Guest post by Marc Hendrickx
A little over a month ago reports appeared in the press (eg. Butterflies ‘fly early as planet warms’) that the common Brown Butterfly (Heteronympha merope) was emerging 10 days earlier than it was 60 years ago all due to global warming attributed solely to CO2 emissions. The report was based on a paper published in Biology Letters. The article was titled “Early emergence in a butterfly causally linked to anthropogenic warming” by Michael R. Kearney, Natalie J. Briscoe, David J. Karoly, Warren P. Porter, Melanie Norgate and Paul Sunnucks was published online on 17 March 2010. The abstract can be accessed HERE.
The basis of the study was opportunistically collected observational data of butterfly emergence based on museum records and private data collected between 1941 and 2005 in an area centred around Melbourne, Australia, a city of about 4 million people. No links to the original data or location information of observations were provided in the published article.
The authors gauged the temperature dependence of Heteronympha merope under laboratory conditions and used historical weather data for 1945–2007 (Bureau of Meteorology, Australia) from Laverton (37.868 S, 144.768 E), a “rural” site close to Melbourne, to model the physiological response of H. merope to temperature. The authors claim that this weather station is a ‘high-quality’ site, unaffected by changes in exposure, urbanization, instrumentation, etc., during the study period. Weather records (mean monthly maximum and minimum air temperature, wind speed and cloud cover) were translated into microclimates experienced by immature H. merope using biophysical modelling software (NICHE MAPPER, http://www.zoology.wisc.edu/faculty/Por/Por.html#niche).
The observed temperature trends at Laverton were compared to output from extended climate model simulations for the single-model grid box overlying Melbourne and Laverton. Anthropogenic climate forcing included observed increases in greenhouse gases and estimated variations of anthropogenic aerosols, whereas natural external climate forcing included estimated changes in solar irradiance and volcanic aerosols.
The results are summarised in Figure 1 from the paper
I found a number of issues with this paper that pointed to strong confirmation bias and quickly put together a comment that I submitted to Biology Letters on 19 March 2010, just two days after the article was published on line. A copy of the manuscript appears below. I received notification this week that the manuscript was rejected. The reviewer comments make interesting reading (see below) and I thought I would share them with WUWT readers, with a view that the collective brain of WUWT readers would help find the necessary references such that I might be able to re-submit the comment to Biology Letters sometime over the next few weeks. I’d also be interested in hearing the views of the authors and invite them to add their comments.
Comment on Kearney et al., 2010: Early emergence in a butterfly causally linked to anthropogenic warming.
Kearney et al. (2010) examine phenological change in Heteronympha merope (Nymphalidae) to test whether (i) the phenological shift could be explained by air temperature change, and (ii) that the associated change could be attributed to human influences. Kearney et al., contend their results support:
- a shift in the mean emergence date for H. merope of 1.6 days per decade over a 65 year period over 12,000 km2,
- an increase in local air temperature of 0.14ºC over the same period, and
- attribution of the phonological and temperature change to anthropogenic warming, due to greenhouse gas emissions.
There are significant issues with the study outlined below that negate the conclusions:
1. Observed emergence times for H. merope were based on opportunistically collected data over an area of about 12,000 km2 (geographic area-37.60-38.54 Lat, 144.17 to145.48 Long.) centred on the Melbourne CBD. The location of individual observation locations is not provided and there potential for location bias is not discussed. Nor is there a discussion of the potential effect of confounding influences that may affect emergence times. These influences include: human impact on habitat (Kobayashi et al., 2009), pollution, coincidence in emergence of H. merope with changing emergence patterns of its food stock, food availability and variation over time. These factors may have provided adaptive stresses favouring earlier emergence.
2.The methodology for determining thermal dependence of development rate for eggs, larvae and pupae did not account for other variables that might be a factor in emergence such as: atmospheric CO2 content or affect of atmospheric pollutants such as CO, and ozone common in urban environments. There is a considerable body of evidence demonstrating that effects of elevated CO2 on plants can influence insect herbivore performance (Watt et al. 1995, Bezemer and Jones 1998). Changes in leaf chemistry for instance, such as decreased leaf nitrogen and increased carbohydrate and polyphenolic concentrations at elevated CO2 (Cotrufo et al. 1998, Penuelas and Estiarte 1998), might affect insect development (Slansky 1993) and potentially effect emergence timing. These factors were not taken into consideration and as such the link between emergence timing and temperature cannot be conclusively stated.
