tropical forecasting final

what months are SSTS warmest

August & Sept

convective to mesoscale

0-100km minutes to hours thunderstorms, tornadoes, dust storms, squall lines

planetary scale

10,000km monsoons, el Nino, MJO weeks/months/years

sub-seasonal oscillations

2 weeks - 3 months MJO

tropical storm winds

34-63kt

threshold for high seas

8 feet

MJO phases and 850mb wind anomalies

8 phases westerly wind anomalies in eastern tropical Pacific associated with phases 8, 1, 2 easterly wind anomalies in eastern tropical pacific are associated with phases 4, 5, 6

variables of the MJO

850 hPa zonal wind 200 hPa zonal wind outgoing longwave radiation OLR (cloudiness)

Saharan Air Layer

A mass of very dry, dusty air which forms over the Sahara Desert

what is generally the busiest period for genesis of tropical cyclones from AEWs? how about in the western caribbean?

AEW: early to mid-september caribbean: october

decadal oscillations

AMO

seasonal oscillations

AO, NAO

AEWs form as instabilities on the

African Easterly Jet form ahead of troughs

annual oscillations

ENSO

ENSO

El Niño Southern Oscillation 2-7 year climate cycle characterized by SST and pressure anomalies across the Pacific 3 phases- El Nino (warm), La Nina (cold), and neutral atmospheric "see-saw" signal back and forth across Pacific

how do forecasters distinguish between a Monsoon trough and the ITCZ?

ITCZ: northern and southern hemisphere trade winds converge monsoon: trade winds and seasonal monsoonal winds converge

what is the general direction of the winds near the surface between 0-30N and what are they called

NE/E - easterly trade winds

should MEOWs and MOMs be considered forecasts?

NO they should be considered as risk maps they are a composite of storms

Probabilistic Storm Surge

P-surge storm surge probabilities based on NHC official advisories real-time forecast accounts for uncertainty in: track/tandfall location, size, forward speed, intensity available 48 hrs before arrival of TS winds

forces on a wind around a hurricane

PGF - inward centrifugal force - outward coriolis force- to the right of wind

arctic oscillation

a see-saw in pressure between the arctic and northern mid-latitudes. Similar to the North Atlantic oscillation, but confined to the middle and higher latitudes. Time scale of decades but its phases are irregular. phases correlate directly with NAO

definition of a tropical cyclone

a warm-core, non-frontal synoptic-scale cyclone, originating over tropical or subtropical waters, with organized deep convection and a closed surface wind circulation about a well-developed center

why do tropical storms need to be triggered?

above boundary layer, RH is 60-70% downdrafts can bring drier air to the surface, impeding new clouds need to overcome "resistance" by moistening in the middle troposphere

how is the atmosphere cooled in deep convection

absorption and scattering of solar radiation cooling during downdrafts

scatterometer

active sensor that measures ocean surface winds by measuring backscatter to determine roughness of surface

cold cloud processes

aggregation- ice crystals sticking together deposition- WV changes to ice riming- ice crystals grow by colliding into supercooled water droplets, which freeze onto them

define rapid intensification

an increase in the maximum sustained winds of a tropical cyclone of at least 30 kt in a 24 hour period (NHC) hard to predict!

define wind shear

any change in wind speed and direction along a straight line

synoptic scale

around 1000km days tropical cyclones

cyclone phase space looks at what 2 parameters

asymmetry vs symmetry warm core vs cold core (thermal wind)

factors affecting storm surge

central pressure (only minimal) intensity (wind speed) forward speed size (radius of max winds) angle of approach width and slope of shelf local features- bays, rivers, islands, etc

relative radii of cloud particles

cloud condensation nucleus: 0.1 micron typical cloud droplet: 10 microns borderline cloud/rain: 100 microns typical raindrop: 1000 microns

deep convection

clouds extend well above freezing level heavy precipitation, thunder, lightning strong updrafts and downdrafts frozen recip melts at freezing level anvils of ice particles cooling and drying stabilizes air beneath clouds

