Oy! If there was ever a poster child for “correlation does not equal causation” this is it.
I have no doubt that when we have ENSO events, there are increased winds, resulting in faster flights, but to claim this extends to global scale AGW, especially since they are only using one region of flight path, is preposterous. I wonder if the correlation will hold if they look at say, New York to London, D.C. to London, and Miami to London? And further, what about the albedo effect of contrails from jet exhaust, wouldn’t that count as a negative feedback due to increased solar radiation reflection, possibly negating any GHG forcing contribution? See the photo below.
This paper from this grad student Hannah Barkley is the worst kind of science (just reading her bio sounds like she’s already made up her mind, science be damned), where oceanography students see themselves as meteorologists, and then extend that to seeing themselves climatologists, without looking at the entire picture of what effects jet travel has on the atmosphere.
Air travel and climate: A potential new feedback?
Global air travel contributes around 3.5 percent of the greenhouse gas emissions behind/driving anthropogenic climate change, according to the International Panel on Climate Change (IPCC). But what impact does a warming planet have on air travel and how might that, in turn, affect the rate of warming itself?
A new study by researchers at the Woods Hole Oceanographic Institution and University of Wisconsin Madison found a connection between climate and airline flight times, suggesting a feedback loop could exist between the carbon emissions of airplanes and our changing climate. The study was published in this week’s Nature Climate Change.
“Upper level wind circulation patterns are the major factor in influencing flight times,” says lead author Kris Karnauskas, an associate scientist in WHOI’s Geology and Geophysics Department. “Longer flight times mean increased fuel consumption by airliners. The consequent additional input of CO2 into the atmosphere can feed back and amplify emerging changes in atmospheric circulation.”
The study began when co-author Hannah Barkley, a doctoral student in the MIT-WHOI Joint Program in Oceanography, asked Karnauskas a deceptively simple question. Barkley had noticed a direct flight she took from Honolulu back to the east coast–a route she has flown many times as field scientist–took far less time than expected, and she asked Karnauskas why that might be.
“The first thing that came to mind was, what did the flight-level winds look like that day,” Karnauskas says.
They quickly queried a database of the winds on a NOAA website, selecting for the altitude jets fly at and plugging in the date of Barkley’s flight, and saw that the jet stream that day was extra fast.
“There was just a big swath of extra-fast westerly winds stretching from Honolulu, Hawaii, to Newark,” says Karnauskas. “It was just serendipitous, as if she was part of some kind of golden mileage club where the atmosphere just opens up for you.”
The finding piqued their curiosity about just how unusual Barkley’s experience was, and the simple question led to a study of decades worth of data on flights between Honolulu and the North American West Coast (Los Angeles, San Francisco, and Seattle) by four different air carriers.
Through a database maintained by the Department of Transportation they were able to download departure and arrival data by each airline and the routes traveled–for every single flight that has occurred over the past 20 years. Because the upper level winds blow from west to east, the eastbound leg of a roundtrip flight is generally faster than the westbound leg. After quality controlling the data, Karnauskas plotted the differences in flight times for eastbound and westbound flights and noticed that regardless of the airline carrier, the difference for all the carriers looked the same, over the past 20 years.
Overview map and flight-time variability. a, Airline routes between HNL and LAX, SFO and SEA International Airports superimposed on the annual mean 300-mb zonal wind field (NCEP/NCAR Reanalysis, 1995–2013). The zonal wind field is contoured every 2.5 m s−1. b, Time series of ΔT
“Whatever was causing these flights to change their duration, was the exact same thing, and it wasn’t part of the airline’s decision-making process,” Karnauskas says. The hypothesis was born that climate variability (not just day-to-day weather) determines flight times.
He began digging into massive volumes of atmospheric data to assemble a “composite” snapshot of what the atmosphere looks like on days where the difference in flight times is large, versus small. When he overlaid the plots of the airlines’s differences in flight times with graphs of wind variability at climatic time scales, Karnauskas says he “was pretty blown away.” The plots were virtually identical.