3.To assess whether the observed change in climate could be attributed to human influence, the observed April-October mean temperature trend for 1944-2007 for the weather station at Laverton (Bureau of Meteorology-BOM ID 87031) was compared to climate model simulations. Laverton is affected by urbanisation effects from significant changes in land use over the period of observations. Australian Bureau of Statistics (ABS 2008, ABS 2008a) data show an increase in population in the area from 7854 in 1933 to 132793 in 2008 (ABS, 2008, 2008a). Hence to define the station as “rural” is a misrepresentation. NASA GISTEMP defines the station as “Urban” with a population of 2.7 million (GISTEMP, 2010). A station at the western edge of the study area with records spanning the period 1903 to 1998 shows no substantial warming (Figure 1). This station, Durdidwarrah BOM ID 87021, is located in the Brisbane Ranges National Park in an area that has not experienced significant land use change since the 1870s when dams were constructed (Catrice, 1997). A comparison between Durdidwarrah, Laverton and the Melbourne CBD station (BOM ID 86071) indicates substantial warming over the Melbourne Region. The disparity between the rural station and the two urban stations suggest this warming is due to urbanization, rather than increases in greenhouse gases. The temperature increases due to urbanization are similar to those reported in China (Jones et al., 2008).
References
ABS 2008. Australian Bureau of Statistics 3105.0.65.001 – Australian Historical Population Statistics. www.abs.gov.au (accessed 18 March 2010).
ABS 2008a. Australian Bureau of Statistics 3218.0 Regional Population Growth, Australia. www.abs.gov.au (accessed 18 March 2010).
Bezemer, T. M., & Jones, T. H. 1998 Plant–insect herbivore interactions in elevated atmospheric CO2: quantitative analyses and guild effects. Oikos 82, 212–222.
Catrice D. 1997 Brisbane Ranges National Park. Parks Victoria. Department of Natural Resources and Environment, Melbourne Victoria (accessed 18 March 2010)
Cotrufo, M. F., Ineson, P. and Scott A. 1998 Elevated CO2 reduces the nitrogen concentration of plant tissues. Global Change Biology 4, 43–54
GISTEMP 2010. NASA GISS Surface Temperature Analysis – Station Data ‘Laverton’ GISTEMP ID 501948650000 (http://data.giss.nasa.gov/cgi-bin/gistemp/gistemp_station.py?id=501948650000&data_set=0&num_neighbors=1) (accessed 18 March 2010).
Goverde, M., Erhardt, A., & Niklaus P. A. (2002) In situ development of a satyrid butterfly on calcareous grassland exposed to elevated carbon dioxide. Ecology 83(5), 1399-1411
Jones, P. D., Lister, D. H., and Li Q. (2008), Urbanization effects in large-scale temperature records, with an emphasis on China, J. Geophys. Res., 113, D16122, doi:10.1029/2008JD009916.
Kearney, M. R., Briscoe, N. J., Karoly, D. J., Porter, W. P., Norgate M. and Sunnucks P. 2010 Early emergence in a butterfly causally linked to anthropogenic warming. Biology Letters (doi: 10.1098/rsbl.2010.0053)
Kobayashi, T., Kitahara, M., Suzuki, Y. and Tachikawa, S. 2009. Assessment of the habitat quality of the threatened butterfly, Zizina emelina (Lepidoptera, Lycaenidae) in the agro-ecosystem of Japan and implications for conservation. Transactions of the Lepidopterological Society of Japan 60(1), 25-36.
Penuelas, J., & Estiarte M. 1998 Can elevated CO2 affect secondary metabolism and ecosystem function? Trends in Ecology and Evolution 13, 20–24.
Slansky, F. 1993 Nutritional ecology: the fundamental quest of nutrients. Pages 29–91 in N. E. Stamp and T. M. Casey, editors. Caterpillars: ecological and evolutionary constraints on foraging. Chapman and Hall, New York, New York, USA.
Watt, A. D., Whittaker, J. B. , Docherty, M., Brooks, G., Lindsay, E. and Salt D. T. 1995 The impact of elevated atmospheric CO2 on insect herbivores. Pages 197–217 in R. Harrington and N. E. Stork, editors. Insects in a changing environment. Academic Press, London, UK.
=================================
Rejection Letter received April 20 , 2010. Dear Mr Hendrickx
I am writing to inform you that we have now obtained responses from referees on manuscript RSBL-2010-0263 entitled “Comment on Kearney et al., 2010: Early emergence in a butterfly causally linked to anthropogenic warming.” which you submitted to Biology Letters.