Atlantic Multidecadal Oscillation AMO

coherent mode of natural variability of SSTs in Atlantic average anomaly of SSTs

how is the atmosphere warmed in deep convection

condensation = release of latent heat sinking in adjacent region (adiabatic warming)

internal dynamics that govern TC motion

convective asymmetry mesoscale systems coupling of upper/lower level circulations outflow layer instability

how does the MJO affect TC activity

convectively enhanced phase of MJO increases TC activity in Indian Ocean, Australian, NW Pacific and NE Pacific basins possible correlation btw more major hurricanes and MJO phase 1-3 (these phases relate to lower vertical shear anomalies vs high anomalies in phase 5-7)

what is data assimilation

data assimilation aims at accurate re-analysis, estimation, and prediction of an unknown, true state by merging observed information into a model -find some way to blend a model "first guess" with observations to best estimate the truth

P-3 lower fuselage radar

doppler radar below plane horizontal view

surface wind maximum is located

downshear

strongest updrafts on ________ side of eye

downshear left

expendables

dropsondes, buoy

forecast model types

dynamical models statistical models global vs regional ensemble

North American Monsoon

early june to late july provides a lot of Arizona's annual rainfall and 60% of northern Mexico's

Walker circulation

easterly trade winds on either side of ITCZ warm waters pushed to west pacific warm pool increased precipitation above WPWP depth of warm waters is greater over warm pool (deep thermocline)

Madden-Julian Oscillation

eastward-moving anomalies of precipitation and westerly wind (and clouds and pressure) traverses planet in the tropics, returns starting point approx. every 30-60 days intraseasonal (multiple events per season) modeling/forecasting is HARD

ENSO and TCs

el nino: more hurricanes in east pacific (less wind shear) and less in Atlantic (more shear) la nina: few hurricanes in east pacific (more shear, drier), more hurricanes in Atlantic (less shear)

peak hurricane szn

end of august - mid sept

2 phases of MJO

enhanced rainfall (convective) suppressed rainfall

as air parcels rise, they

entrain air from the environment this entrained air is unsaturated, cooler than air parcel

how does entrainment affect the parcel's buoyancy

entrainment reduces buoyancy in updraft

external influences that govern TC motion

environmental "steering" flow- main factor subtropical highs, approaching troughs, interactions with nearby TCs

scales of airborne sampling

environmental structure (moisture content) vortex structure (eyewall) convective structure microphysical structure

3 types of factors that influence TC motion

external influences (main) internal dynamics interactive dynamics

tropical vs extratropical cyclone

extratropical derive energy from temp gradient, tropical derive energy from latent heat and sensible heat at the air-sea interface

what are the typical spatial scales for the following types of structure in a tropical cyclone: eyewall, rainbands, cirrus outflow? what are the corresponding words for these scales?

eyewall: 1km-ish, convective scale rainbands: 10-100 kms, mesoscale cirrus outflow: 100-1000s km, synoptic scale

does a TC move faster or slower when it transitions to an extratropical cyclone?

faster- increased forward motion heavy rainfall and strong winds remain

IPCC extreme events expected

fewer cold days and nights more warm days and nights more land regions where the number of heavy precip events has increased than where it has decreased extreme sea levels have increased since 1970

how/why does landfall weaken a TC?

friction causes spin-down moisture availability is low- dry air near surface intrudes TC circulation decrease in surface evaporation rate and latent heat interaction begins when outer rainbands reach land

hurricane genesis location

from africa in aug/sept gulf/west caribbean in october

tail doppler radar

gives vertical winds

global vs regional models

global are the whole world, have lower resolution, parameterized physics such as clouds regional are just certain regions, higher resolution, explicitly resolving clouds and thunderstorms inconsitent physics with "parent" domain

what is the name of the horizontal balance in a mature hurricane?

gradient wind balance

intermediate convection

heavy showers ex. cumulus congestus does not extend far enough vertically to contain ice rain produced by collision-coalescence- warm rain

OLR anomalies

high = convectively supressed, less rainstorms low = cloudy convectively active, lots of rainstorms

under what circumstances can tropical storms form?

high RH high thermodynamic instability low wind shear enough vorticity (not on equator, not too far north) substantial potential intensity

