Impacts of Climate Change on Birds and Measures
Nan Wang
a
Art and Science, University of Saskatchewan, Saskatoon S7N 5B2, Canada
Keywords: Climate Change, Birds, Migration Period, Distribution Measures.
Abstract: The global climate is increasing significantly, and the impact of climate change on biodiversity has become a
hot issue. The climatic environment is essential not only for human survival and development but also for the
survival and continuation of the entire biological community. As an indicator of the environment, the Birds
can reflect ecological changes sensitively, and the merits and demerits of the eco-environment also directly
affect the survival of birds. In this article, the major changes in the distribution, migration, breeding, and
population size of birds under global warming are summarized. Under the influence of climate change, the
distribution of birds shifts to higher latitudes or higher altitudes. The spring migration of birds is earlier than
before. Breeding and non-breeding sites are not moving in the same way, and the distribution of birds is
gradually decreasing. The spawning period of wild birds is earlier, and bird populations are reduced or even
extinct. Finally, this paper proposes some suggestions for coping with climate change by combining domestic
and international research experience and practical cases. In the context of global climate change, the
international community should attach great importance to climate issues and actively cooperate with each
other in compliance with international conventions. Citizens need to increase their awareness of
environmental protection. Scientists develop clean energy and pollution control technologies. In the future,
we should focus on the impacts of climate change on birds and establish a long-term effective monitoring
system.
1 INTRODUCTION
a
The global climate is undergoing significant changes.
The Fourth Assessment Report of the United Nations
Intergovernmental Panel on Climate Change (IPCC)
shows that global temperatures are generally rising,
with an average temperature increase of 0.74 °C over
the last 100 years; the rate of warming during the past
50 years is almost double that of the previous 100
years (A review of the practical problems resulting
from the impact of the climate warming on birds,
2001). Regional changes in rainfall have also
occurred, with a 5-10% increase in rainfall in the
northern hemisphere mid-and high-latitude regions,
as opposed to a 3% decrease in rainfall in the tropics
and subtropics (A review of the practical problems
resulting from the impact of the climate warming on
birds, 2001). In recent years, the impact of climate
change on birds has received increasing attention, and
a recent report by the World Wide Fund for Nature
(WWF) indicates that the survival of most birds is
a
https://orcid.org/0000-0001-6789-3219
under threat due to global climate change (A. Suman,
2021). Climate is one of the environmental factors
affecting the survival of organisms. The increase in
temperature will have an impact on species, mainly in
terms of changes in species distribution, phenology,
and population sizes, such as the distribution of some
plants and animals, the germination and flowering
periods of plant seeds, and the migration and breeding
periods of animals will change to different degrees
(Miller-Rushing, 2008). Birds are one of the most
active and visible components of the ecosystem. As
birds are highly sensitive to climate and weather
changes, the particular reason for this circumstance is
their high mobility.
Birds have commonly been viewed as pioneer
indicator species of the effects of climate change on
ecosystems (HITCH, 2007). Birds have historically
experienced multiple climate changes and have
adapted to their ecological habits. Climate change has
been identified as a critical driver in the formation of
bird migrations (Beale, 2013). The analysis of more
558
Wang, N.
Impacts of Climate Change on Birds and Measures.
DOI: 10.5220/0011235300003443
In Proceedings of the 4th International Conference on Biomedical Engineering and Bioinformatics (ICBEB 2022), pages 558-563
ISBN: 978-989-758-595-1
Copyright
c
2022 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
than 1,700 species revealed that recent changes in
biological distribution are consistent with climate
change predictions, with the global range shifting
6.1km poleward every 10 a and spring phenology
advancing 2.3 d every 10 a (Visser, 2001). Whether
many higher organisms, including birds, will be able
to adapt to the rapid climate change is still unknown.
Therefore, the survival prospects of birds are not
optimistic. Scientists have conducted numerous
studies on the impact of climate change on birds. A
recent study by the University of York increased the
rate of movement by a factor of 2-3, suggesting that
species such as birds move 16.9 km to the poles and
11.0 m to higher elevations every ten years (Both,
M.E.J.P.o.t.R.S.B.B.S. Visser, 2005). It has been
discovered that warming has shifted the distribution
of many bird species to polar regions or high
altitudes.