Unfortunately, your manuscript has been rejected following full peer review. Competition for space in Biology Letters is currently very severe, as many more manuscripts are submitted to us than we have space to print. We are therefore only able to publish those that are exceptional and present significant advances of broad interest, and must reject many good manuscripts.
Please find below the comments received from referees concerning your manuscript, not including confidential reports to the Editor. I hope you may find these useful should you wish to submit your manuscript elsewhere.
We are sorry that your manuscript has had an unfavourable outcome, but would like to thank you for offering your work to Biology Letters.
Yours sincerely
Publishing Editor
Editor’s comments:
I am rejecting this in view of the strong criticisms by refs. 1 and 3. If the author can deal with these comments, we could consider this for e-letters.
Reviewer(s)’ Comments to Author:
(MH-I have added comments in italics)
Referee: 1
Comments to the Author(s)
The ms is a critique of a recent publication by Kearney et al in Biology Letters. But I am not convinced by any of the author’s three criticisms of the paper.
The first criticism is that the data presented in Kearney et al does not support evidence of a change in emergence times over the study period. Kearney et al note in their paper that while “the opportunistically collected data probably adds considerable noise to any signal of phenological shift, there is no reason to expect such data to be chronologically biased”. To me, this proviso seems sufficient (MH-this seems difficult to justify as no actual data is presented). For the criticisms in the current ms to be supported, the author should present some evidence that this species or others are shifting their phenology related to some of the other factors suggested, or some evidence that in fact the data does not support a shift in phenology. (MH-Can WUWT readers help out with suggestions?) I also do not know where the author has extracted the “area of 12000 km2” data from (MH-this was based on the geographic coordinates provided in the paper) , or that the data were drawn from “disparate, genetically diverse groups” (MH-This was an assumption I made that there would be significant genetic variation over a large geographic area-the area covered by the study contains a range of geographies and sub-climates that may provide local variation in emergence timing. The absence of location data for observations makes it impossibel to judge the potential affect of geographic bias).
The second criticism is that the physiological model did not account for other possible variables. No, but the fit of observed phenology to that modelled based on climate was extremely close. For this criticism to be justified the author should again present some empirical evidence that the other variables listed influence emergence times in this species or similar species. (MH-Can WUWT readers help out with suggestions?)
I am most concerned about the third criticism levelled by the author, that the temperature increase noted for the meteorological station in the Kearney et al paper is dependent on urbanisation effects. The author here presents data from a rural met station and argues that it has shown no increase in temperature over the same period of time. However, the comparison is not valid, because the regression of temperature against year in Fig 1 for the Durdidwarrah station is run from 1903 to 1998, rather than 1944 to 2007, as in the Kearney et al paper. Examination of the figure shows that had data for the approximate 1940 to 2000 period been analysed for Durdidwarrah, there would have probably been a significant increase in temperature, comparable to that reported for the Laverton station by Kearney et al. In this case it is essential to compare like with like, as the Kearney et al paper is not looking at changes to butterfly phenology since 1903, but from the 1940s. (MH-Durdidwarrah is a good station but suffers from a number of breaks in reporting. The reviewer is correct in arguing that a trend through Durdidwarrah from 1940 through 2000 would yield a decadal trend similar to Laverton, however virtually all this warming occurred in the late 1940s, the trend since 1950 has been flat).
There are a few presentational errors: various spellings of “phenological” and “effect” and “affect”, “Nymphalidae” spelt incorrectly, Fig 1 could be presented more clearly.
Referee: 2
Comments to the Author(s)
In the short intro, the author writes twice “phonological changes”. I guess that would be “phenological changes”? (MH based on this I take it that Ref 2 was generally happy with the manuscript)
Referee: 3
Comments to the Author(s)
The author makes some relevant and potentially relevant points in his comment on Kearney et al., (MH-my bold) but this manuscript does not bring this criticism in a sound way, as it stands. It needs major revision before it may become acceptable for publication.
1) Point 1 – Hendrickx is criticizing the use of opportunistically collected data. Kearny et al have made the assumption that there is no obvious bias in these data. So, here the author should more convincingly show that there is indeed bias that may impact on the conclusions. It is not enough mentioning the opportunistic nature of the data. This point needs more work. (MH-again any references that demonstrate effect of other influences on emergence appreciated)
2) Point 2 –CO2: that may be a valid issue that has not been considered as an alternative (or interaction) effect by Kearney. Another relevant paper would be Mevi-Schultz et al. 2003. behave Ecol Sociobiol 54: 36-43 (MH-this appears to be generally supportive of my point 2).