Atlantic hurricanes vs global warming

higher rainfall rates more intense on average (medium confidence) uncertain how the annual number will change tropical cyclone surge levels should increase with sea level rise (all else equal)

confident effects of global warming

higher storm surge increased rainfall rates

primary circulation

horizontal flow (tangential) gradient and thermal wind balance symmetric for strong storms

challenges of ensemble forecasting

how to provide accurate probabilistic forecasts (will it actually hit miami 30% of the time) how to provide probabilistic info that is easy for decision-makers to interpret (when to inform the public) even when info is correct, how does one make a yes/no decision based on a probability!

cold clouds- 3/4 stages in the lifecycle of a liquid cloud droplet

ice crystals and supercooled water droplets co-exist (<0C) ice nucleation- hard, fewer nuclei than liquid nucleation condensation- WV deposition grows ice cloud droplets growth- ice crystals grow faster than water droplets

secondary circulation

in-up-out radial and vertical forced by heat and angular momentum sustains primary circulation against friction and radiative cooling also symmetric

as a tropical cyclone moves northward... it encounters

increased temperature gradients increased moisture gradients increased vertical wind shear decreased SSTs and increased SST gradients increased coriolis force

visible imagery

indicated amount of solar radiation reflected albedo, thickness

IFEX and 3 goals

intensity forecast experiment forecasts, nowcasts, research

interactive dynamics that govern TC motion

interaction between primary circulation and vorticity gradient

extratropical transition of a tropical cyclone ways

landfall moving over cooler water increased vertical wind shear (can have dry air intrusion) absorbed by extratropical low/trough

nose doppler radar

least important

datum

like a reference point for storm surge 20 feet of storm surge = 20 feet above datum mean seal level MLLW MHHW

predictions of TCs with climate change

low confidence in basin-scale projections of changes in the intensity and frequency of TCs we have no clue!! modes of climate variability that have led to variations in the intensity, frequency, and structure of TCs across the globe are very likely to continue influencing TCs

shallow TCs are steered by

lower-layer flow ex 500-850hPa mean wind

MJO and Atlantic TCs

lower-tropospheric MJO signal is lost when it hits the Atlantic, but upper level (200mb) divergence may remain strong this leads to reduced vertical wind shear and enhanced vertical motion --> more TCs!

large scale influences on TCs

madden julian oscillation ENSO north atlantic oscillation atlantic multidecadal oscillation (AMO) climate change

what serves as the trigger for TCs?

many TCs develop from African Easterly Waves first seen in April/May, continue until Oct/Nov

ensemble forecasting

many forecasts! reveals possible range of scenarios can make quantitative probabilistic estimates (30% chance it will hit Miami)

MEOW

maximum envelope of water product available on SLOSH pre-computed composite of the maximum storm surge for all surge simulations over a given set of parameters use when you can narrow down to specific scenarios (category, speed, direction, initial tide)

MOMs

maximum of the MEOWs pre-computed used to design evacuation zones and when uncertainty is high

define intensity of a TC

maximum surface wind speed at any point, sustained over a 1 minute period (from NHC)

forecast model cycle

model "first guess" --> observational preparation --> data assimilation --> initial conditions

more shear =

more sensitivity (to other factors that could destroy the storm)

how does deep convection occur

need to destabilize environmental air heating/moistening lifting from approaching a cold front, sea breeze, outflow boundary surface friction leads to convergence in boundary layer --> L, upward flow

where is there a net gain/loss of radiation

net gain in tropics, net loss near poles

are eyewalls vertical

no, stadium effect, there's a slope

is shear all bad?

no, there could be an optimal amount of shear that helps outflow

shallow convection

non-precipitating "trade wind cumuli", 1-2km high

how have monsoon criteria changed

now everyone wants their own monsoon, there's even a "north american monsoon" but there is no winter component so it's debatable

warm clouds- 4 stages in the life cycle of a liquid cloud droplet

nucleation- cloud droplet air is supersaturated and condenses) condensation- droplets grow when more WV condenses on them collision/coalescence- droplet becomes sufficiently heavy so they fall and sweep up other droplets on the way down break up- the droplets break up as they fall

air parcels must overcome ___ and be brought to ____ for deep convection to occur

overcome CIN, reach LFC

convection: dry thermals

parcels do no reach level of saturation mostly in boundary, RH<100% no clouds, invisible on satellite

passive vs active sensors

passive- receive emissions produced by Earth's atmosphere (visible, IR, microwave) active- sensor transmits a pulse and this signal is reflected/transmitted/scattered by Earth's atmosphere (precipitation radar, cloud profile radar, scatterometer)

different ways to make ensembles

perturb initial conditions to create appropriate "spread"- uses same model perturb model physics to represent uncertainty and errors in model- uses same model ensembles of different models!