Even after smoothing out the seasonal differences (the jet stream is always a little stronger in winter and weaker in summer), leaving him with the year-to-year variability, the match held up almost perfectly. Flight-level wind speed explained 91 percent of the year-to-year variance. The result also pointed toward the influence of El Niño – Southern Oscillation (ENSO) – a phenomenon Karnauskas has studied extensively.
As the temperature of the equatorial Pacific Ocean rises and falls, like a pebble in a pond, atmospheric waves are set off toward the higher latitudes of both hemispheres, where they change circulation patterns.
“I came into this study, thinking this is going to be a weird junket that is totally unrelated to anything I do, but it really led me back to El Niño, which is what I do.”
Karnauskas found that just by looking at the state of the tropical Pacific Ocean, he could predict what the airlines’ ΔT had been. For this so-called hindcast, “we’re talking about anomalies happening down at the equator that are affecting the atmosphere in such a spatially broad way, that it’s probably influencing flights all around the world.”
Their analysis also determined that the difference in flight times between eastbound and westbound flights on any given route didn’t cancel each other out; rather there was a residual. In other words, when an eastbound flight became 10 minutes shorter, the corresponding westbound flight became 11 minutes longer.
According to Karnauskas, it took some “obsessive drilling into the data to find that residual, and at face value it seems very minor.” The net additional flying time for a pair of eastbound and westbound flights between, for example, Honolulu and LA is only a couple minutes for every 10 mph speedup of the prevailing wind. But, he says, “the wind really fluctuates by about 40 mph, so multiply those couple of minutes by each flight per day, by each carrier, by each route, and that residual adds up quickly. We’re talking millions of dollars in changes in fuel costs.”
Once the researchers had proven that the atmospheric circulation affects how long planes are in the air, they began to wonder about the impact climate change would have on the airline industry.
According to the study, there are approximately 30,000 commercial flights per day in the U.S. If the total round-trip flying time changed by one minute, commercial jets would be in the air approximately 300,000 hours longer per year. This translates to approximately 1 billion additional gallons of jet fuel, which is approximately $3 billion in fuel cost, and 10 billion kilograms of CO2 emitted, per year.
“We already know that as you add CO2 to the atmosphere and the global mean temperature rises, the wind circulation changes as well–and in less obvious ways,” says Karnauskas.
Based on what they had learned about the airlines’ residual flight times, the researchers explored how climate models predict the atmospheric circulation to change and to make some estimates of how much more CO2 will be emitted by the airline industry in the face of those changes. Currently, global climate models to not incorporate inputs from air travel, so this potential feedback is missing from our state-of-the art models.
Karnauskas believes this information could be useful for the airline industry to more efficiently plan for future fuel costs, reallocate fuel resources, refine the predicted flight durations for their customers, and better manage all the inconveniences and manpower related to flight delays.
While this study focuses on a very small subset of the total global airline traffic, Karnauskas has plans to expand this study to include all US and European flights – a massive undertaking. To work with such large datasets, Karnauskas has been granted access to Azure, a powerful cluster of networked computers operated by Microsoft, under a special research grant jointly offered between Microsoft Research and the White House Climate Data Initiative.
In reflecting on the findings of this project and the simple question Barkley had initially asked, Karnauskas says one of the biggest surprises is that the airline industry doesn’t seem to be aware of the flight time patterns.
“The airline industry keeps a close eye on the day-to-day weather patterns, but they don’t seem to be concerned with cycles occurring over a year or longer,” he says. “They never say, ‘Dear customer, there’s an El Niño brewing, so we’ve lengthened your estimated flight duration by 30 minutes.’ I’ve never seen that.”
###
As is typical with many of these shonky papers, they don’t provide a link to it in the press release, lest anyone read it for themselves and see how ridiculous the press release claim is. So I sought it out myself.
