Effect of sex, temperature, time and flock size on the diving behavior of the wintering Scaly-sided Merganser (<i>Mergus squamatus</i>)

Mingqin Shao; Bin Chen

doi:10.1186/s40657-017-0067-4

Volume 8 Issue 1

Dec. 2019

Turn off MathJax

Article Contents

Abstract

Introduction

Study area and methods

Results

Discussion

Acknowledgments

References

Avian Research > 2017 > 8(1): 9. > DOI: 10.1186/s40657-017-0067-4

Mingqin Shao, Bin Chen. 2017: Effect of sex, temperature, time and flock size on the diving behavior of the wintering Scaly-sided Merganser (Mergus squamatus). Avian Research, 8(1): 9. DOI: 10.1186/s40657-017-0067-4

Citation:

PDF (519 KB)

Effect of sex, temperature, time and flock size on the diving behavior of the wintering Scaly-sided Merganser (Mergus squamatus)

Mingqin Shao^,,
Bin Chen

College of Life Science, Jiangxi Normal University, Nanchang 330022, China

More Information

Corresponding author:
Mingqin Shao, 1048362673@qq.com
Received Date: 06 Oct 2016
Accepted Date: 16 Mar 2017
Available Online: 24 Apr 2022
Publish Date: 28 Mar 2017

Graphical Abstract

Abstract

Abstract

Background
The foraging and diving behavior of waterfowl are affected by a number of important factors. Hence, learning more about these major factors is of great concern in order to protect endangered species. In this study, we verified the effect of sex, temperature, time and flock size on the diving behavior of the Scaly-sided Merganser (Mergus squamatus).
Methods
The study was conducted by means of focal animal sampling in the Wuyuan section of the Poyang Lake watershed in Jiangxi Province, China from December 2015 to March 2016. We used one-way ANOVA and LSD tests to investigate the differences among these factors. Pearson correlations were used to test the relation between pause duration and the previous or subsequent dive duration. The relations between these factors and dive/pause duration are illustrated using Spearman correlations.
Results
Mean dive duration and mean time on the pause of males were significantly higher than those of females. With an increase in temperature, dive duration significantly increased. Along with the passage of time of year and daytime, dive duration significantly increased, while dive duration decreased significantly with the increase in flock size.
Conclusions
Sex, temperature, time and flock size have an effect on the diving behavior of the wintering Scaly-sided Merganser. The difference of diving behavior between males and females is related to differences in body mass. The difference of diving behavior among various temperatures and time periods may be related to a low minimum rate of oxygen consumption, while the difference among various flock sizes may be caused by rising intraspecific competition.
- Diving behavior,
- Flock size,
- Scaly-sided Merganser,
- Sex,
- Temperature,
- Time

FullText(HTML)

Introduction

With complex geographical and climatic conditions, the forest areas in southeastern Tibet are home to many species of Galliformes. Previous fauna surveys in the region, either by foreigners during earlier times (Bailey, 1914; Battye, 1935; Ludlow and Kinnear, 1944) or by Chinese ornithologists since the 1960s (Cheng et al., 1983), only provided general information about the occurrence of Galliforme species. To understand the conservation status of these species in primary forests, we should have more quantitative data on habitat use and population abundance. Moreover, Galliforme species are susceptible to habitat change and are often treated as indicators of ecosystem health (Fuller et al., 2000; Fuller and Garson 2000; Storch, 2000). Data from areas with original ecosystems may provide a baseline for assessing the degree of habitat degradation in contrast to these highly human-disturbed areas.

From May to October 1995, I investigated the habitat use of Galliformes in the upper Yigong Zangbu River, an area never explored by biologists. A further survey aimed at assessing the conservation status of the taxa in the area was made in May 2001.

