Modeling rainfall and flooding

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In summary, there has been an increase in extreme precipitation events and heavy precipitation events due to global warming and greenhouse gases. This is because greenhouse gases have increased the atmosphere's ability to hold water vapor, leading to more intense storms rather than a higher frequency of storms. While the exact extent of the impact of greenhouse gases on extreme precipitation events is not fully quantified, there is evidence from various studies that suggests a link between rising global temperatures and the increase in extreme precipitation. This trend is expected to continue in the future, leading to an increase in flood risk and potential destruction caused by hurricanes.
  • #1
Xnn
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I will not comment about earthquakes and tsumani's.
However, there has been an increase in extreme precipitation
events due to global warming/greenhouse gases.

Basically, greenhouse gases have increased the ability
of the atmosphere to hold water vapor. It is not that
there are more storms than in the past, instead they are more intense.

http://www.ipcc.ch/pdf/assessment-report/ar4/wg1/ar4-wg1-chapter3.pdf


Tropical cyclones making landfall in China are
a small fraction of the total storms, and no obvious long-term
trend can be discerned (He et al., 2003; Liu and Chan, 2003;
Chan and Liu, 2004). However, Emanuel (2005a) and Webster
et al. (2005, 2006) indicated that the typhoons have become
more intense in this region, with almost a doubling of PDI values
since the 1950s and an increase of about 30% in the number of
category 4 and 5 storms from 1990 to 2004 compared with 1975
to 1989.

Substantial increases are found in heavy precipitation
events. It is likely that there have been increases in the number
of heavy precipitation events (e.g., 95th percentile) within many
land regions, even in those where there has been a reduction in
total precipitation amount, consistent with a warming climate
and observed significant increasing amounts of water vapour
in the atmosphere. Increases have also been reported for rarer
precipitation events (1 in 50 year return period), but only a few
regions have sufficient data to assess such trends reliably.

Precipitation has generally increased over land north of
30°N over the period 1900 to 2005 but downward trends
dominate the tropics since the 1970s. From 10°N to 30°N,
precipitation increased markedly from 1900 to the 1950s, but
declined after about 1970. Downward trends are present in the
deep tropics from 10°N to 10°S, especially after 1976/1977.
Tropical values dominate the global mean. It has become
significantly wetter in eastern parts of North and South America,
northern Europe, and northern and central Asia, but drier in the
Sahel, the Mediterranean, southern Africa and parts of southern
Asia. Patterns of precipitation change are more spatially
and seasonally variable than temperature change, but where
signifi can't precipitation changes do occur they are consistent
with measured changes in stream flow.

Droughts have become more common, especially in the
tropics and subtropics, since the 1970s. Observed marked
increases in drought in the past three decades arise from more
intense and longer droughts over wider areas, as a critical
threshold for delineating drought is exceeded over increasingly
widespread areas. Decreased land precipitation and increased
temperatures that enhance evapotranspiration and drying
are important factors that have contributed to more regions
experiencing droughts, as measured by the Palmer Drought
Severity Index. The regions where droughts have occurred
seem to be determined largely by changes in SSTs, especially
in the tropics, through associated changes in the atmospheric
circulation and precipitation. In the western USA, diminishing
snow pack and subsequent reductions in soil moisture also
appear to be factors. In Australia and Europe, direct links to
global warming have been inferred through the extreme nature
of high temperatures and heat waves accompanying recent
droughts.

Tropospheric water vapour is increasing. Surface specific
humidity has generally increased after 1976 in close association
with higher temperatures over both land and ocean. Total
column water vapour has increased over the global oceans by
1.2 ± 0.3% per decade from 1988 to 2004, consistent in pattern
and amount with changes in SST and a fairly constant relative
humidity. Strong correlations with SST suggest that total
column water vapour has increased by 4% since 1970. Similar
upward trends in upper-tropospheric specific humidity, which
considerably enhance the greenhouse effect, have also been
detected from 1982 to 2004.
 
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  • #2
Xnn said:
I will not comment about earthquakes and tsumani's.
However, there has been an increase in extreme precipitation
events due to global warming/greenhouse gases.

Basically, greenhouse gases have increased the ability
of the atmosphere to hold water vapor. It is not that
there are more storms than in the past, instead they are more intense.

http://www.ipcc.ch/pdf/assessment-report/ar4/wg1/ar4-wg1-chapter3.pdf
That may be, but I don't believe the language you used (highlighted) is supported by the IPCC. They make a great many observations, and express concern:
IPCC AR4 3.8.1 said:
There is increasing concern that extreme events may be changing in frequency and intensity as a result of human influences on climate
but do not state the causation as a fact.
 
  • #3


Theory and modeling both predict that hurricane intensity should increase with
increasing global temperatures and we already know that rising levels of CO2
cause rising global temperatures. However, the degree to which the rise
in extreme precipitation events and storms are due to the rise in greenhouse
gases has not been quantified. There are after all, natural variations some
of which span decades.

