Local-Scale Bat Guild Activity Di ﬀ ers with Rice Growth Stage at Ground Level in the Philippines

: High-ﬂying insectivorous bats, as wide-ranging generalist insectivores, are valuable consumers of high-altitude migrating pests of rice in Southeast Asia. Here, we documented the behavior of relatively low-ﬂying bats over irrigated rice to elucidate their potential role as predators of rice-associated pest insects in the Philippines. Speciﬁcally, we tested the local-scale e ﬀ ects of rice stage, particularly seedling and late vegetative stages, and time of night on acoustic activity of bats foraging near ground level within three functional guilds (based on foraging distance from background clutter). We also monitored bat activity from two 50 m-high towers to assess the vertical extent of relatively low-ﬂying guilds, as well as document high-ﬂying bat guild presence and temporal behavior. At ground level, the most active guild biased their activity and feeding over early growth stage ﬁelds, but also foraged at tower level. Activity of the bat guild adept at foraging closest to vegetation did not vary with time of night or rice stage and was absent from tower recordings. High-ﬂying bats were predictably rare at rice level, but exhibited high foraging intensity at 50 m. Given the well-documented, sequential arrival of insect guilds with growth stage, these data suggest that at ground level edge-space bats may be important consumers of detritivores (e.g., mosquitoes). Moreover, our data suggest that just as habitat heterogeneity enhances the services of arthropod predators, these management practices also enhance bat activity and, presumably, their contribution to pest suppression. A.M.S., B.H.; methodology, J.L.S., A.M.S.; formal J.L.S. F.G.H.; investigation, J.L.S., A.C.J., P.A.A. J.D.V.A.; resources, A.M.S., and B.H.; writing—original draft preparation, J.L.S.; writing—review editing, F.G.H. and A.M.S.; visualization, J.L.S. and F.G.H.


Field Site and Rice Growth Stages
We conducted this study within the International Rice Research Institute's (IRRI) 200-hectare farm in Laguna Province, Luzon, Philippines (14.167774 • E, 121.254547 • N; Figure 2). The farm is in close proximity to a diversity of land use types, including residential (Los Baños city, 112,008 residents; 2015 census), lowland and montane second growth forest within the 4244-hectare Makiling Forest Reserve (ASEAN Heritage Site), coconut groves, agro-forest and privately owned irrigated rice fields to the east and northeast. This makes our study site typical of other lowland rice growing areas in the Philippines, especially on Luzon Island. Sampling occurred during the second month of the wet season (July-August) rice crop when planted rice was prominent in the landscape. The average daily weather (2015, 2016 ± standard deviation), including temperature (28.5 ± 0.5 • C, 29.3 ± 0.8 • C), rainfall (8.0 ± 15.16 mm, 3.5 ± 7.0 mm), and wind speed (1.1 ± 0.27 m/s, 1.1 ± 0.6 m/s) were similar during the 2015 and 2016 sampling periods (IRRI Climate Unit), and were similar to annual averages for the region [57]. Despite its intensive cultivation, the IRRI research farm maintains a high diversity of vertebrate and invertebrate wetland species [2,4,39]. We conducted this study within the International Rice Research Institute's (IRRI) 200-hectare farm in Laguna Province, Luzon, Philippines (14.167774° E, 121.254547° N; Figure 2). The farm is in close proximity to a diversity of land use types, including residential (Los Baños city, 112,008 residents; 2015 census), lowland and montane second growth forest within the 4244-hectare Makiling Forest Reserve (ASEAN Heritage Site), coconut groves, agro-forest and privately owned irrigated rice fields to the east and northeast. This makes our study site typical of other lowland rice growing areas in the Philippines, especially on Luzon Island. Sampling occurred during the second month of the wet season (July-August) rice crop when planted rice was prominent in the landscape. The average daily weather (2015, 2016 ± standard deviation), including temperature (28.5 ± 0.5 °C, 29.3 ± 0.8 °C), rainfall (8.0 ± 15.16 mm, 3.5 ± 7.0 mm), and wind speed (1.1 ± 0.27 m/s, 1.1 ± 0.6 m/s) were similar during the 2015 and 2016 sampling periods (IRRI Climate Unit), and were similar to annual averages for the region [57]. Despite its intensive cultivation, the IRRI research farm maintains a high diversity of vertebrate and invertebrate wetland species [2,4,39].
During both years, rice seedlings were manually transplanted within roughly a six-week window in the wet season (July-August). This resulted in a patchwork of fallow and planted fields at various stages of vegetative growth (i.e., ranging from seedling stages to panicle initiation) during the study period. This offered an opportunity to sample bat activity over various stages of rice production simultaneously, from fallow rice fields dominated by grasses ( Figure 2E), to rice paddies approaching the reproductive growth stage ( Figure 2D). Varieties, including the size of patches vary considerably as plant breeding is a major component of the institute's research program. However, the management of rice crops by a single dedicated support team ensures that chemical inputs are generally consistent.  During both years, rice seedlings were manually transplanted within roughly a six-week window in the wet season (July-August). This resulted in a patchwork of fallow and planted fields at various stages of vegetative growth (i.e., ranging from seedling stages to panicle initiation) during the study period. This offered an opportunity to sample bat activity over various stages of rice production simultaneously, from fallow rice fields dominated by grasses ( Figure 2E), to rice paddies approaching the reproductive growth stage ( Figure 2D). Varieties, including the size of patches vary considerably as plant breeding is a major component of the institute's research program. However, the management of rice crops by a single dedicated support team ensures that chemical inputs are generally consistent.

