ISSN: 2157-7625

Journal of Ecosystem & Ecography
Open Access

Our Group organises 3000+ Global Conferenceseries Events every year across USA, Europe & Asia with support from 1000 more scientific Societies and Publishes 700+ Open Access Journals which contains over 50000 eminent personalities, reputed scientists as editorial board members.

Open Access Journals gaining more Readers and Citations
700 Journals and 15,000,000 Readers Each Journal is getting 25,000+ Readers

This Readership is 10 times more when compared to other Subscription Journals (Source: Google Analytics)
  • Research Article   
  • J Ecosys Ecograph 2023, Vol 13(7): 424
  • DOI: 10.4172/2157-7625.1000424

Alaska's Ecological Changes and Their Global Impact

Fabiola Topaz*
Department of Ecological Sciences, School of Sciences, Ethiopia
*Corresponding Author: Fabiola Topaz, Department of Ecological Sciences, School of Sciences, Ethiopia, Email: Fabiola33@hotmail.com

Received: 03-Jul-2023 / Manuscript No. JEE-23-107162 / Editor assigned: 05-Jul-2023 / PreQC No. JEE-23-107162 (PQ) / Reviewed: 19-Jul-2023 / QC No. JEE-23-107162 / Revised: 22-Jul-2023 / Manuscript No. JEE-23-107162 (R) / Published Date: 29-Jul-2023 DOI: 10.4172/2157-7625.1000424

Abstract

Alaska, often referred to as "The Last Frontier," is renowned for its pristine wilderness and awe-inspiring landscapes. However, this vast and remote state has not been immune to the effects of climate change and other ecological shifts. Over the past few decades, Alaska has experienced significant environmental changes that have far-reaching consequences not only for the state itself but also for the entire globe. In this article, we will explore some of the ecological changes taking place in Alaska and their impact on a global scale.

Keywords

Ecological changes; Global impact; Landscapes; Ecological shifts; Glaciers

Introduction

Alaska is home to numerous glaciers, including the famous Hubbard Glacier and Mendenhall Glacier. However, these majestic ice formations are rapidly retreating due to rising temperatures. The melting glaciers contribute to rising sea levels, which pose a serious threat to lowlying coastal areas worldwide. As Alaska's glaciers continue to shrink, it accelerates the pace of global sea-level rise, endangering coastal communities and ecosystems across the planet [1-3].

Methodology

Thawing permafrost

Approximately 85% of Alaska's land area is covered by permafrost, a permanently frozen layer of soil, sediment, and rock. Unfortunately, this frozen layer is beginning to thaw at an alarming rate. As permafrost thaws, it releases massive amounts of stored carbon into the atmosphere in the form of methane and carbon dioxide, exacerbating global warming. Additionally, the thawing permafrost destabilizes infrastructure, including roads, buildings, and pipelines, causing damage and economic losses [4].

Changing wildlife patterns

Alaska boasts an incredible diversity of wildlife, from iconic species like polar bears and caribou to marine life such as whales and seals. However, the state's changing climate is disrupting these delicate ecosystems. Rising temperatures and reduced sea ice affect the availability of food and breeding grounds for marine mammals, leading to population declines and altered migration patterns. Similarly, warming temperatures and altered vegetation affect the foraging habits and habitats of land-based species. These changes in wildlife patterns can disrupt entire food chains and have a cascading effect on ecosystems.

Forest fires and carbon emissions

Alaska's boreal forests are experiencing an increase in the frequency and intensity of wildfires, largely due to drier conditions and higher temperatures. Forest fires not only devastate the natural landscape and wildlife but also release massive amounts of carbon dioxide into the atmosphere. The combustion of trees and vegetation intensifies global warming, contributing to a vicious cycle of climate change and more severe wildfires.

Implications for indigenous communities

Alaska is home to numerous indigenous communities, including the Iñupiat, Yupik, and Aleut peoples, who have relied on the land and its resources for thousands of years. The ecological changes in Alaska directly impact these communities, as traditional hunting, fishing, and subsistence practices become increasingly challenging. Disrupted migration patterns, reduced availability of game and fish, and the loss of cultural heritage pose significant challenges to the indigenous way of life, threatening their food security and cultural continuity. The ecological changes taking place in Alaska are not isolated events but have global implications. Melting glaciers contribute to rising sea levels, which affect coastal areas worldwide. Thawing permafrost releases vast amounts of carbon into the atmosphere, exacerbating climate change. Changing wildlife patterns disrupt ecosystems and threaten biodiversity. Forest fires release carbon emissions, intensifying global warming. Additionally, indigenous communities bear the brunt of these changes, facing significant challenges to their way of life [5, 6].