Here is a letter in the Journal Nature defining an index for potential destructiveness
of hurricanes that factors in both duration and intensity. There has been a marked
increase since the 1970's.

http://www.nature.com/nature/journal/v436/n7051/full/nature03906.html

Theory and modelling predict that hurricane intensity should increase with increasing global mean temperatures, but work on the detection of trends in hurricane activity has focused mostly on their frequency and shows no trend. Here I define an index of the potential destructiveness of hurricanes based on the total dissipation of power, integrated over the lifetime of the cyclone, and show that this index has increased markedly since the mid-1970s. This trend is due to both longer storm lifetimes and greater storm intensities. I find that the record of net hurricane power dissipation is highly correlated with tropical sea surface temperature, reflecting well-documented climate signals, including multi-decadal oscillations in the North Atlantic and North Pacific, and global warming. My results suggest that future warming may lead to an upward trend in tropical cyclone destructive potential, and—taking into account an increasing coastal population—a substantial increase in hurricane-related losses in the twenty-first century.
 
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  • #4


Here's another paper that has found an increase in floods during the 20th century
due to global warming with the expectation that the trend will continue.

http://www.nature.com/nature/journal/v415/n6871/full/415514a.html

Radiative effects of anthropogenic changes in atmospheric composition are expected to cause climate changes, in particular an intensification of the global water cycle with a consequent increase in flood risk. But the detection of anthropogenically forced changes in flooding is difficult because of the substantial natural variability; the dependence of streamflow trends on flow regime, further complicates the issue. Here we investigate the changes in risk of great floods—that is, floods with discharges exceeding 100-year levels from basins larger than 200,000 km2—using both streamflow measurements and numerical simulations of the anthropogenic climate change associated with greenhouse gases and direct radiative effects of sulphate aerosols. We find that the frequency of great floods increased substantially during the twentieth century. The recent emergence of a statistically significant positive trend in risk of great floods is consistent with results from the climate model, and the model suggests that the trend will continue.
 
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  • #5


Xnn said:
Here's another paper that has found an increase in floods during the 20th century
due to global warming with the expectation that the trend will continue.

http://www.nature.com/nature/journal/v415/n6871/full/415514a.html
What?

Please point out the floods it has cited, the specific number of floods, location, and how they positively linked this to "global warming" by ruling out any possibility of natural occurance. Such as natural or man made changes to the terrian that could cause flooding. Why don't I find anything about an increase of actual floods?

This appears to be nothing more than maybe, might, possibly, perhaps...

Where are you reading this stuff you stated as fact?
 
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  • #6


Thanks for the pointer to Emanuel; I'd heard of it like everyone else but never reviewed it.
Xnn said:
Theory and modeling both predict that hurricane intensity should increase with increasing global temperatures and we already know that rising levels of CO2 cause rising global temperatures. However, the degree to which the rise in extreme precipitation events and storms are due to the rise in greenhouse gases has not been quantified.
I don't have access to the full text at the moment, perhaps Emanuel does quantify? But without some kind of quantification of the effect, of what use is the prediction? Suppose (and I have no idea) the effect is predicted to be a cyclone wind speed increase of 1 part in 10000 for a 10 deg K rise in SST?

Xnn said:
There are after all, natural variations some
of which span decades.

Here is a letter in the Journal Nature defining an index for potential destructiveness
of hurricanes that factors in both duration and intensity. There has been a marked
increase since the 1970's.

http://www.nature.com/nature/journal/v436/n7051/full/nature03906.html

Here are some comments on Emanuel 2005 from W. Grey, submitted to Nature in response:
Gray said:
The near universal references to the above paper by most of the major US media outlets and blogs since Katrina and Rita made US landfall requires a response from a few of us who study hurricanes. Having been involved with hurricane research and forecasting for nearly 50 years, I feel I have an obligation to offer comments on this paper's findings which, in my view, are not valid. This paper concludes that global tropical cyclone net power dissipation (or friction times wind) taken to be proportional to the sum of each cyclone's individual 6-hour track period maximum wind speed (Vmax^3) has undergone large (more than doubled) increases over the last 30 years. The author associates these frictional energy dissipation increases with rising mean sea surface temperatures (SSTs) and implies that these SST increases may, in part, be related to human activity. If true, this is a very important finding that has great relevance as regards to the globe's future climate and future hurricane destruction. But, the author's apparent "blockbuster" results and his interpretation of his calculations are not realistic.
http://arxiv.org/ftp/physics/papers/0601/0601050.pdf

If you are interested, Emanuel informally answers some of his critics on his MIT website here.
Skip down to:
5. Empirical Evidence for Increasing Tropical Cyclone Activity (and a response to its critics)
http://wind.mit.edu/~emanuel/anthro2.htm
 
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  • #7


Evo said:
What?
Why don't I find anything about an increase of actual floods?

This appears to be nothing more than maybe, might, possibly, perhaps...

Where are you reading this stuff you stated as fact?