Acoustic Sampling
On 11 nights in 2015 (between 27 July and 7 August) and 10 nights in 2016 (between 21 July and 7 August), two to four ultrasonic detectors were placed beside rice fields that were at various rice crop production stages. We sampled four stages, including flooded fields during land preparation (Water; Figure 2B), seedling/early vegetative stage (Early, <50% cover; Figure 2C), late vegetative stage (Late, >50% cover; Figure 2D), and fallow fields that had dense grassy vegetation (Grass; Figure 2E). Each night, we opportunistically selected rice fields within one of the four main areas of the research farm ( Figure 2). We placed the ultrasonic detectors in pairs-with one of each pair placed in a flooded rice field with low vegetation and canopy cover (either Water or Early) and the other placed in a flooded field with high vegetation and high canopy cover (Grass or Late) (see Table A1 for sampling details). In total, we acoustically sampled approximately 130 hectares of the IRRI farm.
Regardless of the year, the calibrated microphones were placed at an approximate height of 1 m above the ground, pointed at 45 • above horizontal, and programmed to passively monitor between 18:00 and 06:00 h. On any given night, all detectors were in the same research farm area, but were a minimum of 100 m apart (173 median distance). Detectors were moved nightly. During 2015, we deployed two to four calibrated Anabat SD2 passive monitoring detectors (Titley Scientific) in weather-proof housings (plastic ammunition box with a short PVC elbow connector) over 11 nights, including 5 detector-nights in Water fields, 14 detector-nights in Early fields, and 17 detector-nights in Late fields. During the 2016 sampling, we deployed two full-spectrum ultrasonic detectors (SM4Bat, Wildlife Acoustics) with SMM-U1 microphones (with directional horns to protect microphones from rain) for 10 nights, over 11 nights, including 1 detector-night in a Water field, 8 detector-nights in Early fields, 8 detector-nights in Late fields, and 2 detector-nights in a Grass field. In 2016, we added Grass sampling to expand the range of available habitats sampled and switched to full-spectrum detectors in order to capture echolocation pulses nested in background noise more reliably than is possible with a zero-crossing analysis system. On four additional nights, we mounted one detector each on two 50-m tall radio towers on the farm (0.62 km apart; Figure 2). The SMM-U1 microphones (with directional horns) were pointing 90 • from vertical, horizontal to the ground. The directional horns result in a 20-25 dB loss in sensitivity for signals at 20 and 40 kHz, respectively, at 90 • off axis (https://www.wildlifeacoustics.com/images/pdfs/UltrasonicMicrophones.pdf), which minimized the potential overlap in the vertical space sampled with microphones placed near the ground. On all nights, the SM4Bat detectors were programed with the following settings: gain = 12 dB, sampling rate = 256 kHz, minimum duration = 1.5 ms, minimum trigger frequency = 16 kHz, trigger level = 12 dB, trigger window = 3 s, maximum length = 5 s. This resulted in 744 detector-hours-408 in 2015 and 240 at ground level and 96 at 50 m in 2016. While the detection distance from the microphones will vary depending on bat source levels and their orientation to the microphone [58], microphone sensitivity, and environmental conditions (temperature and relative humidity) [59], we can safely assume that we were only detecting bats < 50 m above the rice. For example, the SMM-U1 microphone theoretically can detect a 40 kHz-calling bat with a 94 dB SPL source level at around 20 m when it is flying on-axis with the microphone [60].