Coupling between air travel and climate
Kristopher B. Karnauskas, Jeffrey P. Donnelly, Hannah C. Barkley & Jonathan E. Martin
Nature Climate Change (2015) doi:10.1038/nclimate2715
The airline industry closely monitors the midlatitude jet stream for short-term planning of flight paths and arrival times. In addition to passenger safety and on-time metrics, this is due to the acute sensitivity of airline profits to fuel cost. US carriers spent US$47 billion on jet fuel in 2011, compared with a total industry operating revenue of US$192 billion. Beyond the timescale of synoptic weather, the El Niño/Southern Oscillation (ENSO), Arctic Oscillation (AO) and other modes of variability modulate the strength and position of the Aleutian low and Pacific high on interannual timescales, which influence the tendency of the exit region of the midlatitude Pacific jet stream to extend, retract and meander poleward and equatorward1, 2, 3. The impact of global aviation on climate change has been studied for decades owing to the radiative forcing of emitted greenhouse gases, contrails and other effects4, 5. The impact of climate variability on air travel, however, has only recently come into focus, primarily in terms of turbulence6, 7. Shifting attention to flight durations, here we show that 88% of the interannual variance in domestic flight times between Hawaii and the continental US is explained by a linear combination of ENSO and the AO. Further, we extend our analysis to CMIP5 model projections to explore potential feedbacks between anthropogenic climate change and air travel.
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I would like to know what data were used to determine flight times. Airline schedules / flight results, as far as I know, are based/published on gate to gate times, and not wheels up to touchdown. So… flying to LAX from Phoenix will take longer than it “should” not only due to prevailing westerly winds, but also because of increased taxiing time at LAX (and more air traffic at LAX as well.) I don’t know – maybe this all cancels out, but until we know what data was used, it’s impossible to determine validity of the study.
Spot on as well
Better cancel that upcoming Paris gab fest then, no point in exacerbating the problem unnecessarily when video confrencing is readily available.
“Karnauskas has been granted access to Azure, a powerful cluster of networked computers operated by Microsoft, under a special research grant jointly offered between Microsoft Research and the White House Climate Data Initiative.”
Oh I see: we’ll have volumes and volumes of data that are meaningless…
interesting that Microsoft would name a “cluster of networked computers” after a WWII German crypto code
Exactly what one would expect of Bill Gates.
Maybe the paper should have quoted Representative Debbie Stabenow as a reference:
http://wattsupwiththat.com/2009/08/11/global-warming-creates-volatility-i-feel-it-when-i%e2%80%99m-flying/
In climate science, correlation causes causation.
Part of the results are highly plausible — that ENSO and AO together explain 88% of inter-annual variation in the average difference in flight times east-west vs. west-east. Well, duh. That’s simply to say that these two factors explain most of the inter-annual variation in the jet stream’s path and speed, at least between Hawaii and the U.S. west coast.
The paper’s claims for the importance of its results, however, are highly implausible — that annual fuel costs of $47 billion could vary by $3 billion depending on the state of ENSO etc., when total flight times clearly do not vary by anywhere near the same proportion. Moreover, fuel usage is less than proportional to flight times, as flight times only effect the lower amount of fuel needed to maintain airspeed and altitude, not the fixed amount of fuel needed to raise the airplane to altitude. Short-haul flights involve proportionately more of the latter sort of fuel usage.
I’m not clear what assumptions or claims the paper makes about how global-level climate change affects the jet stream’s path and speed. I gather that that is held out as an issue for future research, while the present paper focuses on the effects of ENSO and AO.
“…the present paper focuses on the effects of ENSO and AO.”
Still, they must pay obeisance to their false god and utter his name.
“The impact of climate variability on air travel, however, has only recently come into focus, primarily in terms of turbulence . Shifting attention to flight durations, here we show that 88% of the interannual variance in domestic flight times between Hawaii and the continental US is explained by a linear combination of ENSO and the AO. ”
So they study the influence of natural variability on flight times.
problems?
Then they ask the question.. what if it gets warmer..and will that effect airlines
pretty fricking basic.
Many businesses now are looking at what a warmer future may mean to their business.
[And as you are fond of pointing out, one data point is not the world, i.e. Honolulu. If they were doing real science, they’d test some other routes for the posited CO2 connection. But they didn’t, and instead interpolated their opinion:
“we’re talking about anomalies happening down at the equator that are affecting the atmosphere in such a spatially broad way, that it’s probably influencing flights all around the world.”