AO positive phase

polar low pressure system (polar vortex) over the arctic is stronger stronger upper level westerlies cold arctic air is forced to remain farther north mid-latitude storm track is further north

microwave imagery

polar orbiting satellites measure radiances in microwave wavelength bands temperature profiles retrieved from radiances passive MIMIC (what we use to look at eyewall development)

AO negative phase

polar vortex is weaker weaker upper-level westerlies cold arctic air can push further south into USA mid-latitude storm track remains further south

AMO and TCs

positive AMO = warmer SSTs = more TCs

NAO and tropical cyclones

positive phase- more southern Azores high --> more zonal TC tracks into gulf of mexico negative phase- more northern Azores high --> more tracks recurving western North Atlantic

classical criteria for a monsoon

prevailing wind shifts 120 degrees btw Jan and July average frequency of prevailing wind > 40% speed of mean wind exceeds 3 m/s pressure patterns satisfy a steadiness criterion

potential storm surge flooding map

provides a quantitative risk assessment for decision makers shows height above ground that water could reach depicts reasonable worst-case scenario 10% chance of exceedence

rainfall in slow vs fast moving storms

rainfall is NOT correlated with intensity! slower moving storms produce more rain over a specific location

ET process

reduced sensible and latent heating, loss of warm core inner core loses symmetric appearance broad asymmetries, increase in area development of fronts faster forward speed

how does moving over cooler water affect TC

reverse of positive feedback loop already discussed; reduction of total heat flux into atmosphere --> decrease in intensity--> weaker heat and moisture fluxes

does the tropospheric air rise or sink at the equator? at 30N

rise at the equator sinks at 30N

how is sea level in the eye compared to the rest of the sea

sea level is higher in the eye bc low pressure above allows water to be up higher

North Atlantic Oscillation

sea-level pressure difference btw subtropical (Azores) high and subpolar low

how does large vertical wind shear affect storms

shear forces dry, low energy air from environment into the core at mid-levels (ventilation) convective towers are tilted which weakens convection (storm loses circular symmetry) concentration of heat becomes difficult

slower vs faster forward speed compared to storm surge

slow speed = more inland penetration fast speed = higher maximum

the atmosphere regulates itself in response to

solar radiation earth's rotation differences in ocean and land surface forcing natural and anthropogenic changes

SHIPS

statistical model, 5 day forecasts of intensity shear, SST, potential intensity, relative humidity, etc

deep layer mean

steering motion is the mean wind in the 250-850hPa (deep) layer

SFMR

stepped frequency microwave radiometer detects microwave radiation from foam at the sea surface (surface winds)

"southern oscillation"

strength of easterly trade winds modified by swings of mass and pressure across the basin higher pressure in east = stronger easterlies higher pressure in west = weak easterlies not well known if this southern oscillation is a cause or effect of el nino, but the 2 are intimately coupled

la nina phase

stronger easterlies, warm pool and convection concentrated in west cooler SSTs in east Pac thermocline slope across pacific increases - more upwelling along South American coast

positive NAO

sup-polar low and subtropical high are stronger than normal stronger pressure gradient/jet stream more northern storm track wet north america

negative NAO

sup-polar low and subtropical high are weaker than normal weaker pressure gradient dry US

IR imagery

surface and cloud top temperatures highest and coldest cloud tops appear as blue

remote sensors

tail doppler radar SFMR

el nino --> la nina transition

takes a lot longer easterly trade winds must re-establish and drive the upwelling off the South American coast

vortical hot towers

tall and skinny circulating storms morph with mesoscale convective system to help it grow form into mesoscale convective vortex

tangential vs radial wind

tangential = swirling, azimuthal radial = inward vertical = up/down

in the tropopause, what happens to pressure and temp as we increase altitude

temp and pressure decrease pressure always decreases

storm surge models are strongly dependent on

the accuracy of the meteorological input

significant wave height

the average height of the highest one-third of the waves

Mean lower low water MLLW and MHHW

the average of the peak low/high tides

what causes a monsoon?