Assignment of Bats to Functional Guilds
The functional role of bats as consumers of insect pests depends on adaptations for prey localization and capture in different habitat types [28,29,61]. Twenty-eight insectivorous bat species have been documented in Laguna Province [27,62]. We classified those potentially active over IRRI rice fields (i.e., excluding those with strong forest associations that have not been documented over rice) into three previously described functional guilds according to their habitat use and corresponding echolocation call characteristics: open-space, edge-space, and narrow-space foragers [28]; Table 1. However, unlike Schnitzler and Kalko [28], we grouped potentially trawling species (i.e., those capturing insects either on or very near the water surface) in the genus Myotis as narrow-space foragers rather than edge-space trawling bats. This scheme aligns each guild clearly with relative vertical air space above the ground. Table 1. Ranges of physical and acoustic measurements characterizing bat species documented within or near the study site and their functional group classification. Sample sizes are all > 10, and represent individuals for the physical traits and call pulses for acoustic traits. 1 Heaney et al. [27]; 2 from free-flying bats in this study; 3 Sedlock et al. [63]; 4 minimum frequency from zero-crossing recordings, Sedlock [62]; 5 from bats captured in this study; 6 recorded from free-flying bats in a large (10 × 5 × 5 m tunnel traps on Mt. Banahaw, unpublished data; 7 hand released free flying bats in this study; 8 recorded from hand-held bats on Mt. Makiling, unpublished data; 9 recorded from free-flying bats over a river on Mt. Makiling, unpublished data.

Analysis of Echolocation Calls
Given the uncertainty of species-level auto-identification algorithms, especially in a region where robust call libraries are lacking [64], poor signal to noise ratios due to ultrasonic insect chorusing in the rice paddies (Tettigonidae), and our desire to document feeding buzzes (i.e., rapid series of acoustic pulses typically preceding an insect capture) that are generally low intensity, we manually inspected every recording. We defined a bat pass as a sequence of greater than two calls within one saved file (maximum length = 15 s (2015) and 5 s (2016). However, for the 2015 Anabat-generated zero-crossing recordings we expedited this process by first scanning the files in Analook W software (Chris Corben, version 4.2n 2017) with custom-made filters. Filters separated the files with bat calls (i.e., >2 calls minimum, at least 1 ms in duration) into groups based on characteristic frequency (i.e., portion of the call with the least frequency modulation). Subsequently, all files were inspected to confirm classification, document taxon-specific feeding buzzes, and low-intensity, broadband calls characteristic of Myotis spp. that often are excluded by the filter. Full spectrum call files were manually inspected within Avisoft-SASLab Pro (version 5.2.12, Avisoft Bioacoustics; settings: FFT = 512, frame = 75%, window = Flat top, frequency resolution = 0.5 ms) for phonic types and the presence of feeding buzzes.
In order to sample a smaller volume of air space around the tower-mounted microphones and avoid counting passes from bats flying closer to the ground, we amplitude filtered the bat passes using Avisoft SASLab Pro batch processing by setting the element detection at −30 dB from full scale (i.e., the maximum sine wave without overloading). This resulted in a subset of the hand-vetted files with bat passes present for sorting into phonic type classes. Given differences in peak frequencies, the "detection volume" will vary among phonic types due to frequency-dependent atmospheric attenuation. Nevertheless, these data should more accurately represent the bat activity at tower-level than the hand-vetted files.
Bat passes were classified as belonging to the open-space guild if they were long duration (>5 ms) and low frequency (<29 kHz). Passes were classified as edge-space guild if they were frequency modulated (i.e., each call sweeps through a range of frequencies), had a distinct quasi-constant frequency terminal end to the call, and had a peak frequency (frequency with most energy) or characteristic frequency > 30 kHz (see Table 1). Narrow-space guild calls included all broadband, short duration (≤3 ms) calls characteristic of gleaning/trawling FM bats (e.g., Myotis horsefieldii) [65] and constant frequency (i.e., pure tone) calls with either or both initial and/or terminal downward sweeps (i.e., Hipposideridae, Rhinolophidae). Some bats have highly flexible call structures, which they modify according to environmental clutter and prey density [66]; nevertheless, our categorization of guilds based on call structure is intentionally conservative to encompass this variability. Species within the families Rhinolophidae and Hipposideridae, as well as Myotis spp. (M. horsfieldii and M. rufopictus), and Miniopterus australis [62,63] are acoustically distinct; therefore, we reported these phonic types separately in addition to their inclusion in the pooled-species guilds.
For each phonic type-either functional guild or acoustically distinct species-we generated three response variables. These included the total bat activity, calculated as the total number of passes per hour, and bat occurrence, calculated as the proportion of one-minute intervals containing a bat pass within each hour (i.e., number of bat-present minutes/60 min). Acoustic activity is not equivalent to bat density; however, the latter index minimizes the bias introduced by circling bats [67]. Therefore, total bat activity provides information on intensity of use (i.e., time spent flying over each growth stage), and bat occurrence provides a better estimate of bat density. We also calculated the total number of feeding buzzes per hour for each phonic type, and transformed this into a foraging intensity index by relating the number of buzzes per hour to the total number of passes per hour (i.e., number buzzes/total number passes).