No issues with the wind speed and El Nino, as you say, pretty fricking basic, CO2/AGW causation, not so much. -Anthony]
that is extrapolated rather than interpolated – rarely is interpolation warranted, but extrapolation is a WAG
Steven,
I’ll take that response to mean that you think this is good science……….or that you are suggesting that we should think that it is…….or both.
Steven is a bit cryptic at times.
“Many businesses now are looking at what a warmer future may mean to their business.”.
Since we are talking about changes of less than 0.1 C per decade, most of these companies are not going to be in business by the time this makes any appreciable difference- how many companies that were around 100 years ago are still in business?
The planes that are in use now (many of them over 20 years old) will be replaced with more modern planes. New planes, such as the Gulfstream G650 have a much higher maximum altitude – 51,000 ft. Compare this to older planes that fly at 39,000ft. Planes equipped with winglets can fly at 42,000 ft – usually about the jet stream.
What the heck is the matter with you Mosh? Anyone who has even a slight knowledge of aerodynamics knows what effect warmer weather has on airlines. I have more than a slight knowledge of aerodynamics having a BS in aeronautics. But this stuff is so simple and so basic I don’t understand why it is being talked about at all, the airlines fully understand it, and a grad student’s paper is of no use to them at all. That is what we complaining about, what make this paper publishable ? it is so elementary as to be useless.
Tom – You mean like someone who has to ask someone this question. –“Barkley had noticed a direct flight she took from Honolulu back to the east coast–a route she has flown many times as field scientist–took far less time than expected, and she asked Karnauskas why that might be.” ???
Might wonder why they do not know the definition of Climate – generally taken as the average over 30 years. Now let’s apply 20 years worth of data to check it out.
Want to make a bet that this paper ends up being counted as another study that proves the consensus? Say what you want about what it’s saying, but I know where I’m putting my wager.
“No issues with the wind speed and El Nino, as you say, pretty fricking basic, CO2/AGW causation, not so much. -Anthony]”
causation of what?
1. you already admit that C02 will cause warming.
2. The question is how much.
basically you have never disputed the causation, you just dispute the amount of warming.
Since the science isnt settled it could be high or it could be low.
It is totally reasonable to explore the problem space. That is, it is totally reasonable and rational to explore the presumed effect under the assumption that the warming is small or medium or high.
We do this type of analysis all the time
We dont know, for example, how tax cuts will specifically impact the deficit going forward.
We have models. We use them all the time.
you dont know how, for example, your retirement portfolio will play out, but its totally reasonble and rational to look at a variety of scenarios.
So, there is nothing wrong with assuming causation, you yourself accept it. We see in the lab that c02 increases plant growth. In the lab of the world we see the same thing— sometimes.
We see in the lab that C02 restricts cooling via radiation.. In the lab of the world we see the same thing.
So, its not the causation you object to, its the level of warming. But the level of warming is uncertain.
Its not settled last time I looked. So its reasonable and rational to look at a variety of possible futures.
[Lead sentence: “Global air travel contributes around 3.5 percent of the greenhouse gas emissions behind/driving anthropogenic climate change, according to the International Panel on Climate Change (IPCC)”, implying it air travel affects itself. You can’t attribute causation of the specific emissions from Jet planes to driving ENSO and winds. And, they didn’t test the theory to see if it holds up elsewhere. That’s my issue. And please don’t try to lecture me about things I already know. Lately, you’ve adopted a “holier than thou” attitude, much like some people we know. – Anthony]
“… commercial jets would be in the air approximately 300,000 hours longer per year. This translates to approximately 1 billion additional gallons of jet fuel, which is approximately $3 billion in fuel cost, …”
Wow! Commercial jets actually get the equivalent of 6 mpg! Four of us should buy one (from an IPCC delegate) and carpool – er, jetpool – to work. We’d actually save on gas.
Ok, they’re a little off on that one. But, that’s ok; even if a commercial jet doesn’t get 6 mpg we’d save on fuel anyway because they’re way off on the price of fuel too. The spot price for jet fuel hasn’t exceeded about $1.80 per gallon since December 2014. Last time I checked $3.00 and $1.80 are not the same thing. (But give it time.)
