JoVE Journal > Environment
Summary
Abstract
Introduction
Protocol
Risultati
Discussion
Divulgazioni
Acknowledgements
Materials
Riferimenti
Ambiente

Low-Cost Automated Flight Intercept Trap for the Temporal Sub-Sampling of Flying Insects Attracted to Artificial Light at Night

Published: December 29, 2021
doi:
10.3791/63156
, , ,
1Department of Ecology, Environment and Evolution,La Trobe University, 2Independent researcher

Summary

To study the impacts of artificial light at night (ALAN) on nocturnal flying insects, sampling needs to be confined to nighttime. The protocol describes a low-cost automated flight intercept trap that allows researchers to sample at user-defined periods with increased replication.

Abstract

Sampling methods are selected depending on the targeted species or the spatial and temporal requirements of the study. However, most methods for passive sampling of flying insects have a poor temporal resolution because it is time-consuming, costly and/or logistically difficult to perform. Effective sampling of flying insects attracted to artificial light at night (ALAN) requires sampling at user-defined time points (nighttime only) across well-replicated sites resulting in major time and labor-intensive survey effort or expensive automated technologies. Described here is a low-cost automated intercept trap that requires no specialist equipment or skills to construct and operate, making it a viable option for studies that require temporal sub-sampling across multiple sites. The trap can be used to address a wide range of other ecological questions that require a greater temporal and spatial scale than is feasible with previous trap technology.

Introduction

There are many arthropod sampling techniques1,2,3, but ecologists often have difficulty applying these methods in ways that are appropriate to their research questions (see4). When choosing an appropriate method for sampling insects, ecologists must consider the targeted species, time, effort, and cost involved in different techniques. For example, a common limitation is that it can be logistically challenging to sub-sample during specific time periods over replicated sites to quantify temporal variables which influence species activity, such as changes in weather or circadian activity (but see5). Most passive-survey insect traps are set for long periods (e.g., over multiple days, weeks, or even months), lacking fine-scale temporal resolution1. For surveys targeting specific time periods across multiple replicate sites (such as nocturnal sampling only across distinct sites), a large team may be required to visit sites over multiple days at the same time points (e.g., within 30 min of sunrise and sunset) to collect specimens and reset traps6; otherwise, an automated trapping device is required5,7,8.

There is a growing field of work on the impacts of artificial light at night (ALAN) on insect activity patterns and localized population dynamics9,10; and on the interactions between ALAN and rates of insect predation4,11,12,13. However, to study the impacts of ALAN on nocturnal insect taxa, sampling needs to be confined to nighttime. Several different active light traps have been described and used for automated temporal sampling of nocturnal insects14. Some examples include simple falling disk-type separation devices, where the catch falls into a narrow tube with a disk falling every hour to separate the catch15, or turn-table separation devices that rotate collection bottles at timed intervals7,16,17. These previous automated light traps address the sampling challenges involved with temporal survey requirements but are often large and unwieldy and use outdated or unreliable technology. A new automated passive sampling device was recently developed and tested8. This device utilized a commercially available flight-interception trap paired with a lightweight custom-designed collection device consisting of a turn-table holding sampling cup that allows for collecting trap contents at user-defined intervals8. This new automated trap employs sophisticated programming that can be operated by a smartphone but is prohibitively expensive to build at around EURO 700 (AUD 1,000) per trap8.

Flight intercept traps are one of the most efficient ways to survey flying insects1,18,19 and work on the principle that flying insects fall to the ground when they collide with a vertical surface. Flight intercept traps come in a variety of designs. However, most are typically constructed with a transparent or mesh surface and a collecting container filled with water and/or a preservative. The new trap described here uses a cross vane/baffle type or multidirectional intercept trap20, given that cross baffles have been shown to increase capture rates14,21 and sample insects from all directions. The purpose of this trap is to survey nocturnal flying insects that are attracted to artificial lights. This phototaxis results in insects circling the light source22; hence a multidirectional trap is most suitable.

Described here is a low-cost automated intercept trap that requires no specialist equipment or skills to construct and operate. The trap uses a commercially available automated pet food dispenser and common items available from hardware stores. This design costs less than EURO 66 (AUD 105) per trap to construct (Table 1), making them a viable option for studies requiring temporal sub-sampling across multiple sites simultaneously.

