China has a rich bat fauna, with > 100 species described (Smith & Xie, Reference Smith and Xie2008), and taxonomic research on bats has increased in the last 2 decades. Three new species have been described (Zhang et al., Reference Zhang, Han, Jones, Lin, Zhang and Zhu2007; Feng et al., Reference Feng, Li and Wang2008; Wu et al., Reference Wu, Motokawa and Harda2008) and the distribution of seven others revised substantially (He & Yang, Reference He and Yang1991; Zhao et al., Reference Zhao, Zhang, Zhou and Liu2002; Zhang et al., Reference Zhang, Zhang, Liang and Zhang2004; Zhang L.B. et al., 2005; Zhang J.S. et al., 2005; Feng et al., Reference Feng, Jiang, Li and Wang2006; Jiang et al., Reference Jiang, Liu and Feng2008; Tan et al., 2009). However, decreases in bat populations have become a matter of concern. Here we review the main problems that currently affect bats in China, including cave exploitation for tourism, pesticide use, loss of old buildings and use for food, and we make appropriate recommendations.

Cave tourism in China, especially in the south, has burgeoned. The effect of tourism on the environment in caves has been studied in China and elsewhere (Cigna & Forti, Reference Cigna, Forti and Kranjc1988; Song et al., Reference Song, Yang, Lin, Wang, Yu, Zhang and Tang1997). The flow of visitors causes fluctuations in carbon dioxide content and temperature, and cave topography and dimensions affect the accumulation and diffusion of the gas, disturbing bats directly (Song et al., Reference Song, Wei and Liang2000). On 2 May 2001, for example, the maximum CO₂ content increased from 1,000 to 7,000 ppm in the chamber in Baiyun Cave, Hebei, after c. 3,000 people visited for 5 hours, and the temperature increased from 16.8 to 19.6^oC (Song et al., Reference Song, Wang, Liang, Wei and Lin2004). In the last 20 years caves have been exploited for tourism and caving, without prior environmental impact assessments having been conducted (Song et al., Reference Song, Wang, Liang, Wei and Lin2004). The effects of disturbance on bats and other cave fauna have seldom been studied in China. Lighting schemes have been installed for visitors without any consideration of the effects on bats and other cave animals, paths have been constructed, and gates at cave entrances for managing visitors are often unsuitable for flying bats to negotiate. The population of fruit bat Rousettus leschenaulti in Yiling Cave in Guangxi Province, for example, decreased from c. 5,000 to < 2,000 after cave tourism was implemented in 1993 (L. Zhang & S. Zhang, pers. obs.).

Based on our surveys of bats in China, combined with enquiries to local people, we estimate that the bat population may have decreased by 60% in the last 30 years. Mortality of bats from pesticides has been well documented (Luckens & Davis, Reference Luckens and Davis1964; Bennett & Thies, Reference Bennett and Thies2007), although the effects of sub-lethal levels of pesticide on bat metabolism and survival has been little studied (Swanepoel et al., Reference Swanepoel, Racey, Shore and Speakman1999). The largest bat colony (of the mollossid Chaerephon plicata) known in China, at Feishu Cave, Guangxi Province, is estimated to have decreased from 1 million to 100,000 in the past 30 years (L. Zhang, pers. obs.). Local people near Feishu Cave told us that heavy crop yields could be obtained with little pesticide use 30 years ago, whereas more and more pesticides now have to be used to ensure similar yields. It is likely that the pests were formerly controlled by the large population of C. plicatus but that the increased use of pesticides caused the decrease of the bat population as a result of bioaccumulation (Schnoor, Reference Schnoor1981). Studies on pesticide levels in these bats would be illuminating.

Availability of suitable roost sites may limit bat distribution and abundance, and protection of roost sites is essential for bat conservation. Many bat species roost in old buildings (Kunz & Lumsden, Reference Kunz, Lumsden, Kunz and Fenton2003), which they select as maternity roosts (Williams & Brittingham, Reference Williams and Brittingham1997) or hibernacula (Whitaker & Gummer, Reference Whitaker and Gummer1992). The advantages for bats roosting in buildings (lower predation risk, earlier births, faster juvenile growth rates and increased energy savings) lead to greater long-term reproductive success (Lausen & Barclay, Reference Lausen and Barclay2006). During urbanization many old buildings were demolished and their replacements are not suitable as bat roosts, and in many areas in China no houses suitable for roosting bats remain. Little attention is paid to bat conservation during planning, and thus bats are not included in impact assessments for construction of new buildings.