Oh, well. These numbers are good enough for climate work. And, also for Obama’s White House Climate Data Initiative. And people wonder why the economy’s still in the doldrums 6 years in?
Oh!!! Up near the stratosphere there are very stong winds. Imagine that? Guess we found that out in WW2 when the B-29 folks almost ground to a halt with 150+ mph head winds up there above 25,000 feet. And the Empire at that time was exploiting that phenom to send fire ballooons to the U.S. Sheesh, that was 70 years ago.
Where do these folks get “vetted” before checking into all the “science” about stuff like weather, atmosphere and stuff like that? Guess it’s all “peer” review, and the peers are just as clueless.
Gums sends…
It is all due to relativity and the coriolis effect. I have discovered proof of this but the is not enough space on my airline ticket to write it down.
Nice catch. You should write that up for peer review. You could get published in the journal that
LewinskyLewandowsky just published in.I would like to see a graph of turbulance over time…
With the methods used in the paper or ones like them one could conclude the data supported one of these two regimes:
http://frontierscientists.com/wp-content/uploads/2013/06/JetStream_ArcticOscillation.jpg
With data that is older, we could learn about past wind patterns. This paper reminds me of the Jennifer Francis work on zonal NH wind flows.
What an idiotic piece of junk research. This self-important genius seems to think the airlines, flight schools, and private pilots are somehow missing the boat on considering jet streams, wind patterns, and weather when flying from here to there. I would love to be a fly on the wall in the backroom where pilots gather. They wouldn’t use this (Cough! Hack! Gag!) dissertation in an outhouse.
http://www.skybrary.aero/index.php/Jet_Stream
Trouble is the WH Climate Data Initiative provided the funding for this silliness and ‘they’ will use this kind of stuff to set regulations. It’s the same thinking that’s behind setting fuel economy standards for over the road trucks: As if the Owner Operators and trucking companies have no self interest in maximizing their own fuel economy. Society is to be governed by professors and their graduate students – god help us.
Yep, and see one of my previous posts.
As a professional pilot for many years, I can assure you that all of us still standing are extremely familiar with all kindsa “weather” and atmospheric phenom and stuff like mountain waves amd rotors on downwind side of mountains and………
I can see it now when at the bar.
Gums, ” Hey, some climate dweeb has just now discovered the jet stream.”
Spectre, ” No kidding?”
“Yeah, seems like they also found out about contrails, too. They might even reflect the sun rays back into space and cut back on “global warming” a bit.”
“Wow, imagine that?”
Gums sends….
P.S. I am losing track of the decimal points but if we humans are only cranking out 4% of the annual Co2, and the jets are only cranking out 3.5 % of the 4%, then what;s the big deal? I would imagine that bovine farts and termites contribute more that that, ya think?
My dearly departed mother considered becoming a professional pilot (fat chance back then) and took at least one University level aerodynamics class. I have her class notes. Incomprehensible to me but fascinating nonetheless.
Pamela Gray July 13, 2015 at 2:55 pm
The trouble is there is a tendency not to refer to those in the doing professions about what they think or to provide advice. There was a court case in the UK about an airfield’s operations and the aviation expert acting for the airfield was barred from giving evidence because as an expert he was considered biased.
Pamela Gray July 13, 2015 at 5:42 pm
Not sure if it is of interest but please look up Barbara Harmer and her interesting background.
All that work for nothing. When teleportation technology comes on line, right after wind turbines replace coal, gas, hydro, and nuclear power plants, we won’t give a rat’s patootie about which way the wind blows.
“Beam me up, Scotty!”
Wtf?!!!
I guess they didn’t factor in the actual number of flights in any given year, nor the increasing efficiency of jets or any other factors, nor any other variable, except flight times. What kindergarten nonsense. I can not believe that this passes for “science”.
If they wanted to do some real science based on Meteorology 101, they could have studied the effect of the weaker jet streams from the warming of the higher latitudes. When we warmed in the 1980’s/90’s, the warming was focused in the higher latitudes. Jet streams are a result of the meridional temperature gradient. Weaken that and you weaken the jet stream.
Don’t just pick one route and make this climate change connection based on something that might effect that region…………from El Nino’s and apply it everywhere.