Notice the last sentance of the abstract reads as follows:

The recent emergence of a statistically significant positive trend in risk of great floods is consistent with results from the climate model, and the model suggests that the trend will continue.

Seems clear enough and no maybe about it.

Don't have the full paper with all the details (it's available, but not free,).
Have emailed the author for more infomation.
 
  • #9


Xnn said:
Here's a link to a free version of the Nature article on increased risk of great floods:

http://www.gfdl.noaa.gov/bibliography/related_files/pcm0201.pdf

Notice it is a 2002 paper.

Wonder if all the recent flooding has made the correlation stronger.
What do you mean by "all the recent flooding"? Are there data or news reports showing global flooding since 2002 are above normal?
 
  • #10


Xnn said:
Notice the last sentance of the abstract reads as follows:

The recent emergence of a statistically significant positive trend in risk of great floods is consistent with results from the climate model, and the model suggests that the trend will continue.

Seems clear enough and no maybe about it.
That's not saying that there "has been an increase in floods", it says "risk". As in "it hasn't actually happened", but there is a chance. That's not the same thing. :smile: This is just a prediction, not fact.
 
  • #11


I've been quickly through the Milly 2002 paper since Xnn's post. Part of the paper concerns model predictions for the future, which is off topic for this thread, and part of the paper concerns observations of existing food data. I'm having some trouble with the latter.

So far I have this:
Milly et al and others in their references admit that that there's no detectable signal in small floods, so they look at major 100-year flood events, that is events that have a probability of 1% on a given year. They globally look at 29 large watershed sites spanning the 135 yr period 1865 to 1999. That would give them a maximum of 3915 site-years, but the data does not cover the full time period for all sites and they end up with 2066 site-years. From that data, if flooding were normal, we would expect to observer 20.6 100-year floods. They look at all this data, and find there were exactly 21 100-year events globally. I don't follow how that finding produces the abstract statement "We find that the frequency of great floods increased substantially during the twentieth century". Anybody? I'm still re-reading the 2nd half of Milly.
 
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  • #12


mheslep said:
I've been quickly through the Milly 2002 paper since Xnn's post. Part of the paper concerns model predictions for the future, which is off topic for this thread, and part of the paper concerns observations of existing food data. I'm having some trouble with the latter.

So far I have this:
Milly et al and others in their references admit that that there's no detectable signal in small floods, so they look at major 100-year flood events, that is events that have a probability of 1% on a given year. They look at 29 large global watershed sites spanning the 135 yr period 1865 to 1999. That would give them a maximum of 3915 site-years, but the data does not cover the full time period for all sites and they end up with 2066 site-years. From that data, if flooding were normal, we would expect to observer 20.6 100-year floods. They look at all this data, and find there were exactly 21 100-year events globally. I don't follow how that finding produces the abstract statement "We find that the frequency of great floods increased substantially during the twentieth century". Anybody? I'm still re-reading the 2nd half of Milly.

It is not the existence of 21 events that is the basis of the quoted sentence, but the fact that those 21 events occur disproportionally in the second half of the record.

Extract:
Under the assumption that flood events were independent outcomes of a stationary process, we used binomial probability theory to determine a probability of 1.3% of having 16 or more of 21 events during the second part of the record. For observations from an extratropical subset of the basins (see below), the corresponding probability is 3.5%, for 7 out of 8 flood events in the second half of the record. Supplementary analyses for shorter return periods (2–50 yr) did not reveal significant trends, but 200-yr flood frequency increased significantly.

The hypothesis in the paper is explicitly described in the final paragraph as "tentative", but the statistical property they measure seems clear enough. The open issues identified in the paper are described in the final paragraph as follows:
Our detection of an increase in great-flood frequency and its attribution to radiatively induced climate change are tentative. The frequency of floods having return periods shorter than 100 yr did not increase significantly. Potentially significant effects of measurement non-stationarity are not easily assessed. The forced signal and unforced variability in the model contain errors of unknown magnitude. Absent from the model are forcings such as solar variability, volcanic activity, land-cover change9, and water-resource development10, and potential biospheric feedbacks such as CO2-induced stomatal closure11 and water-stress-induced root extension12. Especially evident from our study are the needs for improvements in simulation of tropical hydroclimate and continued commitment to stream-gauging programmes worldwide.

(added in edit) This paper is not only about making predictions. It is also about a measured increased in "great" floods, and that is the portion most relevant to the thread. The key finding is: We find that the frequency of great floods increased substantially during the twentieth century. This is not an increase since 2001 of course, but it does have a clear connection to a topic of increasing disasters in present times. The development of discussion into a larger view of "present times" seems a pretty normal kind of thread development; but I would not object to locking the thread if it is to be limited so tightly as to preclude even this kind of associated discussion. I agree that the OP was not well founded.
 