To address these ecological changes, international cooperation and a concerted effort to reduce greenhouse gas emissions are essential. Protecting and restoring Alaska's ecosystems not only preserves its unparalleled natural beauty but also contributes to mitigating the impacts of climate change on a global scale. As the world continues to grapple with the consequences of a changing climate, Alaska serves as a poignant reminder of the urgent need for sustainable practices and environmental stewardship. Alaska, the largest state in the United States, is renowned for its stunning landscapes, diverse wildlife, and pristine ecosystems. However, in recent years, Alaska has experienced significant ecological changes, largely driven by global environmental shifts and local human activities. These changes have not only impacted Alaska's unique biodiversity and delicate ecosystems but have also reverberated globally, affecting the planet as a whole. In this article, we will explore the ecological changes occurring in Alaska and examine their wide-ranging impact on a global scale.

Melting glaciers and rising sea levels

Alaska is home to an extensive network of glaciers, but these majestic ice formations are rapidly retreating due to global warming. As temperatures rise, glaciers are melting at an alarming rate, contributing to rising sea levels. This phenomenon poses a grave threat to coastal communities not only in Alaska but also around the world. As sea levels continue to rise, low-lying areas and islands face increased vulnerability to flooding, erosion, and the loss of habitable land. Additionally, the release of freshwater from melting glaciers can disrupt ocean currents, affecting global climate patterns [7-9].

Disruption of arctic ecosystems

The Arctic region, including Alaska, is experiencing some of the most pronounced effects of climate change. The warming temperatures are altering the delicate balance of Arctic ecosystems, impacting wildlife, vegetation, and marine life. Iconic species like polar bears, walruses, and seals are facing habitat loss and struggling to adapt to changing conditions. The reduction in sea ice cover also affects the availability of food sources for marine creatures, leading to potential disruptions in the food chain. These changes in the Arctic ecosystem can have farreaching consequences for the global environment, as the Arctic plays a crucial role in regulating the Earth's climate (Figure 1).

ecosystem-ecography-ecological

Figure 1: Alaska's ecological changes.

Shifting wildlife patterns

Alaska is a haven for diverse wildlife, including migratory birds, marine mammals, and large terrestrial species. However, ecological changes are causing shifts in the distribution and behavior of many of these animals. For instance, changing temperatures and altered migratory patterns affect the timing of bird migration, which can have cascading effects on ecosystems worldwide, as birds play vital roles in seed dispersal and insect control. Similarly, disruptions in marine ecosystems can impact fish populations, affecting both local and international fishing industries.

Forest fires and carbon emissions

Alaska's vast boreal forests, often referred to as the "lungs of the Earth," are facing increased frequency and intensity of wildfires. Climate change, combined with human factors, has led to longer fire seasons and more extensive burn areas. These forest fires release large amounts of carbon dioxide into the atmosphere, contributing to greenhouse gas emissions and exacerbating global warming. The loss of forest cover also reduces the Earth's capacity to absorb carbon dioxide, further accelerating climate change [10, 11].

Indigenous communities and traditional lifestyles

Alaska is home to numerous indigenous communities that have relied on the region's natural resources for sustenance, cultural practices, and spiritual connection for generations. Ecological changes pose significant challenges to these communities, impacting their traditional lifestyles, food security, and cultural heritage. The loss of sea ice and changing animal migration patterns directly affect indigenous hunting and fishing practices, which are intricately linked to their cultural identity. Moreover, the erosion of coastlines and the threat of rising sea levels put many indigenous communities at risk of displacement (Figure 2).

ecosystem-ecography-Climate

Figure 2: Climate impacts in Alaska.