Bat Capture and Recording Reference Calls
To confirm species identification of acoustically recorded bats and to record voucher calls when possible, we opportunistically captured bats on and adjacent to the IRRI farm using mist nets and roost searches, especially in buildings. We used 6-, 12-and 20-m-long (2.6 m high) mist nets set in various locations, including parallel to the rice field along the bund, across the rice field from bund to bund, over a water reservoir, and across a small stream that ran through the farm. Netting occurred during peak bat activity between 18:00 and 22:00 h. Our total netting effort over three years (2014-2016; we began documenting species present prior to the acoustic sampling) equaled 117 net-hours (net-hours = one 6 m net open for one hour). Roost searches consisted of visual observations and inquiries with building security personnel. We took standard measurements of captured bats and used Ingle and Heaney [68] for species identification. Bats were released at the site of capture. Reference recordings of four Scotophilus kuhlii were taken by releasing them over a stationary SM4Bat detector with SMM-U1 microphone at dawn, just after we saw the last bat in the sky and before the sun came up. One individual of Myotis rufopictus was recorded in a room (approximate width = 4 m, length = 8 m, height = 3 m). Taphozous melanopogan calls were measured from free flying bats outside their roost. M. rufopictus and T. melanopogan calls were recorded using an UltraSoundgate ultrasonic recorder (Avisoft Bioacoustics). We quantified call parameters from spectrograms generated in Avisoft SASLab Pro (FFT = 256, Window = Flat Top, Temporal resolution = 0.51 ms, 50% overlap). We used the automatic parameter measurement tool to measure the peak frequency at the start, end and peak amplitude of each call. Duration was measured at −20 dB below the maximum amplitude. Bandwidth was calculated by subtracting the end from the start peak frequency.

Arthropod Sampling
In order to assess the composition of available insect prey over rice fields during acoustic monitoring and to test for crop stage differences in aerial insect abundance, we used aerial sweep netting over Early and Late vegetative stages. On three evenings (between 19:00 and 20:00 h) and one predawn (between 04:30 and 05:00 h) in 2015, and on five evenings (between 19:00 and 20:00 h) and one predawn (05:00 h) in 2016, we walked along a bund while sweeping a net (diameter = 42 cm) 40 times at a height of approximately 1 m over the rice. Samples from Early and Late stages were collected either simultaneously by two people in each field (2016) or sequentially by one person (2015), and each pairing was selected within the same area of the research farm. Eight different fields across the farm (2015: Sites 1-3, 2016: Sites 1-4) were sampled in both years. We transferred captured insects to vials containing 80% ethanol. Insects were identified to the highest taxonomic level possible by professional technicians using an extensive reference collection that has resulted from years of entomological research at IRRI.