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  • #13


Evo said:
That's not saying that there "has been an increase in floods", it says "risk". As in "it hasn't actually happened", but there is a chance. That's not the same thing. :smile: This is just a prediction, not fact.
From the paper (emphasis mine):
Our detection of an increase in great-flood frequency and its attribution to radiatively induced climate change are tentative. The frequency of floods having return periods shorter than 100 yr did not increase significantly. Potentially significant effects of measurement non-stationarity are not easily assessed. The forced signal and unforced variability in the model contain errors of unknown magnitude. Absent from the model are forcings such as solar variability, volcanic activity, land-cover change, and water-resource development, and potential biospheric feedbacks such as CO2-induced stomatal closure and water-stress-induced root extension.​

How did this paper get published in Nature?
 
  • #14


D H said:
From the paper (emphasis mine):
Our detection of an increase in great-flood frequency and its attribution to radiatively induced climate change are tentative. The frequency of floods having return periods shorter than 100 yr did not increase significantly. Potentially significant effects of measurement non-stationarity are not easily assessed. The forced signal and unforced variability in the model contain errors of unknown magnitude. Absent from the model are forcings such as solar variability, volcanic activity, land-cover change, and water-resource development, and potential biospheric feedbacks such as CO2-induced stomatal closure and water-stress-induced root extension.​

How did this paper get published in Nature?
I was really surprised at this also.
 
  • #15


sylas said:
It is not the existence of 21 events that is the basis of the quoted sentence, but the fact that those 21 events occur disproportionally in the second half of the record.
Yes thanks, on re-read I see that point now.

Extract:
Under the assumption that flood events were independent outcomes of a stationary process, we used binomial probability theory to determine a probability of 1.3% of having 16 or more of 21 events during the second part of the record. For observations from an extratropical subset of the basins (see below), the corresponding probability is 3.5%, for 7 out of 8 flood events in the second half of the record. Supplementary analyses for shorter return periods (2–50 yr) did not reveal significant trends, but 200-yr flood frequency increased significantly.

The hypothesis in the paper is explicitly described in the final paragraph as "tentative", but the statistical property they measure seems clear enough. The open issues identified in the paper are described in the final paragraph as follows:
Our detection of an increase in great-flood frequency and its attribution to radiatively induced climate change are tentative. The frequency of floods having return periods shorter than 100 yr did not increase significantly. Potentially significant effects of measurement non-stationarity are not easily assessed. The forced signal and unforced variability in the model contain errors of unknown magnitude. Absent from the model are forcings such as solar variability, volcanic activity, land-cover change9, and water-resource development10, and potential biospheric feedbacks such as CO2-induced stomatal closure11 and water-stress-induced root extension12. Especially evident from our study are the needs for improvements in simulation of tropical hydroclimate and continued commitment to stream-gauging programmes worldwide.

(added in edit) This paper is not only about making predictions. It is also about a measured increased in "great" floods, and that is the portion most relevant to the thread.
Edit: Yes, though I question whether that changes the answer to the query: What is the statistical significance of the additional floods in the latter part of the date? That is, given a coin that I test for randomness, if I toss the coin 20 times and came up with 10 heads, and also found that I observed only 4 heads in the first 10 tosses and 6 heads came in the last 10 tosses, am I justified in making in conclusions about the randomness of the coin somehow changing during the second ten tosses?

Edit: I see the paper comment's on 'stationarity'; I'm rusty on stationary processes but I believe that pertains to my question above.

The key finding is: We find that the frequency of great floods increased substantially during the twentieth century.
Its the statement published in the abstract, I'm not sure it should be called the 'key' finding, given the conclusion.
 
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  • #16


D H said:
From the paper (emphasis mine):
Our detection of an increase in great-flood frequency and its attribution to radiatively induced climate change are tentative. The frequency of floods having return periods shorter than 100 yr did not increase significantly. Potentially significant effects of measurement non-stationarity are not easily assessed. The forced signal and unforced variability in the model contain errors of unknown magnitude. Absent from the model are forcings such as solar variability, volcanic activity, land-cover change, and water-resource development, and potential biospheric feedbacks such as CO2-induced stomatal closure and water-stress-induced root extension.​

How did this paper get published in Nature?
I don't see any problem with publishing a narrow observation of one aspect a complex system, given that the authors freely admit that there may be a number of various drivers for observations as they do in the conclusion you posted above.

HOWEVER, in my view the stand-alone and qualitative statement in the abstract, "We find that the frequency of great floods increased substantially during the twentieth century", should have had more context or should have been dropped. For instance, as I read the paper, it would be equally appropriate make the following statement in the abstract: "We find that the frequency of 100 year floods was as expected over the observed 139 year time period (X% confidence), with an increasing frequency trend during the twentieth century". Mentioning the 100 year flood level and the time period immediately draw the readers attention to the tentativeness of the data set.
 
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  • #17


mheslep said:
Yes thanks, on re-read I see that point now.Edit: Yes, though I question whether that changes the answer to the query: What is the statistical significance of the additional floods in the latter part of the date? That is, given a coin that I test for randomness, if I toss the coin 20 times and came up with 10 heads, and also found that I observed only 4 heads in the first 10 tosses and 6 heads came in the last 10 tosses, am I justified in making in conclusions about the randomness of the coin somehow changing during the second ten tosses?