3) Point 3: I don’t get this point. How can you distinguish between urbanization and an increase in greenhouse gasses per se? What would be the direct and the indirect effects of urbanization for the system considered. Again, the author is not making his point in a clear way (MH-I would have thought the comparison between the three stations clearly demonstrates a UHI effect over the Melbourne region).
The location of Laverton quoted (37.868 S, 144.768 E) is on the freeway and is not the Laverton weather station.
I found a map claiming to show the weather station and it appears to be about in the middle of both these two images:
http://i42.tinypic.com/nnjevr.jpg
A number of commentators have made good points, especially Al Gored (00:13:07) . Opportunistically collected first flight times would clearly be biased by any trend in the number of people looking for the butterflies, so there is no way to disentagle observer population growth from temperature in this study that I can think of. You should be able to document this.
The data in this paper do seem especially weak and it is unlikely that it would have been published except for its AGW spin. If there is any validity to their pattern, then I suspect it would be due to UHI (also note the use of ‘their’ and ‘there’ in this sentence – I think I got them right, but even Richard Telford seems to have a problem with ‘their’, so you are in good company).
Still, as several commentators have noted, you would be fighting an uphill battle and even if you win, all you will have is a technical comment that no one will pay any attention to. You need a better story than the Karoly rubbish if you want to have an impact.
Prevailing wind direction also has an effect; wind from the city center will have higher temps and probably CO2 content than wind from the rural areas. In addition to the heat island effect, I suspect there is also a CO2 island effect.
All of which pertains to the point that the local conditions may well have advanced hatching times, but the reasons for such changes in conditions are far beyond the reach and purview of the data presented. To prove the GW causality, a similar effect would have to be observed in a hatching site far from any urban center as well.
This is just ridiculous. Springtime jumpstarts, you know, from one day to another.
Warm winds and sunshine boosts temperatures 5-10-15 degrees in a single day!
The notion that mere tenths of degrees would make a difference is a tough task to prove.
Or that the grrenhouse gasses would make a big differense.
I think to much focus is on mean temperatures, what about the sudden rise in temperature from one day to another? Has that changed?
Is nighttime cooling significantly lower now than 50 years ago?
Today, in sweden, I have the first real springday, sun is hot, wind is waarm, and lo!
butterflies are whimsically searching for flowers. This happened from one day to another.
I think the cold winds from the arctic that usually travel eastwards over the sea, this winter decided to blow across land, thats what made the harsh winter. The sea is therefor warmer, and is now giving back energy. Regardless of mean temperature variations of tenths of degrees.
Picking the data points off Fig.1a, I dont find a significant correlation between observed emergence-dates and their predicted emergence-dates.
(But I do not see a predicted emergence date for 1940, which might change things ).
OT (ish)
Well, we now know that the dinosaur extinction was started by excess CO2 causing colder sea temperatures
http://www.telegraph.co.uk/science/dinosaurs/7624014/Dinosaurs-died-from-sudden-temperature-drop-not-comet-strike-scientists-claim.html
“We now believe that they died out gradually and it is very possible that this could have been caused by a series of climatic changes.”
The drop in temperature is thought to have occurred because high levels of CO2 were in the atmosphere which caused global temperatures to rise and polar ice to melt – a phenomenon currently predicted for Earth. ”
They just don’t give up do they? As a non-scientist, I now have about as much trust in climate science as I have in the infallibility of the Pope.
OT again but startling:
http://blogs.telegraph.co.uk/news/jamesdelingpole/100036272/too-many-sceptics-in-bbcs-climate-change-reporting-says-independent-expert/
‘Then there’s Fiona Fox’s outrageous claim that the way the BBC could really improve its science coverage is to have fewer sceptics. She says:
“To have a sceptic or contrarian in every interview is really misleading the public.”’
I had to stop here and wonder if I’d blinked and missed something in BBC climate coverage – all those malicious sceptics spoiling every interview.
More $ for Nabokov lovers?
Reading Lolita in Elite Flutterby Land.
“Some money would still have to be available for other scientists to apply for grants to support individual projects, he said.”