Statistical Analysis
In order to provide a summary of overall activity in all crop production stages sampled, we standardized for differences in sampling effort by calculating the relative total activity (total number of passes/sampling hours) for each phonic type (by guild and species). Given limited sampling nights in Water and Grass growth stages, we only included Early and Late growth stage sampling in our statistical models. We analyzed the data for each year separately, because we deployed different acoustic detectors each year. When there were two detectors in the same rice stage within a site (2015), we averaged the values. We tested the distribution fit of response variables, including total bat activity, proportion bat occurrence, and proportion foraging intensity, and regression residuals for each guild using histograms and qqplots in R [69]. Edge-space proportion occurrence was the only response variable that approximated a normal distribution, and bat activity and foraging activity recorded from towers approximated a Poisson distribution after a square root transformation. All other variables were transformed into binary response variables for statistical models (i.e., presence or absence of a pass or buzz per sampling hour) for analysis.
The responses of bat guild activity to rice stage (Early vs. Late) and time of night (12 h intervals between 18:00 and 06:00 h) were analyzed using generalized linear mixed effect models using the lme4 package in R (lme4 version 1.1-18-1). We used lmer to test the response of edge-space occurrence to stage and time. We used glmer to model the Poisson response of edge-space total activity using a log-link function, and the binomial responses of edge-space foraging, narrow-space occurrence, and open-space occurrence using a logit-link function. There were too few narrow-space and open-space feeding buzzes for analysis. For all models, site was set as a random effect given that each area of the experimental farm had unique attributes that may influence bat activity, such as the size and configuration of fields, number of adjacent buildings, and distance from forest. We also set night as a random effect in all models. All glmer models were fit with maximum likelihood using the Laplace approximation. We tested for over-dispersion using the overdisperse_fun function. For tower recordings, we tested the response of bat activity and foraging activity separately for each guild (edge-and open-space) on the fixed effects of hour and tower using a generalized linear negative binomial model. The contributions from different insect feeding guilds (i.e., detritivores, herbivores, predators) to the aerial arthropod communities over rice fields were examined using three dimensional contingency tables with insect guild, crop stage and time of day as dimensions. Tests of mutual and partial independence as well as comparative frequencies were conducted using chi-squared analyses. Samples from the 2015 and 2016 wet seasons were combined because of low numbers of insects captured.

Bat Assemblage
Our netting effort over and adjacent to rice fields yielded 28 captures of three species, including the Philippine orange-fingered myotis (Myotis rufopictus, 1 individual), the lesser Asian house bat (Scotophilus kuhlii, 24 individuals), and the Javan pipistrelle (Pipistrellus javanicus, 2 individuals) ( Table 1). We also captured one arcuate horseshoe bat (Rhinolophus arcuatus) in a net across a small stream. We located two large Scotophilus kuhlii colonies in buildings near the research farm, and captured 77 individuals (adult females = 26, adult males = 28, juveniles = 23) exiting or returning to the roost. Additionally, we located a small colony of Pipistrellus javanicus in another building, from which we captured 10 adult females.

Bat Activity by Rice Stage and Time
During both sampling years, we acoustically detected representatives from each bat guild in all sampled growth stages at ground level ( Table 2). Edge-space bat calls comprised 89% of all calls recorded, followed by open-space (10%), and narrow-space (1%) bat calls ( Table 2). Myotis spp. calls made up the largest proportion of detected narrow-space activity, followed by Hipposideros diadema and Rhinolophus macrotis. The relative total and foraging activity of edge-space bats during both years was highest over early stage rice, followed by water and late stage rice. Narrow-space and open-space bats exhibited substantially lower relative activity levels across all habitats than edge-space bats. Table 2. Total bat passes recorded from ground level, relative bat activity (total no. bat passes/no. hours) and relative feeding activity (total no. buzzes/no. hours) by rice growth stage for each guild and acoustically distinct taxa within each guild. Water = tilled and water-filled paddy pre-planting, Early = seedling and early vegetative (i.e., canopy < 50%), Late = late vegetative (i.e., canopy > 50%), Grass = grass-filled fallow paddy. Species abbreviations as in Table 1. Total activity, occurrence and foraging intensity of edge-space bats was significantly higher in early compared to late stage paddies in both sampling years (Table 3, Figures 3 and 4). This difference across all response variables was associated with hour of the night in 2015, but not in 2016. Specifically, bats had an early-stage bias only during the first half of the night. In contrast, narrow-space bat presence was not associated with stage or hour. There was a significant stage, not hour, effect for open-space foragers; bats were more likely present over early stage compared to late stage paddies. Table 3. Results of statistical analyses showing the effects of hour and stage on edge-space bat occurrence, edge-space bat total activity, edge-space bat foraging, narrow-space bat presence, and open-space bat presence. Degrees of freedom (df) = 1 for all models. P = p-value with: n.s. = non-significant, * = < 0.05, ** = < 0.01, *** = < 0.001. SE = standard error.