Edit: I see the paper comment's on 'stationarity'; I'm rusty on stationary processes but I believe that pertains to my question above.

I presume we are still okay discussing this? I don't mind if a new thread is made; although it seems to me that this paper is a pretty close development from the OP; if the thread originator would like to stick to post 2001 developments then by all means we can split the thread.

A "stationary" process is stochastic process without a trend; or more formally the probabilities remain the same over time (this is even stronger). What we have here is basically testing the null hypothesis; under the assumption of a stationary process they see how likely the observed distribution might be. If is it very unlikely, then that can be taken as evidence that the null hypothesis is falsified, and that the process of producing floods is not stationary, but has a real underlying trend.

There's a fair bit more involved, and some statistics to deal with independence assumptions that I haven't tried to follow in detail, plus also the comparison of the observations with the behaviour of climate models, which would suggest that the trend seen in observations should be expected to persist; and that is where you get a hypothesis for the scientific explanation for the observed increase.

My reaction to this paper is that there's nothing especially dubious or unusual about publication of a study like this, that tests ideas without claiming to have a clear proof, and which indicates in the conclusion the areas of uncertainty, the limits of the approach and the useful directions for future work. It's appropriately tentative, while still have useful results.

Its the statement published in the abstract, I'm not sure it should be called the 'key' finding, given the conclusion.

Fair enough. One of the key points, then.

Cheers -- sylas
 
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  • #18
Ah. We have a new thread! Thanks. There seems to be a possible point of confusion: some readers may have thought that the paper is about predictions.

It is actually nearly all about an empirical observation from the twentieth century, of an increase in the rate of large floods. There is a fair bit of statistical work to try and sort out whether the increase is significant and suggestive of a change in conditions over the last century. There are also some model experiments to test a hypothesis about the cause of the observed trend.

The focus of the models in the latter half of the paper is to test a hypothesis for the cause of observed increases in great flood risk.

Significance of the increased great flood risk

The largest part of the paper is an evaluation of the significance of the observed increase in frequency of great floods. This is done in two ways:
  1. A simple statistical method assuming independence of events and a stationary process obtained a 1.3% probability of obtaining the observations by chance. A brief extract referring to this argument appears in [post=2446947]msg #12[/post], as the first extract in blue.
  2. Then a much more subtle method was used to deal with the independence assumption, which we should not actually expect to hold in general, even with a stationary process. The method used was to use output from a "control" experiment with coupled climate models and with constant radiative forcing. That is, the models here are not a prediction; but a basis for obtained a comparison with observations and estimating how unlikely they are under the stationary process null hypothesis.

The result with the model experiment indicate that the observed increase in great flood frequency in real life occurs about 3.5% of times in the models of a stationary climate. As the paper says:
Thus, the model-based significance analysis, which implicitly uses the space±time correlation structure of floods in the model, essentially confirms and reinforces the simpler binomial analysis.

Cause of the increase in great flood frequency

On page 516 there follows a smaller part of the paper, which considers a possible hypothesis for explaining the observed increase in great floods. This section of the paper starts with the sentence:
The apparent increase in flood risk might be associated with radiatively forced climate change...
followed by three paragraphs detailing some further experiments with models and non-constant radiative forcing.

The conclusion of this part of the paper appears on page 517:
Thus, the recent history of the observed trend index is generally consistent with the range of results from the scenario experiments.

The experiments on scenarios here are therefore being used to test a hypothesis for the cause of the empirical observations described in the first part of the paper. This paper is not really a modeling paper; models are used simply as a tool in the paper to try and reveal details of the empirical observation.

Summary

This paper is focused on an empirical observation of floods in the past, and considers both the significance of the observation (could it be simply a random bit of bad luck?) and possible causes (could the cause of the observed increase be related to non-constant radiative forcing over the last century?).

The "increasing risk" described in the paper title is an observation of an increased risk over the twentieth century. The paper considers the significance and a possible cause, all in the context of observed changes in climate over the twentieth century.

The brief mention in the abstract that the trend is likely to continue is a fairly usual sort of comment in a paper like this, making explicit the relevance or importance of the work.

Cheers -- sylas
 
  • #19
sylas said:
Ah. We have a new thread! Thanks. There seems to be a possible point of confusion: some readers may have thought that the paper is about predictions.

It is actually nearly all about an empirical observation from the twentieth century, of an increase in the rate of large floods. There is a fair bit of statistical work to try and sort out whether the increase is significant and suggestive of a change in conditions over the last century. There are also some model experiments to test a hypothesis about the cause of the observed trend.

The focus of the models in the latter half of the paper is to test a hypothesis for the cause of observed increases in great flood risk.