Protocol

1. Trap construction

NOTE: All of the components required to build the traps can be found in the Table of Materials. Each trap was constructed as shown in Figure 1 and Figure 2 by one person within 2 h.

  1. Use a jigsaw to cut the polycarbonate roofing sheets (8 mm x 610 mm x 2400 mm) into 610 mm x 230 mm sections (Figure 1, item 1 & 2). Then cut a 8 mm center groove halfway up the center of each (610 mm x 230 mm) pane to allow the two panes to slide together to form a cross baffle.
  2. Slide the crossed baffles snuggly into the plastic funnel opening (Figure 1, item 4) and secure them to the funnel with 20 mm stainless steel angle brackets (Fig 1, item 5b).
  3. With the angle bracket in place, pre-drill holes and then use M4 screws and nuts with washers (Figure 1, item 6b) to secure the cross baffles to the funnel.
  4. Again using the jigsaw, cut a piece of the polycarbonate sheeting (230 mm x 305 mm) from remaining sheets and secure with 20 mm stainless steel angle brackets (Figure 1, item 5a) at a 90° angle to the top of the crossed baffles to form a protective roof (Figure 1, item 3).
  5. With the angle bracket in place, pre-drill holes and then use M4 screws and nuts with washers (Figure 1, item 6a) to secure the roof to the baffle.
  6. Trim the funnel spout to a length of ~30 mm with a hacksaw to ensure the sample trays of the automated pet feeder will rotate unobstructed at the programmed intervals.
  7. Place the automated pet dispenser (Figure 1, item 8) within a 9 L (38 mm diameter) plastic basin (Figure 1, item 7) to protect the samples from weather conditions.
  8. Drill a 20 mm hole into the top of the 9 L basin and place the funnel spout into the hole to position it directly above the sample tray.
  9. Using a drill with a hex-head driver bit, secure the plastic basin covering the pet feeder to a 500 mm piece of treated pine fence paling (Figure 1, item 9) with galvanized hex-head screws (Figure 1, item 14).
  10. To stabilize the entire trap for hoisting into the air via ropes, attach a wooden stake (17 x 17 x 1200 mm, Figure 1, item 10) to the piece of treated pine fence paling (Figure 1, item 9) with an angle bracket and tie wire (Figure 1, items 13, 15 and 16).

Figure 1
Figure 1: Schematic diagram of trap construction. (1 and 2) 610 mm x 230 mm x 8 mm polycarbonate sheets; (3) 230 mm x 305 mm x 8 mm polycarbonate sheet; (4) 24 cm diameter plastic funnel; (5ab) 20 mm angle brackets; (6ab) M4 x 15 mm screws, washers & nuts; (7) 38 cm diameter 9 L plastic basin; (8) automated pet food dispenser; (9) 150 mm x 12 mm treated pine paling; (10) 17 mm x 17 mm x 1200 mm wooden stake; (11) 125 mm x 150 mm angle bracket; (12) 16 mm x 16 mm hex-head screws; (13) angle bracket; (14) 16 mm x 16 mm hex-head screws; (15 and 16) wire stabilizer; (17) karabiner, used for lowering and raising into position. Please click here to view a larger version of this figure.

2. Trap deployment

NOTE: The traps were attached to trees 6 m above the ground (directly below the experimental or control lights) to capture flying insects (Figure 2). Emptying and collection of traps were done by three people on a single day. Further days can be sampled if required by lowering the trap to remove the collected samples, resetting the pet food dispensers, and placing the trap back in position every three days based on the sampling regime.

Figure 2
Figure 2: Low-cost automated flight intercept trap for sampling insects at user-defined time points. (A) Polycarbonate crossed baffles serve as the flight intercept area that allows for collecting insects from all four sides. The polycarbonate roof serves to direct insects downwards and protect the collected samples from the weather. The funnel beneath the flight intercept barrier servers to funnel insects that have collided with the polycarbonate barriers into the collecting trays housed within the circular basin. (B) Trap suspended below experimental light and secured to the tree by a wooden stake and angle bracket. The plywood box below the intercept trap contains a bat detector used to passively record echolocation calls produced by free-ranging insectivorous bats. Please click here to view a larger version of this figure.