Aerial Arthropod Abundance and Composition by Stage
Only 240 arthropods were captured during the sweepnet sampling. Midges (Culicidae) were among the most commonly captured species (Table A2). The frequencies of species representing each guild were not independent of time of day or crop stage (species: χ 2 = 8.707, P = 0.121; Figure 6A), but the numbers captures across guilds did differ according to time of day and crop stage (numbers of individuals: χ 2 = 19.098, P = 0.002; Figure 6B). This was due to a higher abundance of detritivores (making up 64-89% of captures), particularly midges in all samples despite relatively lower detritivore species richness in the samples (36-67%) and declining relative richness of the detritivore group during the late crop stages ( Figure 6C,D).

Aerial Arthropod Abundance and Composition by Stage
Only 240 arthropods were captured during the sweepnet sampling. Midges (Culicidae) were among the most commonly captured species (Appendix B). The frequencies of species representing each guild were not independent of time of day or crop stage (species: χ 2 = 8.707, P = 0.121; Figure  6A), but the numbers captures across guilds did differ according to time of day and crop stage (numbers of individuals: χ 2 = 19.098, P = 0.002; Figure 6B). This was due to a higher abundance of detritivores (making up 64-89% of captures), particularly midges in all samples despite relatively lower detritivore species richness in the samples (36-67%) and declining relative richness of the detritivore group during the late crop stages ( Figure 6C,D).

Discussion
Overall, this study revealed a rice growing area with high bat activity and-based on phonic diversity-a rich assemblage of insect consumers comprised of bats in all three functional groups. However, edge-space bats were by far the most frequently recorded guild at ground level, and caught in mist nets. While most recorded species were expected, one represented a new record for Laguna Province (Myotis rufopictus), recorded previously from adjacent Quezon Province [70]; and others  Table A2 for further details.

