With reference to flood records there are proxies such as varved sediments. The Lake Amersee record has a flood record going back 450 years that shows flood frequencies to be significantly greater during the little ice age. See Czymzik et al, 2010, Water Resources Research, vol 46. doi:10.1029/2009WR008360

Paul,
My view is that flooding is a tricky issue, because it's not a direct climatological consequence of a warmer world; it's a potential consequence of changes to precipitation. As I understand it, an emergent property of climate models is that relative humidity remains constant. If this does occur, then we'd expect the water vapour content of the atmophere to increase at about 7%/K and precipitation to increase at 2%/K. However, one expectation is that more precipitation will ocur in what are currently heavy precipitation events, so we'd expect an increase in the intensity and frequency of extreme precipitation events. This could lead to increased flooding, but that's a much more complex issue.

There are, however, a couple of things to bear in mind. One way that there could be little change in precipitation is if RH increases with warming. However, given that water vapour is a greenhouse gas, this would imply higher climate sensitivity. Alternatively, relative humidity reduces as we warm. This would suggest that climate sensivity is on the lower side, but would suggest an even greater increase in precipitation, with potential implications for flooding.

RR,
That doesn't necessarily follow from what you quoted. I will add that I was called a git here for apparently being patronising ;-)

aTTP,

I agree. Flooding is a very tricky issue. Not least because it is affected so much by land use changes, modern building etc. that all impact on storage in the unsaturated zone etc. Long rainfall records and proxies for rainfall amount would be very useful here. Having said that flooding events, at least as recorded at Lake Amerssee seem to be greatest during the little ice age.

Setting aside climate models one might rationalise this as being the result of increased temperature gradients between the source regions for water vapour and the sites of precipitation. The distribution of net evaporation-precipitation peaks strongly in the tropics where evaporation from the ocean dominates. I'm not sure how much the tropics are warming but possibly less than high latitude regions. Therefore one might expect the flux towards these regions to decrease somewhat due to a lowered temperature gradient. Interestingly, in the paper I referenced the authors ascribe the changes to solar effects on precipitation.

In the absence of good quality data I'm not impressed by generalisations from climate models such as a 7%/K increase in water vapour and 2%/K increase in precipitation, particularly when describing regional patterns. It is too easy to say 'is consistent with' etc. which really isn't strong evidence. Are there any models run for say the little ice age that show how the intensity and frequency of intense precipitation events might vary? I don't know.

I think we both agree that absent good quality data we might go round debating this for a long long time. Hence my call for support for very high quality monitoring and proxy studies. I would say that as I'm an isotope geochemist!

In the absence of good quality data I'm not impressed by generalisations from climate models such as a 7%/K increase in water vapour and 2%/K increase in precipitation

Oh, and when I said "increase" and "decrease" above, I meant relative to RH remaining constant.

RR,
I don't know the answer. I'm simply pointing out that what Julia Slingo said does not immediately imply that we have a longer record. It could be that that is the length of the reliable record. I don't think it follows that the record has to be longer than 248 years.

What I will add, though, is that the expectation is not necessarily that we will see events that we've never seen before. The expectation is that we will see an increase in the frequency and intensity of these events. Of course, we might see an event that that has never occured before in any record, but that we can find evidence for events in the past that match extreme events today is not some kind of evidence against AGW.

aTTP,

it's not immediately intuitive to me what the effects would be. As far as the water cycle is concerned we're actually talking about comparatively small changes in temperature and temperature gradients as well as possible RH. Moreover, RH changes might be different in different regions. The effect this has on precipitation, at least to me is not clear and I'm not sure it is to anyone else beyond statements such as 'is consistent with'.

I certainly wasn't arguing for both increased climate sensitivity and precipitation!

I certainly wasn't arguing for both increased climate sensitivity and precipitation!

Floods are obviously associated with storms and there is much evidence that storminess was greater in the LIA than at present. Evidence comes from weather reports at the time (commonly associated with shipwrecks) and in the form of surviving physical evidence like increased sand transport on land (eg Brecklands) or on the coast. Lamb, for example, believed wind speeds were much higher then than at present.