This paper investigates the effects of climate
warming on bird migration, breeding, population
size, population distribution and provides a reference
for further understanding of the effects of global
climate change on bird ecology. This article also
proposes a series of measures to mitigate global
warming and provide environmental protection for
birds' normal survival and reproduction.
2 IMPACT OF CLIMATE
CHANGE ON BIRDS
2.1 Changes in the Migration Period
The impact of climate change on the living
environment of birds is multifaceted. The influence
of climate warming on the choice of spring migration
time of birds is closely related. Under the influence
of climate warming, the spring migration period of
birds has changed significantly. In general, climate
change has different effects on the migration timing
of short- and long-distance migratory birds, e.g.,
species wintering south of the Sahara (after long-
distance migration) have been migrating earlier in
recent years. Compared to species wintering north of
the Sahara (after short-distance migration), which
have delayed their fall migration (Both, Bouwhuis,
2006). The migration time of birds that fly to southern
Lithuania for wintering is earlier for short- and long-
distance migratory birds. In contrast, short-distance
migratory birds leave their breeding grounds at a
more variable time than long-distance migratory
birds (Field, 2007). For example, the migration
period of the field sparrow bunting is about 17 days
earlier per decade (Parmesan, 2003). This remarkably
important trend was also found by Takuji Usui et al.
that the migration time advances with time. Takuji
Usui et al. also found this very substantial trend of
earlier migration over time. The tendency for early
spring migration was significant at higher
temperatures (Thomas, 1999).
Miller-Rushing et al. studied the interaction term
between U.S. temperature and mean arrival date and
overwintering area, showing that migration times of
species overwintering in the United States, Central
America, and the Caribbean tended to arrive earlier in
warmer years (Butler, 2010). In contrast, migration
times of late-arriving species in the United States
continued to change more rapidly with each unit
change in temperature. In each decade, the earliest
recorded spring arrival date was 0.20 days later for
each species. In contrast, the mean arrival date for
birds of each species was 0.78 days earlier per decade
(Butler, 2010). The autumn departure period of birds
has also changed, but changes in the autumn
migration period are more difficult to monitor and
more complex, occurring both earlier and later
(Miller-Rushing, 2008); (CHINESE JOURNAL OF
PUPULATION, RESOURCES AND
ENVIRONMENT, 2006). In contrast, Gordo et al.
found that the migration of birds from the Southern
Sahara to their breeding grounds in Spain was
delayed due to the warming of the wintering grounds
(Consistent response of bird populations to climate
change on two continents, 2016).
2.2 Breeding Changes
The spawning period of some birds has advanced
compared to the past. After studying 23 populations
of spotted grouse in Europe, Both et al. found that
nine species had an earlier egg-laying period, which
was associated with warmer spring temperatures
(CHINESE JOURNAL OF PUPULATION,
RESOURCES AND ENVIRONMENT, 2006).
Changes in the spawning period of the birds were
mainly related to changes in peak food abundance.
Due to climate change, the flowering period of some
plants and the breeding period of insects may
advance. Such changes are inconsistent with physical
changes in birds, altering the original normal food
chain relationships (Walther, 2002); (Crick, 1997),
resulting in the synchronization of adult or juvenile
birds with food availability and affecting their
survival (Crick, 2004). Food factors are an influential
cause of bird reproduction. Visser et al. found that
climate change altered the peak abundance of food
caterpillars in greater parus, ultimately leading to
Impacts of Climate Change on Birds and Measures
559
changes in the breeding season of greater parus
(Chen, 2011). Second, short-distance migratory birds
are vulnerable to temperature changes. Thus, in
general, the spawning period of short-distance
migratory birds is significantly more variable than
that of long-distance migratory birds (Influence of
climate change on the abundance, distribution and
phenology of woodland bird species in temperate
regions, 2010). Even though long-distance migratory
birds adapt to the effects of climate change, they also
change their migration period (Luhas, 2021). If spring
temperatures continue to rise, this shallow response
of migration timing to spring temperatures may act as
a hard constraint on the response of spawning dates
to breeding site temperatures, thus placing migratory
species at a disadvantage relative to resident species
(Thomas, 1999).