  1. Once at the sampling location, remove the automated pet food dispenser (Figure 1, item 8) from beneath the plastic basin.
  2. Open up the automated pet food dispenser (Figure 3A) and place foil dishes containing soapy water or a preservative of choice in each food tray (Figure 3B, here 20 mL of propylene glycol was used as a preservative).
  3. Follow the directions provided with the automated pet food dispenser to set the food tray rotation times. First, set the clock time, then program each pet food dispenser tray.
    ​NOTE: The automated pet food dispenser rotates food trays (1-6) at pre-programmed times. The 6-meal bowls can be set to open at any time of the day or night, with the trays rotating in sequential order. For this study, the aim was to sample nocturnal and diurnal insects separately. Tray 1 sampled from 8 PM on the first night and then moved to tray 2 at 7 AM the following morning, followed by tray 3 at 8 PM, tray 4 at 7 AM, tray 5 at 8 PM and tray 6 at 7 AM. A delay function allowed for a one-day delay in sampling because it took 2 days to set up all sites, thereby ensuring sampling commenced on the same day/time at all sites.

Figure 3
Figure 3: Automated pet food bowl. (A) Battery-operated 6-meal pet food bowl used to sample insects at user-defined intervals. The food bowls were programmed on alternating schedules to sample nocturnal and diurnal insects. For example, tray 1 opened at 8 PM (nocturnal day 1), tray 2 opened at 7 AM (diurnal day 1), tray 3 opened at 8 PM (nocturnal day 2), tray 4 opened at 7 AM (diurnal day 2), tray 5 opened at 8 PM (nocturnal day 3), and tray 6 opened at 7 AM (diurnal day 3). (B) Lid removed from automated pet food bowl to show the six collection trays. Foil dishes containing propylene glycol as a preservative allowed for the easy removal of the collected insects. Please click here to view a larger version of this figure.

  1. Place the automated pet food dispenser back underneath the plastic basin and secure the basin to the timber fence piece with the galvanized hex-head screws (Figure 1, item 14).
  2. Attach a rope to the top of the trap with a karabiner (Figure 1, item 17). With the use of a ladder, hoist the trap into position and secure it beneath experimental lights by the karabiner.
  3. Attach a second wooden stake (17 mm x 17 mm x 1200 mm, Figure 2B) to the tree (or lamp post) with an angle bracket to stabilize the trap in high winds.
  4. The trap sits on top of the stake; secure it with two large cable ties (Figure 2B).
  5. To collect insect samples, lower the traps with a rope. Remove the automated pet food dispenser from beneath the plastic basin.
  6. Remove the lid of the pet food dispenser (Figure 3A) and lift the aluminum trays out to pour the contents into pre-labeled sample vials (Figure 3B).

Representative Results

The traps were trialed in a survey of flying insects attracted to experimental lighting at four bushland reserves across Melbourne, Australia. Sites consisted of either remnant or revegetated bushland surrounded by residential housing and averaged 15 km apart (range 3-24 km) and 45 ha in size (range 30-59 ha). A total of sixteen traps were installed, four at each site, with and without experimental lights (3 lights and 1 control per site), and surveyed for 3 days and 3 nights from 30 March to 2 April 2021. Installing the traps took a team of two people 2 days, but by utilizing the delay function on the pet food dispenser, sampling commenced at the same time and day for all traps.

The traps operated under variable weather conditions (6.7-29.5 °C, nighttime minimum, and daytime maximum temperatures; 17-46 km/h maximum wind gusts), including rain, without any failures or rain flooding the collecting trays. A total of 488 flying insects were captured over the three sampling days, with 374 from nocturnal sampling and 114 from diurnal sampling. All non-flying taxa (Arachnida, Isopoda, Myriapoda, and Formicidae) were excluded. To evaluate the efficiency of the traps, divide the total number of arthropods collected (488) by the effective surface area (23 cm x 61 cm) of each trap (1403 cm2) by the number of trap-days (16 traps x 3 days) they were operated (48)23. This yielded a value of 0.007 insects/cm2/trap-day, which is within the range of other studies using flight intercept traps (Table 2). The difference between traps placed under lights and those not under lights (i.e., controls) was also examined, as lit traps would effectively become an active light trap and should therefore have increased capture rates (Table 2). Hence, the traps appear to be as effective as traditional flight intercept traps but with the added benefit of sub-sampling at user-defined time periods.