Discussion
Overall, this study revealed a rice growing area with high bat activity and-based on phonic diversity-a rich assemblage of insect consumers comprised of bats in all three functional groups. However, edge-space bats were by far the most frequently recorded guild at ground level, and caught in mist nets. While most recorded species were expected, one represented a new record for Laguna Province (Myotis rufopictus), recorded previously from adjacent Quezon Province [70]; and others were surprising given that they are forest-associated species (Rhinolophus macrotis and Hipposideros diadema) [27]. We could not identify one Rhinolophus-like echolocation call (i.e., constant frequency with initial and terminal frequency-modulated sweeps) to species; however, it had a peak frequency similar to another forest species, R. rufus, recorded on Bohol Island (peak = 44 kHz; [63]). These data highlight both the importance of rice-dominated landscapes for bats, and the potential importance of bats as mobile consumers of rice-associated insect pests in the Philippines.
We predicted that edge-and narrow-space bats would be most active over late vegetative stage rice fields given that insect abundance accumulates with rice growth [10,38]; however, we found the opposite pattern in edge-space foragers that preferred early vegetative growth stages. Specifically, edge-space bats were more active, foraged more intensely, and were possibly more abundant (i.e., occurrence) over early stage fields. These bats also foraged at both dawn and dusk, when insects were also active over the rice fields, albeit at relatively lower levels at dawn compared to dusk. Edge-space bats respond to insect availability at landscape [71] and local-scales, e.g., [72,73]; therefore, it may be that insects available to bats are more abundant over early growth stages. However, our insect data show that aerial insects, especially adult detritivores (midges), are present over early and late vegetative stages equally, although this may be a consequence of our modest sampling effort. The early stage preference could also be a result of utilizing irrigated paddies for drinking, as bat activity is often associated with water [74]. However, this is unlikely given that edge-space bats exhibited a foraging preference (i.e., feeding buzzes) over early stage fields. Bats do emit a "drinking buzz" that lacks a terminal reduced frequency component (i.e., buzz II) [75], but our buzz counts included clear feeding buzzes indicating the bats were pursuing insects. Alternatively, bats may simply be avoiding the relatively complex background clutter of closed-canopy late stage fields. Complex background echoes can mask prey echoes, whereas smooth surfaces, such as water, can enhance prey echoes at close range [76]. This hypothesis is further supported by the low relative activity of edge-space bats over fallow grass-filled paddies. Or, it is possible that a combination of early stage prey availability, drinking, and late stage background echo avoidance all contribute to this behavior.
Regardless of the mechanism(s) driving the early-stage preference of edge-space foragers at ground level, this habitat preference has several implications for bats' potential role as consumers of rice-associated insect pests. First, this early stage foraging preference, combined with insect guild-rice stage associations ( Figure 1) and our own insect sampling, suggests that edge-space foragers are consuming more detritivores (and possibly arthropod predators) than herbivorous insects immediately over rice. Specifically, mosquitoes and midges begin emerging soon after transplanting and after the fields are flooded [47,53]. A landscape-scale study in Vietnam found that mosquito larvae and adults in houses adjacent to paddies were negatively associated with rice height and water depth [12], suggesting that mosquitoes may be at densities attractive to foraging bats during the seedling stage (although see [77]). Therefore, edge-space bat's early-stage preference concentrates bat feeding in locations that may enhance their service as natural enemies of mosquitoes. Diet studies of common edge space species (i.e., Scotophilus kuhlii and Pipistrellus javanicus) are needed to test this prediction. Secondly, it has been suggested that ultrasound-hearing insect pests in the families Pyralidae and Noctuidae (e.g., stemborers and armyworms) may alter their behavior in response to a soundscape rich in bat echolocation pulses [78]. For example, the Indian meal moth's (Plodia interpunctella, Pyrallidae) reproductive success declined when exposed to ultrasound pulses in the lab [79]. Our data show that the magnitude of the "soundscape of fear" effect on hearing insects is rice stage-specific, and may decline as rice matures. Third, just as local habitat complexity can influence rice-associated insects [80,81] and birds [8], our data highlight the influence of local-level habitat complexity in determining the composition and abundance of insectivorous bats foraging at ground level.
Unlike edge-space bats, narrow-space activity at ground level was relatively low and, in 2015, appeared to peak in the middle of the night. The absence of a distinct early evening foraging activity peak (prominent in edge-space activity), may indicate that they are not tracking overall aerial insect abundance that tends to peak at dawn and dusk over rice [71]. Narrow-space bats may be feeding on insects that are active in the middle of the night, such as many rice-associated moths [82][83][84]. Moreover, narrow-space bat echolocation is more clutter-tolerant [28], which would afford them access to prey on or immediately above rice-a zone that is functionally unavailable to the other two guilds. In fact, in Thailand, Myotis spp. were the most common bats recorded at ground level over rice [33], not the widespread edge-space foragers reported here. Rhinolophus macrotis, a horseshoe bat with large ears and a pure-tone echolocation call, made up a large proportion of total narrow-space bat calls. As a forest-associated bat [27,85], its regular activity over rice paddies was unexpected. However, this species is known to consume eared moths [86], which are associated with rice. In