Bats provide important ecosystem services, pollinating plants, dispersing seeds and controlling pests. However many people in China regard bats as vermin because some species feed on economically important fruits, such as longan and litchi. Bats are also regarded as nefarious animals because they fly in the dark. Before the emergence of the SARS virus many restaurants in Guangzhou and other cities in south China offered bats, and live bats were also sold in markets (Mickleburgh et al., Reference Mickleburgh, Waylen and Racey2009; L. Zhang & S. Zhang, pers. obs.). In some remote villages our surveys have repeatedly revealed that local people capture wild bats to eat, to meet their protein requirements (L. Zhang & S. Zhang, pers. obs.). We have also found bamboo wattles, used to kill bats, in caves (L. Zhang & G. Zhu, pers. obs.).

There are additional factors causing decreases of bat populations in China. Many forests were destroyed during the Cultural Revolution (1966–1976) and vast steel-making and iron-smelting facilities were established, resulting in the loss of many roosting sites and foraging areas. Recently, many small paper mills have been built, resulting in the clear-cutting of forests and their replacement with the fast growing eucalypts that are preferred by the mills (Zhang, Reference Zhang2008). We have found that many limestone hills excavated to make cement have lost their bat-roosting caves. No bat species are included in the lists of wildlife under special state protection (1989 Law of the People's Republic of China on the Protection of Wildlife), and no nature reserves protect bat species or their roost sites. Access to caves in which bats roost is unrestricted.

To prevent further declines of bat populations in China we make the following recommendations. (1) Education programmes about the importance of bats in providing ecosystem services should be available for adults and schoolchildren; the people and the government should be provided with more information so that they can participate in conservation of bats rather than eat them. (2) Local and national governments should enact laws to protect bats; the addition of threatened bat species to the lists of wildlife under special state protection in China would improve people's perception of bats. (3) Roosting sites should be protected, even from researchers, so that bats are not disturbed, especially during critical periods such as pregnancy, lactation and hibernation; exploitation of caves, demolition of old buildings, and quarrying of limestone hills should be subject to environmental impact assessments before work is conducted. (4) Farmers should use safer pesticides, both for their own health and the benefit of bats; this is especially important for the economy of people living in remote villages and for bats in such areas.

Some advances have already been made. Research on bats is now taking place in several Chinese universities. An award from the UK Darwin Initiative was important in developing a research and education centre to promote bat conservation close to Beijing. The Centre has a display area, dormitories, a kitchen and dining room, experimental rooms, bat housing facilities and a large flight area that has hosted a colony of fishing bats Myotis ricketti. The Centre has hosted postgraduate students and groups of schoolchildren. A bat research group has been established at the Institute of Zoology, Chinese Academy of Sciences in Beijing, at East China Normal University in Shanghai, and at Guangdong Entomological Institute in Guangzhou, under the direction of SZ. During tenure of the Darwin Initiative research was carried out on the taxonomic status of small horseshoe bats in Asia (Li et al., Reference Li, Jones, Rossiter, Chen, Parsons and Zhang2006), the diet, echolocation calls and genetics of the endemic Myotis pequinius (Jones et al., Reference Jones, Parsons, Zhang, Stadelmann, Benda and Ruedi2006), the large bat Ia io, discovered to feed extensively on birds by capturing them in flight (Thabah et al., Reference Thabah, Li, Wang, Liang, Hu, Zhang and Jones2007), genetic variation in greater horseshoe bats across their range, showing extensive genetic divergence of Chinese bats and the occurrence of two lineages with different echolocation calls in China (Rossiter et al., 2007), and description of a new species, Barbastella beijingensis, which was first captured near the Darwin Initiative Centre (Plate 1; Zhang et al., 2007).

Plate 1 Barbastella beijingensis, a recently described bat species (Zhang et al., Reference Zhang, Han, Jones, Lin, Zhang and Zhu2007), occurs in Fangshan, Beijing.

A web site describing the bat fauna of China was developed under the Darwin Initiative (Bats in China, 2009). The site includes photographs, range maps, echolocation call recordings and a bibliography covering 72 species. Articles about bats are appearing in the Chinese popular press and on national television. A guide for teachers about bat conservation is available in Hong Kong. Local people in Guangxi are being educated about the conservation of bats in the region's bamboo forests (Zhang, Reference Zhang2008). If these and other initiatives can be developed further there is yet hope for the conservation of bats in China despite the intense pressures associated with industrialization, urbanization and habitat loss.