Material Number needed per trap Cost AUD (per trap)
Batteries (C cell) – 10 pack 4 16.70 (6.68)
Battery operated automated 6 meal pet food bowl – each 1 59.00 (59.00)
Galvanised hex-head screws (10-16 x 16 mm) – 100 pack 5 17.54 (0.87)
Galvanised steel angle bracket (125 x 150 mm) – each 2 1.58 (3.16)
Galvanised tie wire (0.70 mm x 75 m) – per roll ~2 m 5.00 (0.13)
Plastic basin (38 cm, 9 L round) – each 1 4.50 (4.50)
Plastic funnel (24 cm) – each 1 4.99 (4.99)
Stainless steel angle bracket (20 mm) – 16 pack 8 4.73 (2.37)
Stainless steel screws & nuts (M4 x 15 mm) – 18 pack 16 3.56 (3.16)
Stainless steel washers (3/16” & M5) – 50 pack 16 4.98 (1.59)
Sunlite Polycarbonate roofing sheet (8mm x 610 mm x 2.4 m) – each Each sheet makes 4 traps 60.00 (15.00)
Treated pine paling (150 x 12 mm) – each 1/3 1.60 (0.53)
Wooden stakes (1200 x 17 x 17 mm) – 10 pack 2 12.99 (2.60)
Total cost per trap AUD 104.58

Table 1: Design cost of automated intercept trap. The table lists the cost and source of all the components required to build the trap.

Trap type1 Total captures Trap effective surface area (cm2) Number of trap-days (# traps x # days) Number arthropods/cm2/trap-day Source
Novel 1,609 550 432 0.007 Carrel (2002)23
Window 1,241 3,721 6 0.056 Chapman & Kinghorn (1955)32
Window 1,107 3,686 140 0.002 Canaday (1987)33
Window 3,540# 9,600 150 0.002 Hill & Cermak (1997)18
Window 30,530 26,000 2,160 0.00050 Lamarre et al (2012)19
Window 428 623.7 1,860 0.0004 Burns et al (2014)34
Multi 10,161 1,378 1,825 0.004 Basset (1988)35
Multi 15,000 10,800 804 0.002 Russo et al (2011)36
Multi 2,30,162 1,200 40,500 0.005 Knuff et al (2019)37
*Multi 1,360 1,680 1,548 0.0005 Wakefield et al (2017)6
Multi 12 1,680 516 0.00001
*Multi 2,725 1,000 142 0.019 Bolliger et al (2020)8
*Multi (A) 2,991 1,000 142 0.021 Bolliger et al (2020)8
*Multi (A) 49,613 1,000 2,080 0.024
*Multi 1,625 1,000 264 0.006 Bolliger et al (2020)12
*Multi (A) 449 1,403 36 0.009 This study
Multi (A) 39 1,403 12 0.002
1Trap types: Novel – not a standard window or multidirectional style trap, Window – single vane rectangular panel, Multi – multidirectional cross vane/baffle panels, Multi (A) – multidirectional automated trap.
*Denotes traps were positioned under lights #Based on average catch; hence, number of trap days not multiplied by number of traps.

Table 2: Comparison of relative capture efficiency of various flight intercept traps. To calculate the number of arthropods/cm2/trap-day, divide the total number of insects collected by the effective surface area of each trap by the number of trap-days they were operational23.

SUPPLEMENTARY FILES: Data are available from the Dryad Data Repository: http://doi.org/10.5061/dryad.gqnk98sp1

Discussion

Despite the automated flight-intercept trap described by Bolliger et al. (2020)8 being well designed and very effective at sampling at user-defined time periods, they are likely to be cost-prohibitive for many researchers. This study shows that passive trapping surveys using automated traps for sub-sampling flying insects at user-defined periods can be carried out on a modest budget. Traps were built to sample at six pre-defined time points by utilizing a commercial pet food dispenser and materials commonly available from hardware stores, without any specialized skills, for a tenth of the cost required to build a Bolliger et al. (2020)8 trap. Professional electronic and mechanical knowledge is also required to build the Bolliger et al. (2020)8 automated flight-intercept traps at a cost of EURO 700 (AUD 1,000) per trap. Similar quotes were obtained locally for the construction of traps based on the Bolliger et al. (2020)8 design, with the most competitive being AUD 937 per trap.