Study area and methods

Fieldwork was carried out in the Sawang area (93°39′E, 32°24′N; Fig. 1), in Jiali county, southeastern Tibet, from May to October in 1995. Topographically, the study area is characterized by high mountains and deep canyons, with elevations ranging from 3700 to 6870 m, where most valley bottoms are less than 100 m wide. My survey area covered 32 km of the main valley and 14 km of three branches of the valley (Fig. 1). The vegetation is still original and varies vertically. On north-facing slopes < 4300 m in elevation, plant communities in the forest are dominated by Halfour spruce (Picea likiangensis) and between 4300–4800 m, by forests and scrubs of Rhododendron spp.; on south-facing slopes, between 3700–4300 m, the forest is dominated by Hollyleaf-like oak (Quercus aquifolioldes) between 4200–4700 m, by Tibetan juniper (Sabina tibetica) and at elevations > 4700 m, by alpine scrubs and meadows.

Figure 1. Spatial patterns of habitat in t survey area. Vertical lines: oak forests; crossed lines: spruce forests; circles: juniper forests; dots: Rhododendron shrubs; short oblique lines: alpine shrub-meadows; white sections: rocky zones; black sections: glaciers; thick lines: rivers and streams; black squares: villages.

DownLoad: Full-Size Img PowerPoint

Along the entire valley of 50 km, there are only five Tibetan villages, with a very low population density (one person per 100 km²). Farmland is restricted to the bottom of the mountains. The villagers cut the oaks near the foot of the mountains for firewood, resulting in secondary scrub oak forests.

Because the birds are shy in dense cover, I had few opportunities to catch sight of them. However, I found that feathers, fallen from their plumage, could survive for at least one month and were easy to identify in the field and distinguishable among species. The detection rate of feathers of each species in a defined habitat should be positively related with the number of birds and the time they spent in their habitat. Thus, encounter rates of molted feather samples were used as indicators of the relative abundance of Galliformes. The methodology of feather-counting was described by Lu and Zheng (2001). When collecting feather samples along the transects, I also noted individual birds, their flock size and membership. The data on individual sightings were provided in contrast to the results of feather-counting. I compared the flock size of each Galliforme species during the nesting period (late May to early July) to that in the chick-rearing period (mid-July to mid-October).

Results

All of seven species of Galliformes in the study area were found on south-facing slopes and only two species, the Chinese Grouse (Bonasa sewerzowi) and the Blood Pheasant (Ithaginis cruentus) also appeared on north-facing slopes (Table 1). A hybrid of the White Eared-pheasant (Crossoptilon crossoptilon) × the Tibetan Eared-pheasant (C. harmani) was the most predominant component of the Galliforme community, followed by Blood Pheasants and Chinese Grouse. These three species were relatively well adapted to the various types of vegetation in the area. Two other forest-dependent species, the Snow Partridge (Lerwa lerwa) and the Pheasant Grouse (Tetraophasis obscurus), were limited to the upper part of the forests with relatively low population densities, while a third species, the Crimson-bellied Tragopan (Tragopan temminckii) was only rarely sighted. Two meadow-dependent species, the Tibetan Snow Cock (Tetraogallus tibetanus) and the Tibetan Partridge (Perdix hodgsoniae), were relatively uncommon.

Table 1. Mean hourly encounter rates of Galliforme feather and individual (in parentheses) samples from the study area in summer

Habitat	Elevation (m)	Survey time (h)	Chinese Grouse	Snow Partridge	Tibetan Snow Cock	Pheasant Grouse	Tibetan Partridge	Blood Pheasant	Crimson-bellied Tragopan	Hybrid Eared-pheasant
Farmland	3700−3800	46.0					(0.04)
South-facing slopes
Secondary oak shrubs	3700−3900	39.6						0.05 (0.03)		0.81 (0.15)
Oak forest	3800−4300	82.2				0.02 (0.02)		0.09 (0.04)	0.02 (0.01)	3.21 (0.34)
Shrub-meadow above tree line	4300−4500	19.5								0.92
Juniper forests	4200−4700	62.0	0.70 (0.13)	0.03 (0.03)				1.00 (1.00)	0.03 (0.02)	1.69 (0.27)
Shrub-meadows above tree line	4600−4900	25.5		(0.04)	(0.04)					0.75 (0.24)
North-facing slopes
Spruce forests	3700−4300	16.6	0.12 (0.12)					0.18 (0.18)
Rhododendron	4300−4800	8.5						0.12
Shrub-meadows above tree line	4600−4900	7.0

| Show Table

DownLoad: CSV

The following provides further information about each species.