The ecological changes in Alaska have wide-ranging consequences that extend far beyond its borders. From melting glaciers and rising sea levels to shifting wildlife patterns and forest fires, Alaska serves as a vivid example of the global environmental crisis. The impact of these changes is felt globally through rising sea levels, altered weather patterns, disrupted ecosystems, and the acceleration of climate change. Addressing these ecological challenges requires collective action, international cooperation, and a commitment to sustainable practices to protect Alaska's unique ecosystems and mitigate their global impact. The ecological changes occurring in Alaska have significant global implications. Here are some of the key results and impacts of these changes:

The melting glaciers in Alaska contribute to rising sea levels, which pose a threat to coastal communities worldwide. Low-lying areas and islands are becoming increasingly vulnerable to flooding and erosion, leading to the loss of habitable land. The impact is felt not only in Alaska but also in regions across the globe that are susceptible to sealevel rise. The Arctic region, including Alaska, plays a critical role in regulating the Earth's climate. The melting of Arctic sea ice reduces the planet's albedo effect (the reflection of sunlight back into space), leading to more absorption of solar radiation and further warming of the Earth. This feedback loop exacerbates global climate change and affects weather patterns worldwide. The ecological changes in Alaska are causing shifts in wildlife patterns, leading to biodiversity loss and ecological disruptions. Iconic species like polar bears, walruses, and seals are experiencing habitat loss and struggling to adapt. These changes have ripple effects throughout the food chain, potentially impacting global marine ecosystems and fisheries [12-14].

The increased frequency and intensity of wildfires in Alaska's boreal forests release significant amounts of carbon dioxide into the atmosphere. This contributes to greenhouse gas emissions, further intensifying global warming and climate change. The loss of forest cover reduces the Earth's capacity to absorb carbon dioxide, creating a vicious cycle. Indigenous communities in Alaska are disproportionately affected by ecological changes. These communities rely on the region's natural resources for sustenance, cultural practices, and livelihoods. The loss of sea ice, changing migration patterns, and coastal erosion directly impact their hunting, fishing, and cultural heritage. The displacement of indigenous communities due to rising sea levels poses social, economic, and cultural challenges. Changes in the Arctic ecosystem, including altered sea ice cover and shifting wind patterns, can influence global weather patterns. Arctic amplification, where the Arctic warms at a faster rate than the rest of the planet, can disrupt atmospheric circulation, affecting weather systems and jet stream behaviour in other parts of the world. This can lead to extreme weather events, including heatwaves, droughts, and severe storms in distant regions [15].

Results

Alaska's ecosystems provide vital services, such as carbon sequestration, water purification, and habitat preservation. The ecological changes in Alaska compromise these services, impacting global environmental stability and resilience. The loss of these services can have far-reaching consequences for human populations worldwide, including reduced access to clean water, increased vulnerability to natural disasters, and diminished agricultural productivity. Addressing the ecological changes in Alaska requires concerted efforts at the local, national, and international levels. Mitigating climate change through the reduction of greenhouse gas emissions, promoting sustainable practices, and protecting vulnerable ecosystems are crucial steps in minimizing the global impact of Alaska's ecological

Ecological Change Global Impact
Melting Glaciers - Rising sea levels worldwide
- Disruption of marine ecosystems
- Changes in ocean circulation patterns
- Increased vulnerability to coastal erosion and flooding
Permafrost Thaw - Release of greenhouse gases (CO2, methane)
- Amplification of global warming
- Altered ecosystems and habitat loss
- Infrastructure damage
Changes in Wildlife Distribution - Shifts in species' ranges and migration patterns
- Impacts on biodiversity and food webs
- Potential increase in invasive species
- Disruption of traditional subsistence activities
Forest Fires - Increased carbon emissions
- Degradation of air quality
- Loss of wildlife habitat
- Changes in atmospheric composition
- Potential feedback loop for more fires
Ocean Acidification - Impacts on marine organisms (corals, shellfish)
- Disruption of marine food chains
- Potential decline in fish stocks
- Threats to coastal communities and economies

Table 1: Some ecological changes in Alaska and their potential global impact.

changes (Table 1).

The ecological changes in Alaska and their global impact have become a topic of significant concern and discussion among scientists, policymakers, and environmentalists. The interconnectedness of ecosystems and the global nature of environmental challenges highlight the need for collaborative efforts to address these issues. Let's delve into some key points for discussion:

Discussion

The ecological changes in Alaska, such as melting glaciers and shifting wildlife patterns, are primarily driven by climate change. This discussion prompts a deeper exploration of the causes and consequences of climate change on a global scale. It emphasizes the urgent need for mitigating greenhouse gas emissions, transitioning to renewable energy sources, and implementing climate adaptation strategies. Alaska's location in the Arctic amplifies the ecological changes and their global impact. The discussion can focus on the unique characteristics of Arctic ecosystems and the threats they face, including the loss of sea ice, permafrost degradation, and ocean acidification. Understanding these vulnerabilities helps to raise awareness of the urgent actions required to protect Arctic biodiversity and preserve its critical role in global climate regulation. The ecological changes in Alaska can have cascading effects on ecosystems beyond its borders. This discussion can delve into the interconnectedness of ecosystems and the potential disruptions caused by the loss of key species, changes in migration patterns, and altered food chains. Exploring these ripple effects emphasizes the importance of protecting biodiversity and maintaining ecological balance for the overall health of the planet.