The Bolliger et al. (2020)8 paper failed to recognize any of the older entomology literature and stated, "there were no current time-interval sampling devices for insects". This is not the case, as time-interval or sub-sampling devices have been used in a number of studies since 193414. However, these older devices were large and most often operated as single units (see Figure 1. In Steinbauer, 20035); hence up-scaling to a number of devices for replication that could be mounted at height (i.e., 5-6 m) would be difficult.

The new trap design described here was as effective as other flight-intercept traps (Table 2) despite trapping occurring immediately following a full moon, with lunar illumination known to reduce catches24 and in the austral autumn when insect activity is beginning to decline25. Capture rates would be expected to increase during more favorable seasons and weather conditions. Each collection tray has a 330 mL capacity to accommodate most applications, but it would be beneficial to test during swarming events to ensure collection trays do not overfill. These traps can be used for both passive and active sampling of flying insects and will have a broad range of applications in studies that require greater temporal resolution in flying insect collection than was previously possible.

With major insect declines being reported worldwide26,27, the key roles insects play in ecosystem services and trophic interactions have generated ecological concern28 and debate29. Our current understanding of these declines is insufficient to identify the drivers, and to date, there have been modest attempts at understanding spatial, temporal, and taxonomic factors30. One area of growing concern is the role that ALAN has as a driver of insect activity, community composition and decline31, and nocturnal species are especially impacted by changes in natural light cycles. To correctly survey insect responses to ALAN, nocturnal synchronous sampling at defined time periods (i.e., nighttime only) across a number of replicated sites and treatments cannot be accurately performed using manual traps without high labor intensity, the trap described here provides a novel and low-cost solution to address these research questions.

Divulgazioni

The authors have nothing to disclose.

Acknowledgements

The research was funded through the La Trobe University Net Zero Fund, sponsored by Sonepar. The research was conducted under Department of Environment, Land, Water and Planning scientific permit no. 10009741. We thank Martin Steinbauer for comments on an early draft and two anonymous reviewers.

Materials

Batteries (C cell) – 10 pack Duracell MN1400B10 https://www.duracell.com.au/product/alkaline-c-batteries/
Battery operated automated 6 meal pet food bowl – each OEM China XR-P006-002 Automated 6-meal pet food bowls range in price dependent on supplier, for example in the UK they can be purchased for £19 GBP ($36 AUD).
Galvanised hex-head screws (10-16 x 16 mm) – 100 pack Bunnings Warehouse 1-311-9151-CTPME Bunnings Warehouse is an Australian hardware chain with stores in Australia and New Zealand. Items purchased from Bunnings Warehouse can be found at most hardware stores. https://www.bunnings.com.au/
Galvanised steel angle bracket (125 x 150 mm) – each Bunnings Warehouse AZ11 https://www.bunnings.com.au/
Galvanised tie wire (0.70 mm x 75 m) – per roll Bunnings Warehouse 50218 https://www.bunnings.com.au/
Plastic basin (38 cm, 9 L round) – each Ezy Storage FBA31541 https://www.ezystorage.com/product/laundry/basic-accessories/9l-round-basin/
Plastic funnel (24 cm) – each Sandleford Pf24 https://www.sandleford.com.au/plastic-funnel-24cm
Stainless steel angle bracket (20 mm) – 16 pack Bunnings Warehouse WEB2020 https://www.bunnings.com.au/
Stainless steel screws & nuts (M4 x 15 mm) – 18 pack Bunnings Warehouse SFA394 https://www.bunnings.com.au/
Stainless steel washers (3/16” & M5) – 50 pack Bunnings Warehouse EBM5005 https://www.bunnings.com.au/
Sunlite Polycarbonate roofing sheet (8mm x 610 mm x 2.4 m) – each Suntuf (Palram Industries Ltd) SL8CL2.4 https://www.palram.com/au/product/sunlite-polycarbonate-multi-wall/
Treated pine paling (150 x 12 mm) – each STS Timber Wholesale P/L n/a https://www.ststimber.com.au/sts-timber-wholesale-products/fencing
Wooden stakes (1200 x 17 x 17 mm) – 10 pack Lattice Makers n/a https://latticemakers.com/product/tomato-stakes-17x17mm-pack-of-10/
DOWNLOAD MATERIALS LIST