The Chinese Grouse: This survey discovered a new distribution of the species, which extends its range from 98°40′ to 93°39′E. In the survey area, often 2–5 birds (3.4 ± 0.3, n = 11) were encountered in their preferred habitat with streams and dense scrub, sometimes in small open plots in the forest, feeding or dusting. If suddenly disturbed, the birds fly up to nearby trees.

The Snow Partridge: In late June, three groups with five, five and six birds respectively were flushed from a juniper woodland close to the tree line, where their dusting sites were located. In late July, two birds were found in a scrub-grassland above the tree line.

The Tibetan Snow Cock: Because of limited time of investigation in its preferred habitat, i.e., high-elevation meadows with rocks, I only saw one group of seven birds. One young bird, caught, weighted 0.53 kg, suggesting that the date of egg-laying of this bird was early April.

The Pheasant Grouse: This bird limited its activities to the upper part of the forest dominated by oak but never moved out of the forest into the scrub-grassland above the tree line. If disturbed by dogs, this bird flew up to the top of trees. Its microhabitats consisted often of rocks and streams. Dusting sites beside a path visited by the birds were found at least three times.

The Tibetan Partridge: Despite considerable efforts in investigating this species in the alpine scrub-meadows, believed suitable for this bird, I did not manage to find a single bird there. Only one pair was continuously seen at the foot of the mountains from June through July.

The Blood Pheasant: The birds occurred in various habitats but their densities on south-facing slopes were higher than on north-facing slopes. They preferred microhabitats close to streams. Usually two birds (46.5%) (2.0 ± 0.3, ranging from 1–4, n = 11) remained together during the breeding season. I found in late September that these birds and Hybrid Eared-pheasants used the same dusting hollows. In winter, according to the villagers, flocks are formed of more than 10 individual birds, appearing at lower elevations.

The Crimson-bellied Tragopan: Only two single birds were found in an oak woodland and a dusting site in the juniper forest.

The Hybrid Eared-pheasant: This bird has the largest population among the Galliformes in the area and appeared in various habitats on south-facing slopes, with oak forests as its most preferred habitat. During the nesting period (May to July), flock size varied between 1 to 7 birds (2.9 ± 0.3, n = 43) and then increased (7.0 ± 1.0, 2–15, n = 14) during the brood-rearing period (August to October).

Discussion

My results showed that the Galliforme species in the study area tended to avoid coniferous forests dominated by Balfour spruce, an environment widely encountered on the eastern Qinghai-Tibet plateau and preferred by many species of Galliformes (Cheng et al., 1978; Johnsgard, 1999). The reason is thought to be that the climate in the woodland is so humid that ground-dwellers have difficulties in breeding and foraging (Lu and Zheng, 2001).

Before the 1980s, rifles were available to local people. It is generally known that game animals, including Galliformes, were frequently killed during that period. In the mid 1990's, the Firearm Law of the People's Republic of China was issued, forbidding anybody to own and keep any kind of gun privately. As a result, pressure from hunting of wildlife has declined considerably. However, trapping, especially by people from outside Tibet, has not been entirely prohibited, causing a certain loss of Galliformes. Oak-cutting in nearby villages has led to the emergence of second scrub oak forests, not suitable to Galliformes. To encourage local people to use firewood in more effective ways (for example by promoting more efficient stoves), is one means of reducing the loss of oak forests.

However, overall, because of low population densities, poor communication and less developed economies, as well as protection by local religious and government policies, Galliformes in the region have been facing relatively fewer threats. But it should be kept in mind that developing local economies and improved communication will inevitably pose a threat to wildlife. Therefore, development plans for unexplored areas should be carefully made, because once loss of biodiversity, derived from a long-term evolutionary trend, reestablishment is almost impossible.