…-
“Nobel Prize winner Sir Paul Nurse calls for reform of science funding
Public funding of science should become more elitist, says the Nobel laureate nominated as next head of Britain’s national academy of science.
Sir Paul Nurse, named yesterday as the only candidate to succeed Lord Rees of Ludlow as President of the Royal Society, called for reform of the £3.2 billion budget to give more support to the few scientists who can “really move the needle” by making major discoveries.
In an interview with The Times, the geneticist, who won the Nobel Prize for Medicine in 2001 and is currently president of the Rockefeller University in New York, said that funders should identify 100 to 150 excellent scientists in all fields, who would get generous long-term support to pursue their interests.
The amount of funding would vary from field to field, and the elite would be assessed for five to seven years to ensure that they still deserved their status. Some money would still have to be available for other scientists to apply for grants to support individual projects, he said.”
http://www.timesonline.co.uk/tol/news/science/article7106626.ece
Jordan (03:12:23) : “I’m not an entomologist, but I wonder if cumulative degree-days is a proxy for the aggregate of limiting factors (like exploitable food supply). ”
Degree days are not a proxy for anything. Temperature has independent effects on insect development. Obviously, other factors also have effects including food and water availability, light/dark cycles, etc. One commenter here had a question about potential light pollution effects, which struck me as insightful. Photoperiod changes can also have strong independent effects on developmental events. The premise of this paper seems quite weak, since it appears that the authors are just reporting a correlation without making much of an attempt to evaluate other variables that might affect the timing of adult emergence. Then, to make matters worse, they jump to an unsupported conclusion about the cause of the observed warming. It might very well be UHI, but from the bug’s perspective temperature is temperature.
I live about 20kms from Laverton and I can tell you, it was once a rural area, which became an air force base from the early 1940s to the early 1990s or so, and since then has seen significant development and is now is part of one the most fastest urban growth corridors in Australia. A perfect case of seeing an increasing warming bias over the past 50 years.
But hey, why let facts get in the way of a good story!
I thought it somewhat humorous that the first referee decried spelling then spelled impossible as “impossibel”.
Comparative degree days to hatching tells us nothing more than there was a change. It doesn’t tell us what within a dynamic system was the causative agent or agents.
Hatch time for many organisms are far more plastic than simply degree days. Predation risk plays an essential role mediated by kairomones (chemical odors released by predators and the prey being eaten). The smell of conspecifics (kin) being eaten and/or the smell of predators can accelerate hatching time – significantly. (Yup -the smell is transferred into the egg) Chemical alarm signaling can also change the place and timing of ovipositing.
Here are some papers showing chemical alarm signaling and its role in hatch timing for dragon flies, trout, daphnia, spiders, and frogs :
http://www.esajournals.org/doi/abs/10.1890/0012-9658%282006%2987%5B809:TCMPPI%5D2.0.CO%3B2
http://www.springerlink.com/content/n151246k72342tlh/
http://www.springerlink.com/content/w7547312266t3113/
http://rspb.royalsocietypublishing.org/content/269/1505/2155.abstract
http://www.pnas.org/content/92/8/3507.full.pdf
I note one place where a spelling correction is called for.
The location of individual observation locations is not provided and there ////[THEIR??? THE???/ /// potential for location bias is not discussed.
Sorry that it is such a minor point, for the note is interesting.
IanM
Re: MarcH (Apr 24 03:07),
Maybe our understanding of confirmation bias is different to theirs.
The prelim paper lists email addresses for the authors, maybe fire one off? If not appropriate for you to do that, let me know and I’ll do it. A courteous invite.
The thing that I don’t understand is what has this study got to do with CO2 emissions? Why did this study need modelling? They didn’t predict future emergence times for these butterflies did they?
The temps have been what they have been, the butterflies emerged whenever they emerged. A conclusion that they are emerging earlier is sufficient. Why bother with Karoly and modelling of T’s precip etc with CO2 forcing?
p.s. The 1st reviewer states “The second criticism is that the physiological model did not account for other possible variables. No, but the fit of observed phenology to that modelled based on climate was extremely close.”
Marc have you had a chance to figure out why fig.B is different in the prelim report? Looks like the model results are different.
Weather affects timing of insect cycles. Ask bats. They are really good at figuring this out, even to the point of waiting to fertilize eggs till more insects are available. The females hold onto sperm they received earlier and then somehow move it to their eggs when the timing is right. Wonder if anyone has studied bats down there? Wonder what the weather cycles were like during the study period in question?