Significance of the increased great flood risk

The largest part of the paper is an evaluation of the significance of the observed increase in frequency of great floods. This is done in two ways:
  1. A simple statistical method assuming independence of events and a stationary process obtained a 1.3% probability of obtaining the observations by chance. A brief extract referring to this argument appears in [post=2446947]msg #12[/post], as the first extract in blue.
  2. Then a much more subtle method was used to deal with the independence assumption, which we should not actually expect to hold in general, even with a stationary process. The method used was to use output from a "control" experiment with coupled climate models and with constant radiative forcing. That is, the models here are not a prediction; but a basis for obtained a comparison with observations and estimating how unlikely they are under the stationary process null hypothesis.

The result with the model experiment indicate that the observed increase in great flood frequency in real life occurs about 3.5% of times in the models of a stationary climate. As the paper says:
Thus, the model-based significance analysis, which implicitly uses the space±time correlation structure of floods in the model, essentially confirms and reinforces the simpler binomial analysis.

Cause of the increase in great flood frequency

On page 516 there follows a smaller part of the paper, which considers a possible hypothesis for explaining the observed increase in great floods. This section of the paper starts with the sentence:
The apparent increase in flood risk might be associated with radiatively forced climate change...
followed by three paragraphs detailing some further experiments with models and non-constant radiative forcing.

The conclusion of this part of the paper appears on page 517:
Thus, the recent history of the observed trend index is generally consistent with the range of results from the scenario experiments.

The experiments on scenarios here are therefore being used to test a hypothesis for the cause of the empirical observations described in the first part of the paper. This paper is not really a modeling paper; models are used simply as a tool in the paper to try and reveal details of the empirical observation.

Summary

This paper is focused on an empirical observation of floods in the past, and considers both the significance of the observation (could it be simply a random bit of bad luck?) and possible causes (could the cause of the observed increase be related to non-constant radiative forcing over the last century?).

The "increasing risk" described in the paper title is an observation of an increased risk over the twentieth century. The paper considers the significance and a possible cause, all in the context of observed changes in climate over the twentieth century.

The brief mention in the abstract that the trend is likely to continue is a fairly usual sort of comment in a paper like this, making explicit the relevance or importance of the work.

Cheers -- sylas
Does the paper take into consideration agriculture, animal farming, housing and business developments, roads, changes in drainage, redirection of streams and rivers, articial and natural, dams - artificial and natural, silting, etc... and that these things need to be studied all the way the down from the source of the water? This is a HUGE undertaking, but obviously very important in understanding and predciting where and why an area might flood. This is really complicted stuff.

Am I wrong that this paper falied to take these critical flood causing conditions into consideration?
 
  • #20
Evo said:
Does the paper take into consideration agriculture, animal farming, housing and business developments, roads, changes in drainage, redirection of streams and rivers, articial and natural, dams - artificial and natural, silting, etc... and that these things need to be studied all the way the down from the source of the water? This is a HUGE undertaking, but obviously very important in understanding and predciting where and why an area might flood. This is really complicted stuff.

Am I wrong that this paper falied to take these critical flood causing conditions into consideration?

As shown in the last section Sylas referenced in https://www.physicsforums.com/showpost.php?p=2446947&postcount=12", the authors specifically point out they consider none of those factors Evo. But nor do they make any claim what so ever about what's causing the floods. They simply did the work to collect global flood data (100 yr) and run trend studies on it. They report that.

Unfortunately Xnn's post (https://www.physicsforums.com/showpost.php?p=2445234&postcount=4" in the thread that introduced the 100 yr flood paper makes the statement "another paper that has found an increase in floods during the 20th century due to global warming", which is completely unsupportable from that paper.
 
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  • #21
Evo said:
Does the paper take into consideration agriculture, animal farming, housing and business developments, roads, changes in drainage, redirection of streams and rivers, articial and natural, dams - artificial and natural, silting, etc... and that these things need to be studied all the way the down from the source of the water? This is a HUGE undertaking, but obviously very important in understanding and predciting where and why an area might flood. This is really complicted stuff.

The paper does not do any of that. It is not really a paper about predictions, and it most certainly does not attempt to predict where floods might occur. The paper is clear that conclusions are tentative, and of course you are right that this is a very complex area; no one paper is going to wrap up all of that!

The contribution of this paper is to quantify the stochastic significance of an observed twentieth century increase in great flood frequency (which suggests that there is some cause involved other than just chance) and also to present evidence that increased radiative forcing is a credible cause for the observed trend.

It does not rule out other factors, or attempt an exhaustive consideration of them. It does not attempt to predict where floods occur. It is rather testing a hypothesis which is already on the table in prior scientific work -- that large floods should be expected to increase given radiative effects of anthropogenic changes in atmospheric composition, such as intensification of the global water cycle. The paper concludes with suggestions for further work, which explicitly includes some of the aspects you mention.

The evidence from the paper does suggest that other factors work as well as, rather instead of, the factor of increased radiative forcing.

