

 

Table 3: Variance (r²) explained for our new 1 August forecast scheme for NTC in the developmental dataset (1949-1989), in the independent dataset (1990-2005), and over the entire dataset (1949-2005).

 

 

 

3        Predictions of Individual Monthly Atlantic TC Activity for August, September and October

A new aspect of our climate research is the development of TC activity predictions for individual months. There are often monthly periods within active and inactive Atlantic basin hurricane seasons which do not conform to the overall season. For example, 1961 was an active hurricane season (NTC of 222), but there was no TC activity during August; 1995 had 19 named storms, but only one named storm developed during a 30-day period during the peak of the hurricane season between 29 August and 27 September. By contrast, the inactive season of 1941 had only six named storms (average 9.3), but four of them developed during September. During the inactive 1968 hurricane season, three of the eight named storms formed in June (June average is 0.5).

We have conducted new research to see how well various sub-season or individual monthly trends of TC activity can be forecast. This effort has recently been documented in papers by Blake and Gray (2004) for August and Klotzbach and Gray (2003) for September. These reports show that it is possible to develop skillful prediction schemes for August-only and September-only Atlantic basin tropical cyclone activity. We have also developed a separate October forecast scheme. On average, August, September, and October have about 26%, 48%, and 17% or 91% of the Atlantic basin's NTC activity. Initial August-only forecasts have now been made by Blake for the last six years (2000-2005), and the verification of these forecasts looks promising. The verification of the September-only and October-only forecasts also appears to show skill.

3.1  Independent August-Only Statistical Forecast

       Figure 2 and Table 4 list the predictors used in the August-only hindcast (Blake and Gray 2004) for each of the seven different forecast parameters. The table also shows hindcast skill for the 51-year period 1950-2000, as well as the independent jackknife hindcast skill over this period. Table 5 gives the predictor values for August 2006. Table 6 gives our independent statistical prediction for August 2006. These predictors indicate well above-average activity for August 2006. The most skillful August predictors, in general, call for a very active month, so we are calling for considerable activity during the month.

 

Figure 2:  Global map showing locations of August-only TC predictors.  Table 4 provides a listing and description of these predictors.  The numbers in the boxes are keyed to the descriptions given in Table 4.  The numbers in parentheses beneath each box indicate how many individual parameters (NS, NSD, etc.) are obtained from each predictor. 

 

Table 4: Listing of predictors chosen for each forecast parameter and the total hindcast variance explained by these predictors for the August-only forecast.  The name and atmospheric parameter utilized in each predictor is given below – where the number is keyed to Fig. 2. 

 

 

Table 5: August 2006 predictors.  The sign of the predictor associated with increased tropical cyclone activity is in parentheses.

 

 

 

Table 6: Independent August-only prediction of 2006 hurricane activity based on Blake and Gray (2004).  August climatology is shown in parentheses. 

 

 

 

3.2  Independent September-Only Statistical Forecast

      Figure 3 and Table 7 list the predictors used in the September-only hindcast (Klotzbach and Gray 2003) for each of the seven different forecast parameters. The table also shows hindcast skill for the 51-year period 1950-2000, as well as the independent jackknife hindcast skill over this period. Table 8 gives the predictor values for September 2006. Table 9 gives our independent statistical prediction for September 2006.  Predictor values for September 2006 are mixed, so our final forecast is calling for slightly above-average activity for the month.

 

Figure 3:  Predictors selected for the end of July forecast of September tropical cyclone activity.  The numbers in each area are keyed to the description given in Table 7.

 

Table 7: Listing of predictors chosen for each forecast parameter and the total hindcast variance explained by these predictors for the September-only forecast.  The name and atmospheric parameter utilized in each predictor is given below – where the number is keyed to Fig. 3. 

 

 

Table 8: September 2006 predictors.  The sign of the predictor associated with increased tropical cyclone activity is in parentheses.