As far as the comment letter, I would agree. It was poorly written and poorly sited. And if you need this much help finding articles or data to refute this study, maybe you shouldn’t be the one to comment on it?
cited, Pam, cited
As well as the many good points above there are further at the New Scientist page on this story at http://www.newscientist.com/article/dn18671-global-warming-changes-natural-event-first-causal-link.html
More evidence on confounding factors can be found in the Kearney et al interim report. (For link and more details see the post by Baahumbug on 24/4 at 02:11:42)
“Over the past few months, Maddie Barton has been rearing four populations of larvae – Carnarvon Gorge, South Australia (MR and WP), Olinda and Tasmania (HB and LA) under three temperature treatments: 20, 15 and 8°C. Growth rates of each larval stage and overall development rates have been measured and so far, at 20°C, individuals from Carnarvon Gorge and South Australia appear to be developing faster than those originating from the southern end of their range.”
There is no useful information at all in the Kearney paper on the emergence data that was collected. We don’t know number or frequency of observations, but do they have phenotype information? Could the observed variation in emergence be due to the arrival in Melbourne of a faster developing phenotype and little to do with the change in temperature?
I agree that a comment in Biology Letters will have little initial impact, but I assume it will also appear in CAB/Scopus etc which may result in your points being considered by subsequent research groups that wish to cite Kearney. More mainstream exposure would be good, similar to that generated by the original paper. Can I suggest that once v2 is published (or rejected) you could send this web site and any associated data to Christopher Booker or James Delingpole at the UK Telegraph to see if they will expose the story. By then the UK election will be over and hopefully the Icelandic volcano will have stopped erupting and they may be looking for some Global warming related news!
Just read Science Daily . An article declares that GW will stop bird migration. As someone else said, “they just won’t stop.”
As someone else noted, I would (a) avoid claiming that the paper is all wrong; (b) focus on one key issue, e.g., actual biologically relevant temperature pattern; and (c) find a really good editor to check spelling and grammar.
Ultimately, the best counter is to find another first flight data set that does not support the strong AGW hypothesis.
MarcH:
I had another thought. I recall looking at Mountain Pine Beetle infestation studies and the weakness there was that the current infestations actually were similar to earlier equally severe infestations that happened to be outside of the time period of the study. It may be worthwhile looking at first flight data prior to the start of the period focused on in the original article.
AlGoresaur
Laverton rural?! I wanted to fall about laughing when I read that. I first lived in Melbourne in 1984. It has grown hugely since then. Laverton is out near Altona and by the Prince’s Freeway to Geelong. Don’t tell me that the huge sprawl of Melbourne and the increasing use of cars and air-conditioners hasn’t had an effect on local temperatures.
On a separate note: Please consider posting on the dinosaur study reported on in the Telegraph and mentioned several times above. I was a dinosaur enthusiast as a young man, and I realize this is off-topic for the thread, but just a couple of points on that story:
– I believe there was an Atlantic Ocean by the end of the Age of Dinosaurs, as Pangea started breaking up during the Jurassic – could be wrong here?
– I also seem to remember there was strong evidence that the dinosaurs were warm-blooded… but no proof to point to myself.
Sorry to be OT on that.
I followed the link to the Telegraph article on dinosaur extinction, and was hugely amused by the lead paragraph:
“British researchers claim that a sudden plummeting in the sea temperature of 16F (9C) more than 137 million years ago was the first step towards their eventual road to extinction.
Whose extinction? Judging by the paragraph, British researchers are on their eventual road to extinction. Perhaps not a bad idea.
I looked at the Google maps for this area and it is mostly civilized. It is urban or farmland. I’m not sure that trying to find a rural temperature history will be useful if the butterflies have become urbanized. Isn’t nice how the paper is completely useless without this information.
At one time I needed to measure vapor transport through polymers. From this I became aware of how insects are completely controlled by humidity. You do not see mosquitoes out in the sunshine in the middle of the day because they will rapidly dry out. They come out in the evening as the temperature drops and the r.h. goes up. This is also true for the butterflies.
http://users.sa.chariot.net.au/~erg/merope_ds.htm
If irrigation has increased in the study area, I would expect the insects would have done better from the higher humidity
Here is a graph showing a decreased trend in pan evaporation:
http://www.fcubed.com.au/fcImages/img-evapGraph.png
If temperatures have gone up from land use change and evaporation has gone down, the humidity must have gone up.
I have not found historical trends for irrigation near Melbourne.