It's normal in a complex world for many factors to be at work. It's good science to give evidence that a particular factor has a role, without giving a complete wrap up of all causes for a phenomenon or a complete description that would let you make firm predictions. This paper is only about a general frequency world wide. There's no attempt to predict when, or where. There's still plenty of work to do here, of course!

Cheers -- sylas

PS. Actually, mheslep, IMO it would be a reasonable informal description to say that this paper gives evidence that the 20th century increase was due to global warming. The phrase used in the paper is "Radiative effects of anthropogenic changes in atmospheric composition"; and for a general audience it is quite reasonable to translate that as "global warming".
 
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  • #22
sylas said:
[...]
The contribution of this paper is to [...] and also to present evidence that increased radiative forcing is a credible cause for the observed trend.

[...]

PS. Actually, mheslep, IMO it would be a reasonable informal description to say that this paper gives evidence that the 20th century increase was due to global warming. The phrase used in the paper is "Radiative effects of anthropogenic changes in atmospheric composition"; and for a general audience it is quite reasonable to translate that as "global warming".
I agree with everything you wrote that I omitted in the quote above :wink:, and disagree with what's left! The authors provide no evidence for the cause of the observed data. The full statement in the abstract: "Radiative effects of anthropogenic changes in atmospheric composition are expected to cause climate change, in particular an intensification of the global water cycle1 with a consequent flood risk2" is background fluff. The only angle for radiative forcing in this paper is in the modeling. Frankly that statement should have gone into the introduction, and would have been fairly placed there, but not in the abstract which should be a tightly worded summary of the original work done by the authors, and not others (my view).
 
  • #23
sylas said:
The paper does not do any of that. It is not really a paper about predictions, and it most certainly does not attempt to predict where floods might occur. The paper is clear that conclusions are tentative, and of course you are right that this is a very complex area; no one paper is going to wrap up all of that!

The contribution of this paper is to quantify the stochastic significance of an observed twentieth century increase in great flood frequency (which suggests that there is some cause involved other than just chance) and also to present evidence that increased radiative forcing is a credible cause for the observed trend.

It does not rule out other factors, or attempt an exhaustive consideration of them. It does not attempt to predict where floods occur. It is rather testing a hypothesis which is already on the table in prior scientific work -- that large floods should be expected to increase given radiative effects of anthropogenic changes in atmospheric composition, such as intensification of the global water cycle. The paper concludes with suggestions for further work, which explicitly includes some of the aspects you mention.

The evidence from the paper does suggest that other factors work as well as, rather instead of, the factor of increased radiative forcing.

It's normal in a complex world for many factors to be at work. It's good science to give evidence that a particular factor has a role, without giving a complete wrap up of all causes for a phenomenon or a complete description that would let you make firm predictions. This paper is only about a general frequency world wide. There's no attempt to predict when, or where. There's still plenty of work to do here, of course!

Cheers -- sylas

PS. Actually, mheslep, IMO it would be a reasonable informal description to say that this paper gives evidence that the 20th century increase was due to global warming. The phrase used in the paper is "Radiative effects of anthropogenic changes in atmospheric composition"; and for a general audience it is quite reasonable to translate that as "global warming".

But how can you say that you can't rule factors due to chance, when the modern landscape has changed drastically due to improved land moving machinery and infrastructure? Ruling out chance assumes that nothing else has changed in the system. But lots of things have changed in the twentieth century...levies, human built flood plains, acres and acres of concrete and asphalt. There are too many moving parts in the system to make a definitive statement, IM very HO, that any observations are, or are not, due to chance.

And while I agree that perhaps an "informal" conclusion may be reached from these observations, I certainly don't want to tether manufacturing with regulations based on such weak evidence.
 
  • #24
mheslep said:
I agree with everything you wrote that I omitted in the quote above :wink:, and disagree with what's left!

Ain't that always the way? Disagreement is so much more entertaining and motivating.:biggrin:

I guess it comes down to the question of whether model based experiments are evidence or not. I tend to think yes; it's no different in principle from how numerical simulations are used in all kinds of fields. For an example in one of my fields of interest, the best evidence for a certain group of asteroids formed in a past collision is a numerical simulation of how orbit parameters change over time. See: Nesvorny et al (2002) The recent breakup of an asteroid in the main-belt region, in Nature Vol 417, June 13 2002, pp 720-722. Poupular account Detective work identifies "baby" asteroids in New Scientist. Extract: "A computer model that calculates orbital changes indicates that the 13 best-known orbits of asteroids in the group coincided 5.8 million years ago - a sign they were then part of the same body.". Note that the model doesn't actually locate asteroids at a point in space, but simply figures out that they were all in about the same orbit at that time.

The abstract looks fine to me; it's quite normal for an abstract to give directly relevant context like that. The initial sentence is a hypothesis being tested in the paper using model based evidence -- or whatever you prefer to call it. The paper is giving support for the sentence in the abstract.