the seasonal oscillation of solar heating with net heating in the summer hemisphere, which leads to migration of the equatorial trough and the ITCZ the differential heating between land and ocean and the resulting pressure gradient the swirl introduced to the winds by earth's rotation moisture processes and convection

how are the tropics defined

the tropics encompass the region of relatively low surface pressure located between high pressures belts in the subtropics. This definition emphasizes the dynamic nature of atmospheric circulations as a response, primarily, to solar heating of the earth, and, secondarily, to other factors such as surface properties.

storm surge warning

there is a danger of life-threatening inundation from rising water moving inland from the shoreline somewhere within the specified area generally within 36 hours life-threatening situation

storm surge watch

there is the possibility of life-threatening inundation from rising water moving inland from the shoreline somewhere within the specified area generally within 48 hours

how do eyewall replacement cycles affect rapid intensification

they bring intensification to a halt almost half of tropical cyclones are undergoing rapid intensification as they begin an ERC

why is it hard to predict hurricane changes

they're rare events climate models are limited attribution is difficult because of all the other large-scale oscillations and factors we don't know the accurate count of storms from earlier years, especially shorter ones or ones in the middle of the Atlantic

limitation of scatterometer

thick gaps in coverage contamination by rain

forecast improvements over time

track forecasts have constantly improved, less error intensity forecasts are barely better than they used to be

how have TC tracks already changed

translational speed is down by 10% storms are slower from 1949

TAFB

tropical analysis and forecast branch

multi-cell thunderstorms

updrafts and downdrafts support each other new cells form from lifting air from gust front of adjacent cell longer lasting, bring heavier precipitation

dynamical models

use "primitive equations" of fluid dynamics and physics of the atmosphere, coupled to ocean ex. GFS, ECMWF, HWRF give u a picture

data assimilation 101 with T

use least squares theory to produce minimum error

statistical models

use weighted combinations of parameters relevant to intensity change ex. ships just numbers

vertical wind shear

vector difference between 200hPa and 850hPa wind vectors often expressed as a magnitude

environmental influences on TCs

vertical wind shear ingestion of dry air outflow interactions air-sea interactions

el nino phase effects across globe

warm and dry west pacific & Australia wet and warm south america warm north america wet over california

hurricane intensification process

warm core builds as water condenses this release of heat induces stronger azimuthal (swirling) winds central pressure drops- increasing radial pressure gradient stronger inflow and updrafts stronger winds = more water vapor exchange from ocean --> building warm core

favorable conditions for hurricane intensification

warm ocean deep convection low wind shear moist middle troposphere enhanced upper-tropospheric outlfow

single cell thunderstorms

warm, buoyant plume of rising air creates clouds single updraft and downdraft mature stage had heavy downdraft with rain and hail downdraft cuts off updraft and storm extinguishes itself, leaving only anvil

el nino phase

weaker easterlies --> warm pool spreads out warmer SSTs in east pacific increased surface convergence over central/eastern pacific increases precipitation thermocline gets deeper in east, shallower in west pac

what is the general direction of the winds in the upper troposphere at around 30N

westerly (from west to east)

la nina --> el nino transition

westerly wind burst in the western pacific leads to quick transition wind burst can be initiated by any large-scale phenomenon (MJO) transitions usually occur in spring

width and slope of shelf compared to storm surge

wide & gentle slope = the worst - water just rolls up and huge waves hit homes narrow and sharp slope = barrier waves must overcome to reach land, much less storm surge

radius of max winds compared to storm surge

wider = worse acts like a big wall and just pushes it all onto land

in-situ data

wind, pressure, temp in flight recorded

when is the enso signal usually the strongest?

winter! december, jan, feb

what is the typical height (in km) of the tropopause in the tropics vs that in the mid-latitudes?

~20km in the tropics, <16km difference is usually greater than 3-4km