2.3 Population Size
Climate change not only changes the distribution and
phenology of species but also affects their population
changes, making populations smaller or even extinct.
Møller et al. found that birds that migrate long
distances do not adjust their migration period in time
to adapt to the new environment (Thomas, 1999).
Gasner et al. used models to predict population
changes of Mesoamerican birds under future climate
scenarios showing that almost half of the species'
populations will decline over the next century, with a
few species trending towards extinction
(Wormworth, 2006). The frequent occurrence of
extreme weather events, the spread of diseases, and
the invasion of exotic species due to climate change
also contributed to the changes in bird populations.
Extreme weather events affect the migration and
breeding success of birds (Sanz 2010). McKechnie
and Wolf predicted that warming-induced heat waves
would increase bird mortality in desert areas by 2080
(Sanz 2010). According to Garamszegi's study,
climate change has increased malaria incidence in
birds, leading to population declines (Jenni, 2003).
Some competitive exotic species also take the
opportunity to invade, leading to bird diseases,
reduced food availability, and population declines
(Influence of climate change on the abundance,
distribution and phenology of woodland bird species
in temperate regions, 2010).
2.4 Distribution Effects
In a natural state, the distribution areas of birds are
dynamic and flexible, even in the absence of climate
change. Many factors affect the spread and
distribution of birds. When climate change makes the
original habitat no longer suitable for survival, it will
force many species to shift and open up new
territories. For birds, climate warming is the
dominant influence in changing their range.
Theoretically, such dispersal and distribution should
be random. However, an obvious rule can be found
from the reports of new records of bird distribution in
recent years. The range of many bird species is
expanding northward, and this trend has increased in
recent years. A plausible explanation for the above is
that climate warming is causing birds to move
northward in their range. In Europe, Thomas and
Lennon studied changes in the distribution of bird
breeding sites in Britain. They found that species in
the northern region had moved an average of 18.9 km
northward by analyzing distribution data over the last
20 years (Joshi, 1992). For North America, Hitch and
Leberg studied changes in the distribution of 56 bird
species and found that birds in the northern range did
not expand southward, while birds in the southern
region moved northward by 2.35 km per year
(Garamszegi, 2011). Global warming will lead to a
significant reduction in the range of bird populations,
which may lose their entire range in the future (La,
Sorte, 2017). Steen et al. analyzed data from breeding
bird surveys. The distribution of five common
waterfowl species in the Prairie Pothole Region
(PPR) of the United States was predicted to decrease
by 64% for these five species. However, 100% of the
habitat would be lost for the black-faced vireo
(Porzana Carolina) 100% of the habitat would be lost
for the American bittern (Botaurus lentiginosus)
(Gasner, 2010). Jie Liang et al. evaluated the habitat
changes and populations of seven orders and 23
different species of the IUCN Red List of migratory
birds from 2014 to 2017 (2014-2017) based on the
maximum entropy approach (MaxEnt) model.
Habitat changes and population center shifts. Most of
the individual species in the study will move more
than 50 km, and all species will move to more suitable
sites (Gasner, 2010).
ICBEB 2022 - The International Conference on Biomedical Engineering and Bioinformatics
560
Table 1: Migration of Migratory Birds (M.R. Gasner, 2010).
Orders Shift direction Shift distance (km)
Total migratory birds Northeast 51. 01
PODICIPEDIFORMES Northeast 49. 00
CICONIIFORMES Northeast 24. 88
GRUIFORMES Northeast 66. 17
CHARADRIIFORMES Northeast 52. 74
LARIFORMES Northeast 73. 63
PELECANIFORMES Northeast 43. 55
3 MEASURES AGAINST GLOBAL
WA R MI NG
3.1 International Community and
Government Policies
Currently, global climate change is receiving
widespread attention from the international
community. Globally, 192 countries have joined the
UN Framework Convention on Climate Change
(Jonzen, 2006), a global climate protection
agreement, and signed the Kyoto Protocol in 1997,
pledging to jointly reduce greenhouse gas emissions
and help vulnerable regions cope with the disasters
caused by warming by 2012 (Gordo, 2010).