Riferimenti

  1. Epsky, N. D., Morrill, W. L., Mankin, R. W., Capinera, J. L. Traps for Capturing Insects. Encyclopedia of Entomology. , (2008).
  2. Catanach, T. A., Silvy, N. J. Invertebrate sampling methods for use in wildlife studies. The Wildlife Techniques Manual. 1, 336-348 (2012).
  3. Montgomery, G. A., Belitz, M. W., Guralnick, R. P., Tingley, M. W. Standards and best practices for monitoring and benchmarking insects. Frontiers in Ecology and Evolution. 8, 579193 (2021).
  4. Haddock, J. K., Threlfall, C. G., Law, B., Hochuli, D. F. Light pollution at the urban forest edge negatively impacts insectivorous bats. Biological Conservation. 236, 17-28 (2019).
  5. Steinbauer, M. J. Using ultra-violet traps to monitor autumn gum moth, Mnesampela private (Lepidoptera: Geometridae), in south-eastern Australia. Australian Forestry. 66 (4), 279-286 (2003).
  6. Wakefield, A., Broyles, M., Stone, E. L., Harris, S., Jones, G. Quantifying the attractiveness of broad-spectrum street lights to aerial nocturnal insects. Journal of Applied Ecology. 55, 714-722 (2017).
  7. Williams, C. B. The time of activity of certain nocturnal insects, chiefly Lepidoptera, as indicated by a light-trap. Transactions of the Entomological Society of London. 83 (4), 523-555 (1935).
  8. Bolliger, J., Collet, M., Hohl, M., Obrist, M. K. Automated flight-interception traps for interval sampling of insects. PLoS ONE. 15 (7), 0229476 (2020).
  9. Grubisic, M., van Grunsven, R. H. A., Kyba, C. C. M., Manfrin, A., Hölker, F. Insect declines and agroecosystems: does light pollution matter. Annals of Applied Biology. 173, 180-189 (2018).
  10. Owens, A. C. S., Lewis, S. M. The impact of artificial light at night on nocturnal insects: a review and synthesis. Ecology and Evolution. 8 (22), 11337-11358 (2018).
  11. Rydell, J. Exploitation of insects around streetlamps by bats in Sweden. Functional Ecology. 6, 744-750 (1992).
  12. Bolliger, J., Hennet, T., Wermelinger, B., Blum, S., Haller, J., Obrist, M. K. Low impact of two LED colors on nocturnal insect abundance and bat activity in a peri-urban environment. Journal of Insect Conservation. 24, 625-635 (2020).
  13. Rodríguez, A., Orozco-Valor, P. M., Sarasola, J. H. Artificial light at night as a driver of urban colonization by an avian predator. Landscape Ecology. 36, 17-27 (2021).
  14. Hienton, T. E. Summary of investigations of electric insect traps. United States Department of Agriculture. , (1974).
  15. Johnson, C. G. A suction trap for small airborne insects which automatically segregates the catch into successive hourly samples. Annals of Applied Biology. 37 (1), 80-91 (1950).
  16. Hutchins, R. E. Insect activity at a light trap during various periods of the night. Journal of Economic Entomology. 33 (4), 654-657 (1940).
  17. Nagel, R. H., Granovsky, A. A. A turn-table light trap for taking insects over regulated periods. Journal of Economic Entomology. 40 (4), 583-586 (1947).
  18. Hill, C. J., Cemak, M. A new design and some preliminary results for a flight intercept trap to sample forest canopy arthropods. Australian Journal of Entomology. 36, 51-55 (1997).
  19. Lamarre, G. P. A., Molto, Q., Fine, P. V. A., Baraloto, C. A comparison of two common flight interception traps to survey tropical arthropods. ZooKeys. 216, 43-55 (2012).
  20. Wilkening, A. J., Foltz, J. L., Atkinson, T. H., Connor, M. D. An omnidirectional flight trap for ascending and descending insects. The Canadian Entomologist. 113, 453-455 (1981).