Cheers -- sylas
 
  • #25
lisab said:
But how can you say that you can't rule factors due to chance, when the modern landscape has changed drastically due to improved land moving machinery and infrastructure? Ruling out chance assumes that nothing else has changed in the system. But lots of things have changed in the twentieth century...levies, human built flood plains, acres and acres of concrete and asphalt. There are too many moving parts in the system to make a definitive statement, IM very HO, that any observations are, or are not, due to chance.

Science does not deal in formal proof. The paper does give good evidence that the increase was indeed significant (i.e., very unlikely to be just random chance); it also supports the hypothesis that a stronger water cycle in a warmer world should be expected to give a trend similar to what is observed.

Of course other factors may be involved. But "levies" don't change the frequency of floods; they try to limit the damage they cause. It's hard to see how flood plains could have an effect. Again, they may alter the impact of a flood, but that is not what is being measured. Most of the factors you mention are not really things that should be expected to have an effect, especially given the carefully defined account of a "great flood" described in the paper.

Unfortunately the paper is not generally accessible that I can see. But here's another extract:
Here, we consider 29 basins larger than 200,000 km2 in area for which discharge observations span at least 30 yr. We analyse annual maximum monthly-mean flows, rather than annual maximum instantaneous flows; these two are strongly correlated in large basins. In contrast with earlier studies4,5, this investigation has a global scope and focuses on extreme events; we analyse the 100-yr flood (that is, the river discharge that has a probability of 0.01 of being exceeded in any given year), which is commonly used in flood-risk assessment for river-basin planning and design of major structures. Choosing such a large-magnitude threshold probably reduces any distortion of our analysis by nonclimatic factors such as land-use changes and river development.

Note that the paper is specifically looking at river discharge to identify floods, and the 29 basins of the study are shown in figure 2. So although the paper is suitably cautious about not over-hyping the conclusion, and is explicit that there are other factors involved which could also be considered, the conclusions of the paper should not be surprising, and the investigation does give a credible level of support for its conclusion.

Note that this is far from an isolated paper. There's plenty of scientific work indicating that the water cycle has been strengthening, and that this is an expected consequence of a stronger greenhouse effect.

Cheers -- sylas
 
  • #26
Maybe this is my imagination, but it seems to me that that papers in the hard physical sciences, e.g. physics, chemistry, rarely, say 1 in 10, put footnotes and/or background material justifying the work in the abstract, but that papers on climate do it almost de rigueur.
 
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  • #27
sylas said:
...But "levies" don't change the frequency of floods;
They apparently can change the frequency of great floods such as those discussed here. The extensive system built on the Mississippi river was credited in part with worsening the 500 year flood there some years ago. That is, that great flood might have been a one or two hundred year flood had the river been allowed to rise out of its banks naturally.
 
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  • #28
mheslep said:
Maybe this is my imagination, but it seems to me that that papers in the hard physical sciences, e.g. physics, chemistry, rarely, say 1 in 10, put footnotes and/or background material justifying the work in the abstract, but that papers on climate do it almost de rigueur.

That's an interesting thought! it might be worth having a quick squiz at a range of journals to see if there is a difference in footnoting (easy to check objectively).

But the climate change mention here is directly relevant to the work of the paper; not merely background. The first sentence of the abstract is the factor that is explicitly taken up and tested in the paper as a factor that increases the frequency of great floods, using the model based analysis in the latter half. The last half is an explicit conclusion from the paper, also based on experiments performed by the authors and described in the paper. The bulk of the abstract describes the bulk of what the paper is doing.

Cheers -- sylas

PS. The paper explicitly describes great flood in terms of discharge from a large river basin. Levies don't impact that.
 
  • #29
sylas said:
...
I guess it comes down to the question of whether model based experiments are evidence or not. ...

Okay, I should not have said 'no evidence', but rather 'no physical evidence', or
'only model based evidence' for the hypothesis that flooding is caused by climate change.
 

1. How do you create a model for predicting rainfall and flooding?

Creating a model for predicting rainfall and flooding involves collecting and analyzing data on past weather patterns, topography, and land use in the area. This data is then input into computer programs to simulate various weather scenarios and predict potential flooding.

2. What factors influence the accuracy of a rainfall and flooding model?

The accuracy of a rainfall and flooding model is influenced by several factors, including the quality and quantity of data used, the complexity of the model, and the expertise of the scientists creating and interpreting the model.

3. Can a rainfall and flooding model accurately predict extreme weather events?

While rainfall and flooding models have improved in accuracy over the years, predicting extreme weather events such as hurricanes or flash floods can still be challenging. These events are often influenced by multiple factors and can be difficult to predict accurately.

4. How can rainfall and flooding models be used to mitigate the impacts of extreme weather?

Rainfall and flooding models can be used to identify areas that are at high risk for flooding and inform land use and development decisions. They can also be used to develop emergency response plans and evacuation routes in case of extreme weather events.

5. Are there any limitations to using rainfall and flooding models?

Like any scientific model, rainfall and flooding models have limitations. They rely on historical data and assumptions, and may not account for all possible variables. It's important to continually update and improve these models to increase their accuracy and usefulness.

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