Much of the evidence is detailed in Brian Fagan's fine book The Little Ice Age.

aTTP says....."the rate at which it has warmed has probably been faster than at any other time during the Holocene."

the data to support that speculation are very tenuous - similar rates of increase have probably occurred several times earlier in the Holocene.

For example:-
50 year mean temperatures over central England rose about 1.25ºC between 775 and 650 ybp ( Lamb 1966a)
Chinese temperatures rose 2ºC between 850 and 1150 AD ( Hsieh 1976)
New Zealand cave temperatures rose 1ºC between 1350 and 1450 AD.

Temperature rises comparable or faster than the rise in the last 150 years have occurred at least five times since the 10.3 ky event. The rise following the cold nadirs of the 10.3, 9.3 and 8.2 ky events was almost certainly larger and faster than that which has occurred in the last 150 years . Indeed most cooling events recorded in the NORTHGRIP dO18 data are followed by rapid temperature rises.

Paul Dennis

I suggested a polynomial because a variety of lines of evidence, from monastery and estate records through freezing of ponds and the River Thames suggest a cooling trend through the 2nd millennium in Western Europe, followed by warming as the Industrial Revolution gathered pace in the latter 1800s.

A linear regression would not detect a pattern of cooling followed by warming, A 1st order polynomial might.The CET is very noisy data, so it may be difficult to distinguish a possible LIA from the noise.

I was reading a short précis of Richard Alley's 2000 paper and was struck by one omission. How big are the 95% confidence limits on his temperatures? Is the GISP2 data good enough to reliably distinguish the +/- 0.5C variations of the "Minoan Warm Period" and "Roman Warm Period" from the longer term cooling trend?

Radical Rodent, interesting that you should link to the Great Storm of 1703. One of the Royal Navy heroes to survive that was Sir Cloudesley Shovell, one of history's more preposterous names. The 1707 Scilly Naval Disaster, saw Shovell smash 4 mighty ships into the Scilly Isles, with much loss of life, including his own.

The Fleet Wreck was partially due to bad weather for a few days, compounding navigational errors, until they made landfall at night, where no land was supposed to be.

This led the Admiralty and Houses of Parliament to launch a competition for someone to build an accurate Marine Chronometer, very belatedly won by John Harrison, of 'Longitude' fame, along with 'Only Fools and Horses'.

The Beaufort Scale, a method of assessing the wind's force by observation was devised in 1805, but not introduced as a 'standardised' measurement until 1830. Whether this was due to more stormy weather during the LIA, or about Britain ruling the waves by defining how unruly they were, I don't know.

Charting of the seas and oceans of the World by the Royal Navy was carried out in about this time (mid third of the 1800s) and I presume that with knowledge of 'trade winds' gathered over centuries, some patterns of world weather and circulation were formed.

Charted depths of water on many charts of the world are still using the depths recorded 150 years ago. Tectonics have shifted a bit since then, but charts are not normally updated until after the first ship has bumped into the 'error'.

RR,

Is this a first?

On what evidence? All the data we have to date is that the warming has caused a decrease in the frequency and intensity of these events; why is there the conviction that this is going to change, and soon?

Proof that climate scientists have been wrong before, is NOT evidence against an increase in the intensity and frequency of such events.

Martin A

Thanks for the information on 2nd order polynomials.

Looking at your graphs, I would estimate the 95% confidence limits for your regression lines at +/-2.5C.

I would agree that there is little chance of pulling useful trend information out of CET.Anything between no change and +/-5C would fit within those limits.

Mike Jackson

By eye, there looks to be an increase in named storms, but no real change in the number of hurricanes or major hurricanes.

If the US has not had a hurricane in ten years that suggests

a) that the hurricanes are tending to go elsewhere, perhaps staying offshore.

and/or

b) that the USA has been lucky.

if there i8s a staw to be clutched at, EM will reach for it. I suggest he relabels himself as Ecdysiast Man, always eager to display his lack of credentials.

"luck" is one of those quantities that EM will no doubt define with a formula involving made up numbers, like most of the formulae he writes.