fact, virtually all of the economically important moth pests belong to families that have evolved effective anti-bat defenses-either ears (Pyrallidae and Noctuiidae) or defensive (or warning) clicks (Arctiidae)-to avoid bat predation [87,88]. Also surprising, was the regular occurrence of Hipposideros diadema, a large perch-hunting bat associated with forest, agroforest areas, and residential areas with vegetation for perching [27]. Myotis species were the most commonly encountered species within the narrow-space guild, and were detected foraging in all rice stages sampled. Lastly, while we provide clear acoustic evidence of narrow-space foraging over rice, we acknowledge that these data may be an under-estimate of total activity given that high frequency calls result in short-range detection, especially of low-intensity feeding buzzes. Moreover, we know little about these species' foraging strategies, and whether they employ alternative sensory modes (e.g., passive listening) to detect and localize prey (e.g., [89]).
Acoustic monitoring from 50-m tall radio towers revealed edge-space and open-space bats actively foraging throughout the night. While we did not simultaneously monitor at ground-and tower-levels, these data suggest that the foraging zone of some edge-space bats at our site extends to at least 50 m above ground level (AGL). The possible exception may be Miniopterus australis, whose acoustically distinct calls were not recorded from either tower; however, we do acknowledge that this could be due to low sampling effort. Other than M. australis, the recorded calls assigned to the edge-space guild recorded from the tower were similar to those recorded at ground level with respect to peak frequency (mean ± s.d = 42.19 ± 2.57, n = 467; 41.63 ± 1.86, n = 529, respectively), duration (mean ± s.d = 6.46 ± 2.86, 9.45 ± 5.26, respectively) and bandwidth (mean ± s.d = 5.74 ± 6.37, 5.92 ± 5.86, respectively). Given these call characteristics and our capture records, we suspect that most of these calls at groundand tower-level belong to Scotophilus kuhlii. In a high altitude bat survey in Thailand, S. kuhlii was not detected at 200 m AGL and was detected only once at 100 m AGL [33] suggesting that it may have an altitude limit around 100 m AGL. We also documented feeding activity of the open-space bat, Taphozous melanopogan, at tower level, which aligns with altitudinal records as high as 200 m AGL in Thailand [33]. The higher activity at Tower 1 may have resulted from artificial lighting around adjacent buildings, although edge-space foragers did not exhibit a Tower preference. Open-space bats were also detected at ground level, and unexpectedly, responded to rice growth stage. Given how few feeding buzzes were detected from ground-level recordings, this may indicate they were drinking from water-filled, open-canopy rice paddies. However, if this were the case, we might expect to have recorded drinking buzzes over paddies with exposed water. Video-based studies that visually capture behavior at ground level would confirm whether irrigated rice provides a water source for open-space bats.
Seemingly absent from the open-space forager guild were calls of free-tailed bats (Molossidae), specifically Chaerophon plicatus, which is an important natural enemy of planthoppers in Thailand [17,30,31]. Chaerophon plicatus calls recorded in Thailand overlap spectrally with T. melanopogan, especially at ground level where C. plicatus calls have a higher peak frequency [33]; therefore, we acknowledge the possibility for misidentification (which is why our analysis is at the guild level).
Nevertheless, the call structure of T. melanopogan is distinct in having a downward sloping terminal component and often multiple harmonics lacking in molossid calls [90]. We noted several instances of single harmonic calls terminating in a feeding buzz with clear, multi-harmonic, downward sloping series of pulses distinctive of T. melanopogan. Clearly, a detailed study of these species' call structure in sympatry is needed. Nevertheless, the Philippines has very few known C. plicatus colonies remaining, largely due to disturbance of caves through mining, guano collection, tourism, and bush hunting [27]. In contrast, T. melanopogan is a common species throughout the Philippines with broad roosting tolerances-from pristine sea caves to church bell towers [e.g., 63]. We found a large colony (>1000 individuals) roosting in an old gymnasium on the University of the Philippines campus adjacent to the IRRI research farm. An analysis of T. melanopogan diets throughout the rice growing cycle would reveal the extent to which they are contributing to migratory rice pest consumption at our study site.

Conclusions
Our study provides the first glimpse of the guild-specific behavior of insectivorous bats foraging over irrigated rice in the Philippines, and highlights the potential importance of edge-space bats, such as Scotophilus kuhlii and Pipistrellus javanicus, in consuming insects associated with early stage rice (e.g., mosquitoes). Moreover, bats' clear response to small-scale heterogeneity in vegetation structure suggests that local-scale cropping practices, including diversified cropping and ecological engineering that increase habitat complexity, may enhance bat foraging activity at ground level as well. However, just as some birds avoid bunds with tall vegetation [8], the form of vegetation on bunds may promote or inhibit pest-regulating services of bats depending on how they respond to introduced structural complexity. Given this, more information on the foraging strategies of bats near vegetation is warranted. Finally, the guild-specific behavior documented here can inform diet studies necessary to confirm bats' role in suppressing rice-associated insect pests. Appendix A Table A1. Acoustic monitoring sampling details. Night = 18:00-06:00 h, Date = date of the start of the sampling night, Site = area of farm (see Figure 1), Stage = rice growth stage (see Methods), No. of detectors = number of ultrasonic detectors in each site and stage; the data from two detectors in one site and stage per night were averaged for analysis, Detector type = the model of ultrasonic detector and microphone deployed.