I suggest for government agencies to establish a nature reserve in the region. This will prevent large-scale landscape use in the future and also provide a foundation for enhancing public conservation awareness. To aid conservation, further studies on the biology and ecology of the Galliformes are needed.

Acknowledgments

I would like to thank Duojicipei and his family for accommodation in the area. I am grateful to Bingyuan Gu, Soulong Ciren and Cangjue Zhuoma for their assistance in the survey. The field survey was supported by the Tibetan Bureau of Science and Technology, the National Natural Science Foundation of China (Grant No. 39800016) and the Tibet Important Bird Area Survey Programme organized by BirdLife International.

References (41)

References

Benvenuti S, Dall'Antonia L, Falk K. Diving behaviour differs between incubating and brooding Brünnichs guillemots, Uria lomvia. Polar Biol. 2002;25:474-8.

BirdLife International. Mergus squamatus. 2014. . Accessed 14 March 2017.

Bourget D, Savard JP, Guillemette M. Distribution, diet and dive behavior of Barrow's and common goldeneyes during spring and autumn in the St. Lawrence estuary. Waterbirds. 2007;30:230-40.

Boyd IL, Croxall JP. Dive durations in pinipeds and seabirds. Can J Zool. 1996;74:1696-705.

Butler PJ, Jones DR. The comparative physiology of diving in vertebrates. Adv Comp Physiol Biochem. 1982;8:179-364.

Clark CW, Mangel M. The evolutionary advantages of group foraging. Theor Popul Biol. 1986;30:45-75.

Cooper J. Diving patterns of cormorants Phalacrocoracidae. Ibis. 1986;128:562-70.

Costa DP. The relationship between reproductive and foraging energetics and the evolution of the Pinnipedia. Symp Zool Soc Lond. 1993;66:293-314.

Dewar JM. The bird as a diver. London: H.F. & G. Witherby, Ltd.; 1924.

Duncan K, Marquiss M. The sex-age ratio, diving behaviour and habitat use of Goldeneye Bucephala clangula wintering in northeast Scotland. Wildfowl. 1993;44:111-20.

Frere E, Quintana F, Gandini P. Diving behavior of the Red-legged Cormorant in southeastern Patagonia, Argentina. Condor. 2002;104:440-4.

Gomes A Jr, Pereira J Jr, Bugoni L. Age-specific diving and foraging behavior of the Great Grebe (Podicephorus major). Waterbirds. 2009;32:149-56.

Green JA, Boyd IL, Woakes AJ, Green CJ, Butler PJ. Do seasonal changes in metabolic rate facilitate changes in diving behaviour? J Exp Biol. 2005;208:2581-93.

Guillemette M, Woakes AJ, Henaux V, Grandbois JM, Butler PJ. The effect of depth on the diving behaviour of common eiders. Can J Zool. 2004;82:1818-26.

Halsey LG, Butler PJ, Woakes AJ. Breathing hypoxic gas affects the physiology as well as the diving behaviour of tufted ducks. Physiol Biochem Zool. 2005;78:273-84.

Halsey LG, Blackburn TM, Butler PJ. A phylogenetic analysis of the allometry of diving. Am Nat. 2006;167:276-87.

He FQ, Lin JS, Yang B, Jiang HD, Zhang HH. Current distribution and status of the wintering Scaly-sided Merganser Mergus squamatus in China. Chin J Zool. 2006;41:52-6 (in Chinese).

Ji Y, Bai CR, Zhang J, Zhang LW, Huang XP. The study on water resources carrying capacity in typical counties of Xinjiang River Basin, Poyang Lake. J Jiangxi Normal Univ (Nat Sci Ed). 2014;38:656-60 (in Chinese).

Jiang JH, Shao MQ. Diving behavior and difference of wintering little grebe and great crested grebe. Sichuan J Zool. 2015;34:719-24 (in Chinese).