There’s an entire planet, much of which has weaker jet streams from the beneficial warming of the higher latitudes. What about the rest of the planet and flights?
What a sad, sad circumstance this whole CAGW is in seducing kids into this cult of conformity so that they are trained to prepare such utter drivel basically for the publicity and self justification of their department or organisation. It has sweet F.A. to do with science.
That is nothing. Try crossing Kansas going west
http://geology.com/state-map/maps/kansas-state-map.gif
with a 1991 Volvo two-axle tractor with a set of 14′ high doubles. Then you are getting into some serious torture.
https://www.google.com/search?q=1991+volvo+2+axle+tractor&client=opera&hs=BMU&source=lnms&tbm=isch&sa=X&ved=0CAgQ_AUoAmoVChMI8Ky67p7ZxgIV0ymICh1O1QDj&biw=910&bih=440#tbm=isch&q=volvo+with+a+set+of+doubles
Please, if any one really cares deeply about headwinds, make sure no one gets on the highway with less than a 440 Puddy Tat.
Ship by rail.
Yeah, then you can just get it when you get it.
Might this be the paper, or a substantial part of it?
http://marrella.meteor.wisc.edu/Karnauskas_etal_2014.pdf
Anthony, I think I may have found the paper
I read a “study” this weekend, I believe it was on msn that places with lots of crime also had lots of guns.
From this they concluded that the presence of guns cause crime.
This is typical climatology. These people pick a subject they know nothing about and jump to foolish conclusions based on their comprehensive ignorance of all the factors involved.
There is a very, very simple reason why eastbound flights take longer when you correct for the wind speed.
Why? All eastbound flights fly further than the westbound flights.
Steven Mosher will be able to tell us why … it’s pretty frickin’ basic.
Lol! Spit our pizza and red wine! Looks like someone died on my puter screen!!!!
Pamala friend. Please think FAA. All of this is moot. No one will sanction a fuel load based on the “hope” of a tail wind. Nor arrival times based on the wind.
This is a classic example of poor mentoring. Hannah Barkley should have been redirected to some “experts” at one of the airports to learn how things work and why things work.
But then it is the blind leading the blind.
Pamala, you mentioned your late Mother. Earlier this year I was cleaning out my late mother’s house. I found my Dad’s pilots license. He was blind in one eye.. As am eye, pun intended. It was an eye opener to me; no pun this time
I know I’m opening up Pandora’s box but oh well.
michael
Most of my trips via air have been coast to coast. Arrival times take into account the conditions of the jet stream present when you board. Your advanced ticket will say one thing. When you get on the plane the pilot says another thing.
Pilots will also adjust their altitude to get the best time given the circumstances.
Bingo.
Its up to the pilot and the air traffic controller.
But then if these people get their paws on the FAA I don’t see myself traveling by air.
Oh and I have traveled to Europe several times. As a student and just for fun.
michael
Tailwinds, headwinds?
I flew the “lites”, but the “heavy” folks actually changed their course to exploit the jet stream over the Pacific.
So one day I faced about a hundred + knot head wind and got worried about gas. Requested the wind at FL400 and dude says light and variable. So trop was just a thousand feet above me and I was cleared to FL400 and sure enough – no wind!
Gums sends…
How’s this for hypocrisy?
http://www.flyertalk.com/forum/25108558-post43.html
Not sure of his point. Am sure he ain’t no pilot.
Can anyone name a variable other than wind speed that might affect the duration of a flight at a particular altitude and why?
TALT Eastbound
http://www.turbulenceforecast.com/maps/atlantic_east.gif
TALT Westbound
http://www.turbulenceforecast.com/maps/atlantic_west.gif
Curvature of the earth?
Oo oo oo .. air density?
Exactly. Aircraft performance depends on air density. That is why El Niño/La Niña appear in the figure from the paper – they alter the temperature profile of the atmosphere. Less dense air, airplanes go faster (assuming they are not limited by engine performance).
No. I can’t
There is no difference between going east or west except for wind direction.
But then you talk about “affect the duration at a particular altitude”. Which is very different.