Formulate supporting laws, regulations, and
standards, and improve fiscal, tax, price, financial,
and other policy measures. Improve the management
system and monitoring and implementation
mechanism. In particular, increase the support and
backing in finance and science and technology. The
EU updated its bioeconomy strategy in 2018 to
accelerate development at the national level and keep
the economy in balance with the living world. Greater
emphasis has also been placed on increasing the
resilience of ecosystems and ensuring their
contribution to climate change mitigation and
biodiversity conservation. However, the
responsibility for mapping the interactions between
priority setting and goal setting rests with national
governments. More than 40 governments worldwide
have adopted explicit national strategies to advance
their bioeconomy sectors (Udomsri, 2011).
3.2 Responsibility of Citizens
Energy-saving, emission reduction, and combating
climate change also require the participation of all
human beings. Coping with climate change is the
shared responsibility of all human beings, and each of
us should participate in it. The theoretical framework
in Figure 1 presents the relationship between urban
residents' behavioral responses to climate change and
their influencing factors. It introduces the concept of
the mechanism of the relationship between the
influencing factors and the behavioral responses of
urban residents. Thus, the reactivity and behavior of
citizens in response to climate warming are also
crucial. As individuals, we must change our
consumption and lifestyle to a low-carbon lifestyle to
solve the climate change crisis. We can incorporate
relevant content into textbooks and disseminate
relevant knowledge. Introduce the relationship
between energy conservation and climate change and
people's daily lives through various media and
introduce climate change's immediate and long-term
effects. Call on the public to reduce greenhouse gas
emissions through energy conservation and emission
reduction in all aspects of life. Encourage the public
to monitor wasteful behavior and illegal emissions
(Usui, 2017). Through the participation of all people,
national policies should be transformed into
voluntary actions of each citizen.
3.3 Scientific and Technological Means
Adaptation to climate change is one of the
components of the response to climate change, and
scientific and technological progress and innovation
are important to support adaptation to climate change.
Environmental technologies are divided into two
basic categories: pollution prevention technologies
and pollution control technologies used after
pollution has occurred. Clean technologies are
technologies that ensure the prevention of pollution
before it occurs through organizational and
technological changes. Burning fossil fuels, such as
oil, coal, etc., or cutting down forests and burning
Impacts of Climate Change on Birds and Measures
561
Figure 1: Garbage Floating on the Ocean Surface (T. Usui, 2017).
them produces large amounts of carbon dioxide,
contributing to climate warming. Clean energy is an
environmentally friendly source of energy that is
more environmentally friendly, emits less, and
pollutes less than traditional fuels. Biomass and
municipal solid waste (MSW) is widely accepted as
an important local renewable energy source and is
one of the largest renewable energy sources in the
world. MSW incineration in Thailand has a
sustainable potential and direction in mitigating
climate change and promoting biomass-based
electricity production (U.N.F.C.o.C.C.J.R.o.E,
2010). Renewable energy plays a critical role in
climate change mitigation and adaptation in highly
climate-sensitive countries such as Nepal. Nepal has
installed micro-hydropower projects, solar energy,
improved cookstoves, biogas technology, improved
water plants, and wind energy to mitigate and adapt
to climate change. The adoption of renewable energy
technologies in Nepal has reduced greenhouse gas
emissions and enhanced carbon sequestration (Steen,
2012).
4 CONCLUSIONS
Climate change in this century is a long-term and
gradual process, and its impact on human and global
ecology is undoubtedly enormous. Since the impact
of climate warming on the world's economic life,
agricultural production, and ecological environment
is still expanding, it is of great importance to use birds
as indicator species to monitor the evolution of the
Earth's environment. In the context of climate
change, the geographic range of birds is shifting to
higher latitudes. The spawning period of birds has
been advanced during the breeding period, and the
population size has been gradually reduced. In the
face of the increasingly severe ecological hazards
caused by climate change, it is possible to mitigate
the warming problem from the government, people,
and technology. In the future, a complete bird data
monitoring system can be established, integrating
data collection, uploading, sharing, and research.
Scholars conduct long-term monitoring and
investigation on a particular object and carry out
several large-scale land bird monitoring studies. New
prediction and assessment methods are studied and
researched to accurately predict trends in the world's
birds under future climate scenarios. In the future, we
should combine modern research techniques to
improve management methods, strengthen education
and awareness, and better respond to climate change's
harm.
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