Kato A, Watanuki Y, Shaughnessy P, Le Maho Y, Naito Y. Intersexual differences in the diving behaviour of foraging subantarctic cormorant (Phalacrocorax albiventer) and Japanese cormorant (P. filamentosus). C R l'Académie Sci Ser Ⅲ Sci la Vie. 1999;322:557-62.

Kato A, Watanuki Y, Naito Y. Annual and seasonal changes in foraging site and diving behaviour in Adélie penguins. Polar Biol. 2003;26:389-95.

Laich AG, Quintana F, Shepard ELC, Wilson RP. Intersexual differences in the diving behaviour of Imperial Cormorants. J Ornithol. 2012;153:139-47.

Liu Y, Yang ZJ, Zuo B, Yi GD. Wintering distribution and population size of scaly-sided Merganser Mergus squamatus in Jiangxi Province. J Northeast Normal Univ (Nat Sci Ed). 2008;40:111-5 (in Chinese).

Polak M, Ciach M. Behaviour of Black-throated Diver Gavia arctica and Red-throated Diver Gavia stellata during autumn migration stopover. Ornis Svecica. 2007;17:90-4.

Quintana F. Diving behavior of Rock Shags at a Patagonian colony of Argentina. Waterbirds. 1999;22:466-71.

Roberts G. Why individual vigilance declines as group size increases. Anim Behav. 1996;51:1077-86.

Ropert-Coudert Y, Kato A. Diving activity of hoary-headed (Poliocephalus poliocephalus) and Australasian little grebes (Tachybaptus novaehollandiae). Waterbirds. 2009;32:157-61.

Sato K, Mitani Y, Cameron MF, Siniff DB, Naito Y. Factors affecting stroking patterns and body angle in diving Weddell seals under natural conditions. J Exp Biol. 2003;206:1461-70.

Schreer JF, Kovacs KM. Allometry of diving capacity in air-breathing vertebrates. Can J Zool. 1997;75:339-58.

Shao MQ, Zeng BB, Hounsome T, Chen LX, You CY, Wang HB, Dai NH. Winter ecology and conservation threats of Scaly-sided Merganser Mergus squamatus in Poyang Lake Watershed, China. Pakistan J Zool. 2012;44:503-10.

Shao MQ, Shi WJ, Zeng BB, Jiang JH. Diving behavior of scaly-sided merganser, Mergus squamatus in Poyang Lake watershed, China. Pakis J Zool. 2014;46:284-7.

Shao MQ, Zhang XR, Dai NH, Guo YR, Gan WL, Tong LF, Jian MF, Tu YL. Preliminary study on behaviors of wintering Scaly-sided Merganser. Sichuan J Zool. 2010;29:984-5 (in Chinese).

Thompson SA, Price JJ. Water clarity and diving behavior in wintering common loons. Waterbirds. 2006;29:169-75.

Trillmich F, Ono K, Costa DP, De Long RL, Feldkamp S, Francis J, Gentry GL, Heath C, Le Boeuf BJ. The effects of El Niño on pinniped populations in the eastern Pacific. In: Trillmich F, Ono K, editors. Effects of El Niño on pinnipeds. Berlin: Springer; 1991. p. 247-70.

Wang S, Xie Y. The Chinese red list of threatened species. Beijing: Higher Education Press; 2009 (in Chinese).

Wanless S, Finney SK, Harris MP, McCafferty DJ. Effect of the diel light cycle on the diving behaviour of two bottom feeding marine birds: the blue-eyed shag Phalacrocorax atriceps and the European shag P. aristotelis. Mar Ecol Prog Ser. 1999;188:219-24.

Watanuki Y, Burger AE. Body mass and dive duration in alcids and penguins. Can J Zool. 1999;77:1838-42.

Wilson RP, Pütz K, Bost CA, Culik BM, Bannasch R, Reins T, Adelung D. Diel dive depth in penguins in relation to diel vertical migration of prey: whose dinner by candle light? Mar Ecol-Prog Ser. 1993;94:101-4.

Yi GD, Yang ZJ, Liu Y, Zuo B, Zhao J, Hao XL. Behavioral time budget and daily rhythms for wintering Mergus squamatus. Acta Ecol Sin. 2010;30:2228-34 (in Chinese).