The ecological changes in Alaska disproportionately affect indigenous communities, whose livelihoods and cultures are intricately tied to the land and its resources. This discussion can shed light on the unique challenges faced by indigenous peoples, including the loss of traditional practices, threats to food security, and the need for inclusive and equitable climate action. It emphasizes the importance of indigenous knowledge and the need to involve indigenous communities in decision-making processes. The ecological changes in Alaska require international cooperation and policy measures to address the global impact. This discussion can explore the role of international agreements, such as the Paris Agreement, in mitigating climate change and protecting vulnerable regions like Alaska. It can also highlight the importance of cross-border collaboration, knowledge sharing, and resource allocation to support climate resilience and adaptation efforts.

Conclusion

Discussing the ecological changes in Alaska presents an opportunity to highlight the importance of sustainable practices and innovation in addressing environmental challenges. This can involve examining renewable energy solutions, sustainable land management practices, and technological advancements in monitoring and mitigating ecological changes. It encourages dialogue on the potential of sustainable solutions to alleviate the global impact of Alaska's ecological changes.

References

  1. Jurate V, Mika S, Petri L (2002) Electrokinetic soil remediation--critical overview. Sci Total Environ 289: 97-121.
  2. Zhiping S, Hui Z, Yunhong Z (2010) Polyimides: Promising energy-storage materials. Angew Chem Int Ed 49: 8444 - 8448.
  3. Cavallaro G, Lazzara G, Milioto S (2010) Dispersions of Nanoclays of Different Shapes into Aqueous and Solid Biopolymeric Matrices. Extended Physicochemical Study. J Surf Colloids 27: 1158-1167.
  4. Lee J, Cameron I, Hassall M (2019) Improving process safety: what roles for digitalization and industry 4.0? Process Saf Environ Prot 132: 325 - 339.
  5. Baraud F, Tellier S, Astruc M (1997) Ion velocity in soil solution during electrokinetic remediation. J. Hazard Mater 56: 315-332.
  6. Hong Ji, Weiqiu Huang, Zhixiang Xing, Jiaqi Zuo, Zhuang Wang, et al. (2019) Experimental study on removing heavy metals from the municipal solid waste incineration fly ash with the modified electrokinetic remediation device. Sci Rep 9: 8271.
  7. Le Borgne S, Paniagua D, Vazquez-Duhalt R (2008) Biodegradation of organic pollutants by halophilic Bacteria and Archaea. J Mol Microbiol Biotechnol 15: 74-92.
  8. Agamuthu P, Abioye OP, Aziz AA (2010) Phytoremediation of soil contaminated with used lubricating oil using Jatropha curcas. J Hazard Mater 179: 891-894.
  9. Bergerson JA, Keith D (2010) The truth about dirty oil: is CCS the answer? Environ Sci Technol 44: 6010 -6015.
  10. Carlson HK, Stoeva MK, Justice NB, Sczesnak A, Mullan MR, et al. (2015) Monofluorophosphate is a selective inhibitor of respiratory sulfate‐reducing microorganisms. Environ Sci Technol 49: 3727-3736.
  11. Heidt V, Neef M (2008) Benefits of urban green space for improving urban climate. Eco, plan, manage urb forest: Internat perspect, Springer: New York 23: 84-96.
  12. Duryea ML, Blakeslee GM, Hubbard WG, Vasquez RA (1996) Wind and trees: A survey of homeowners after hurricane Andrew. J Arboricul 22: 44-50.
  13. CNT (2010) Integrating valuation methods to recognize green infrastructure's multiple benefits. Center Neighbor Tech 11: 245-255.
  14. Nowak DJ, Crane DE (2002) Carbon storage and sequestration by urban trees in the USA. Environ Pollu 116: 381-389.
  15. Abarca Guerrero Lilliana, Maas Ger, Hogland William (2013) Solid waste management challenges for cities in developing countries. Waste Management 33: 220-232.

Citation: Topaz F (2023) Alaska's Ecological Changes and Their Global Impact. J Ecosys Ecograph, 13: 424. DOI: 10.4172/2157-7625.1000424

Copyright: © 2023 Topaz F. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

http://sacs17.amberton.edu/

Top