On average, over many flights, an airplane flying westbound will take off directly towards its destination and land straight ahead into the westerly prevailing wind at its destination. An airplane flying eastbound will take off into the westerly prevailing wind and fly many miles turning though 180° to head towards its destination. On arrival in the vicinity of the destination it will fly many miles past the airport and turn through 180° to approach the airport into the prevailing westerly wind.
On average, therefore, eastbound flights will fly many more miles on the same route as a westbound flight because of the requirement to land into wind which on planet earth prevails from the west.
The problem the authors of the paper have is that they only have departure and arrival times. They do not know how much time was spent in the airport environment during the approach or the departure.
This whole analysis is utterly meaningless because of the uncertainty in measuring flight durations. There is at least three different ways to define flight times, none of which is actually relevant in this case. There is “off blocks/on blocks”, from take off power on until leaving the active runway after landing and from (nose) gear expansion until (nose) gear compression. The last is the one usually recorded by onboartd recording systems. However for this kind of analysis to be meaningful, time spent in holding patterns should be deducted, and also corrections applied because a pilot will often depart from an optimum flight profile in order to conform to a “slot” time at a busy destination airport.
Just a guess but the engine power outputs may vary somewhat dependent upon air density which itself is also dependent on temperature in addition to altitude. However the turbine airflow characteristics may be able to compensate to prevent power loss at higher altitudes; in which case the reduced air density at high altitudes may afford less wind resistance which would then improve performance.
I’ll admit I’m really guessing here.
Jet aircraft performance improves dramatically with altitude. Colder air improves engine efficiency, thinner air decreases drag. This effect is so strong that the optimum profile for short flights is actually climbing half-way and let down at flight idle the other half.
Hi Billy
E.M.P. (sorry just being evil) Take your pick. ANYTHING that will shutdown a airport or air corridor. Take your pick. Last year my son and I were delayed by over 24 hours due to great lake effect lightning. Its not just aircraft in the air.
Okay you did say “altitude” Stacking aircraft. Or just plain “can’t get there from here!”
again take your pick.
michael
michael
Coming in on a Wing and a Prayer
aka.414th Bomb Squadron
Yep. Those bombers could take a beating and keep flying. Amazing engineering.
You might like this article about where to reinforce bombers to keep them flying while absorbing hits.
http://www.ushahidi.com/2013/09/27/what-wwii-bombers-tell-us-about-the-marginalized-and-vulnerable/
Pam found the paper. They used Wheels Up to Wheels Down for their times.
I have a hunch that may introduce some of the variation they refer to in their notes but the key issue is what they say about the use of the models:
“Analyzing the predicted response of 300-mb zonal winds to increased radiative forcing
105 by 34 GCMs included in the Coupled Model Intercomparison Project, Phase 5 (CMIP5) 10 paints
106 an uncertain future.”
In other words, the models don’t provide a clue.
As for the notes:
“i Bureau of Transportation Statistics, Research and Innovative Technology Administration, U.S.
Department of Transportation.
ii MIT Global Airline Industry Program, Airline Data Project
(http://web.mit.edu/airlinedata/www/Revenue&Related.html).
15
iii The BTS statistic “AirTime” is used, which is wheels up to wheels down.
iv The sensitivity of westbound flight durations to u300 is greater than that of eastbound flights of
the same route, so an increase in u300 lengthens the westbound flight by slightly more than it
shortens the eastbound flight resulting in a net increase in total flying time (“T). The average
sensitivity of “T to u300 for the flights analyzed is 0.38 minutes flying time per m s-1 zonal wind.
v Bureau of Transportation Statistics, Research and Innovative Technology Administration, U.S.
Department of Transportation.
vi National Air Traffic Controllers Association.
vii Assume burn rate 1 gal per second. Varies depending on aircraft and many other variables.
viii Assume emissions coefficient 9.6 kg CO2 per gal (eia.gov/environment/emissions/co2_vol_mass.cfm”
If the primary author is correct in her recollection regarding Hannah, I consider Hannah’s question rather lacking in basic atmospheric science acumen for a graduate student involved in Woods Hole. I think she should be properly chastised as should her professors.