Zeng BB, Shao MQ, Lai HQ, Jiang JH, Li C, Dai NH. The effects of gender and temperature on the wintering behavior of Chinese merganser. Acta Ecol Sin. 2013;33:3712-21 (in Chinese).

Zhao ZJ. A handbook of the birds of China. Changchun: Jilin Science and Technology Press; 2001 (in Chinese).

Cited By

Figures(1) / Tables(4)

Get Citation

PDF

XML

Article Metrics

Article views (297) PDF downloads (8)

	Xiaogang Yao, Neng Wu, Yan Cai, Canchao Yang. 2023: The effects of anthropogenic noise on nest predation with respect to predator species across different habitats and seasons. Avian Research, 14(1): 100121. DOI: 10.1016/j.avrs.2023.100121
	Xiyuan Guan, Xiaodong Rao, Gang Song, Daiping Wang. 2022: The evolution of courtship displays in Galliformes. Avian Research, 13(1): 100008. DOI: 10.1016/j.avrs.2022.100008
	Ángel Hernández. 2021: Habitat use and space preferences of Eurasian Bullfinches (Pyrrhula pyrrhula) in northwestern Iberia throughout the year. Avian Research, 12(1): 8. DOI: 10.1186/s40657-021-00241-0
	Xueqin Deng, Qingshan Zhao, Junjian Zhang, Andrea Kölzsch, Diana Solovyeva, Inga Bysykatova-Harmey, Zhenggang Xu, Helmut Kruckenberg, Lei Cao, Anthony David Fox. 2021: Contrasting habitat use and conservation status of Chinese-wintering and other Eurasian Greater White-fronted Goose (Anser albifrons) populations. Avian Research, 12(1): 71. DOI: 10.1186/s40657-021-00306-0
	Junjian Zhang, Yanbo Xie, Laixing Li, Nyambayar Batbayar, Xueqin Deng, Iderbat Damba, Fanjuan Meng, Lei Cao, Anthony David Fox. 2020: Assessing site-safeguard effectiveness and habitat preferences of Bar-headed Geese (Anser indicus) at their stopover sites within theQinghai-Tibet Plateau using GPS/GSM telemetry. Avian Research, 11(1): 49. DOI: 10.1186/s40657-020-00230-9
	Yanguang Fan, Lizhi Zhou, Lei Cheng, Yunwei Song, Wenbin Xu. 2020: Foraging behavior of the Greater White-fronted Goose (Anser albifrons) wintering at Shengjin Lake: diet shifts and habitat use. Avian Research, 11(1): 3. DOI: 10.1186/s40657-020-0189-y
	Ru Jia, Tian Ma, Fengjiang Zhang, Guogang Zhang, Dongping Liu, Jun Lu. 2019: Population dynamics and habitat use of the Black-necked Crane (Grus nigricollis) in the Yarlung Tsangpo River basin, Tibet, China. Avian Research, 10(1): 32. DOI: 10.1186/s40657-019-0170-9
	Shan Tian, Jiliang Xu, Jianqiang Li, Zhengwang Zhang, Yong Wang. 2018: Research advances of Galliformes since 1990 and future prospects. Avian Research, 9(1): 32. DOI: 10.1186/s40657-018-0124-7
	Meng Zheng, Lizhi Zhou, Niannian Zhao, Wenbin Xu. 2015: Effects of variation in food resources on foraging habitat use by wintering Hooded Cranes (Grus monacha). Avian Research, 6(1): 11. DOI: 10.1186/s40657-015-0020-3
	Zhiping Huo, Junfeng Guo, Xia Li, Xiaoping Yu. 2014: Post-fledging dispersal and habitat use of a reintroduced population of the Crested Ibis (Nipponia nippon). Avian Research, 5(1): 7. DOI: 10.1186/s40657-014-0007-5

Effect of sex, temperature, time and flock size on the diving behavior of the wintering Scaly-sided Merganser (Mergus squamatus)