  21. Frost, S. W. Insects captured in light traps with and without baffles. The Canadian Entomologist. 90 (9), 566-567 (1958).
  22. Muirhead-Thompson, R. . Trap responses of flying insects: The influence of trap design on capture efficiency. , 287 (1991).
  23. Carrel, J. E. A novel aerial-interception trap for arthropod sampling. Florida Entomologist. 85 (4), 656-657 (2002).
  24. Steinbauer, M. J., Haslem, A., Edwards, E. Using meteorological and lunar information to explain catch variability of Orthoptera and Lepidoptera from 250 W Farrow light traps. Insect Conservation and Diversity. 5, 367-380 (2012).
  25. Recher, H. F., Majer, J. D., Ganesh, S. Seasonality of canopy invertebrate communities in eucalypt forests of eastern and western Australia. Australian Journal of Ecology. 21, 64-80 (1996).
  26. van Klink, R., et al. Meta-analysis reveals declines in terrestrial but increases in freshwater insect abundances. Science. 368, 417-420 (2020).
  27. Wagner, D. L. Insect declines in the Anthropocene. Annual Review of Entomology. 65, 457-480 (2020).
  28. Cardoso, P., et al. Scientists’ warning to humanity on insect extinctions. Biological Conservation. 242, 108426 (2020).
  29. Saunders, M. E., Janes, J. K., O’Hanlon, J. C. Moving on from the insect apocalypse narrative: Engaging with evidence-based insect conservation. BioScience. 70 (1), 80-89 (2020).
  30. Cardoso, P., Leather, S. R. Predicting a global insect apocalypse. Insect Conservation and Diversity. 12, 263-267 (2019).
  31. Owens, A. C. S., Cochard, P., Durrant, J., Perkin, E., Seymoure, B. Light pollution is a driver of insect declines. Biological Conservation. 241, 108259 (2020).
  32. Chapman, J. A., Kinghorn, J. M. Window traps for insects. The Canadian Entomologist. 87 (1), 46-47 (1955).
  33. Canaday, C. L. Comparison of insect fauna captured in six different trap types in a Douglas-fir forest. The Canadian Entomologist. 119, 1101-1108 (2012).
  34. Burns, M., Hancock, G., Robinson, J., Cornforth, I., Blake, S. Two novel flight-interception trap designs for low-cost forest insect surveys. British Journal of Entomology and Natural History. 27, 155-162 (2014).
  35. Basset, Y. A composite interception trap for sampling arthropods in tree canopies. Journal of the Australian Entomological Society. 27, 213-219 (1988).
  36. Russo, L., Stehouwer, R., Heberling, J. M., Shea, K. The composite insect trap: An innovative combination trap for biologically diverse sampling. PLoS ONE. 6 (6), 21079 (2011).
  37. Knuff, A. K., Winiger, N., Klein, A. -. M., Segelbacher, G., Staab, M. Optimizing sampling of flying insects using a modified window trap. Methods in Ecology & Evolution. 10 (10), 1820-1825 (2019).

Tags

Automated Flight Intercept TrapLight PollutionFlying InsectsTemporal Sub-samplingEcological StudyPolycarbonate RoofingCross BaffleAutomated Pet FeederSample TrayTreated Pine Fence Paling

Play Video
PDF
DOI
DOWNLOAD MATERIALS LIST
Citazione di questo articolo
Robert, K. A., Dimovski, A. M., Robert, J. A., Griffiths, S. R. Low-Cost Automated Flight Intercept Trap for the Temporal Sub-Sampling of Flying Insects Attracted to Artificial Light at Night. J. Vis. Exp. (178), e63156, doi:10.3791/63156 (2021).
Scarica citazione
Ristampe e autorizzazioni

View Video

To prove you're not a robot, please enter the text in the image below

CAPTCHA Image
Play CAPTCHA Audio
Refresh Image