Tidal Wave Renewable Energy

TIDAL WAVE RENEWABLE ENERGY 3 Tidal Wave Renewable Energy

Tidal power is among the most renewable forms of energy and the most considered infantile. Tidal power has numerous positive and negative impacts. One such positive impact includes its cleanness and compactness in nature. Tidal power is mostly recognized as a green energy source as it emits zero gases related to the greenhouse. Another positive impact of tidal energy is that it is predictable (MacDougall, 2016).

Substantially, the gravitational forces in celestial bodies will not end sooner or later, and high and low tides are cyclical, thereby making it easier for engineers to develop efficient systems. The negative impact of tidal power is that it lacks adequate research. Therefore, it is not easy to evaluate its implications when used in specific ways. Also, its emissions of the electromagnetic field in water may cause harm to the sensitivity life of a marine. Since tidal is among the most renewable and environmentally friendly sources of energy, there are possibilities for replacing fossil fuel energy.

Notably, fossil fuels are a non-renewable form of energy, meaning that its energy is exhaustible, unlike that of the tidal wave. Also, the use of fossil fuels is not environmentally friendly, which may contribute to environmental hazards. For instance, the transportation of fuels from mines can lead to air pollution and severe spills and accidents. The world environmental organizations are currently looking for alternative ways of generating energy with zero greenhouse gas emissions. One of the possible alternatives options for them to choose from is tidal power if more is done to bring it to large scale production.

Tidal power is based on infrastructure technology that is expensive to construct. Therefore, it will increase the cost of developing the energy plant, which is relatively cheap for other forms of energy production (MacDougall, 2016). Also, the time that the project might take to complete is long, and this may contribute to delays as it takes about ten years for full completion of the plant. Besides, this may increase the sensitivity to the discount rate regarding the electricity cost. Further, if developed to large-scale commercial use, the tidal power will lead to inexhaustible energy that is predictable, thereby increasing the power sufficiency and efficiency.

Developing or building a tidal power infrastructure is too costly for a person. Therefore, the government can assist by contributing the funds necessary to produce the energy form. In other words, the provincial and federal governments have a significant role in tidal power development as far as the project's cost and risks are concerned with the progress barrier. In some years come, the clean power plan will likely survive and expand throughout the globe. Currently, the governments of many countries are switching from non-renewable forms of energy to renewable.

This will encourage many companies within the energy industry to consider developing a tidal power plant as it is among the known renewable form of power. Due to its property as a non-pollutant agent, many governments, especially in first-world countries, will shift to tidal wave plants following the world environmental organizations to restrict activities that contribute to environmental pollution. References MacDougall, S. (9 September 2016). Funding and Financial Support for Tidal Energy Development in Nova Scotia: Report to the Offshore Energy Research Association. 11-20

Paper For Above instruction

Introduction

As the world increasingly contemplates sustainable and environmentally friendly energy sources, tidal power has emerged as a promising candidate due to its renewable nature and predictability. Unlike fossil fuels, which are finite and contribute significantly to environmental degradation, tidal energy offers a clean alternative capable of meeting global energy demands. This paper critically examines the advantages and challenges of tidal wave renewable energy, evaluates its potential as a sustainable energy source, and explores the role of government and industry in fostering its development.

Advantages of Tidal Power

Tidal energy offers numerous environmental and operational benefits. Foremost among these is its zero greenhouse gas emissions, which positions it as a truly green energy source. The cyclical and predictable nature of tides, driven by celestial gravitational forces, ensures a reliable and consistent energy supply, unlike solar or wind power that depends on weather conditions (MacDougall, 2016). Additionally, tidal power infrastructure, once installed, produces substantial amounts of energy with minimal ongoing environmental disturbances compared to fossil fuel extraction and combustion processes. The compactness of tidal power systems allows access in coastal regions where energy needs are pressing, providing a localized solution that can reduce transmission losses and increase efficiency.

Challenges and Limitations

Despite its advantages, tidal energy development faces significant hurdles. Primarily, the high capital costs linked with constructing tidal power plants limit economic feasibility. The infrastructure requires robust, durable turbines and barrages capable of withstanding harsh marine conditions, which escalates upfront investments (MacDougall, 2016). The lengthy project timelines—often spanning a decade or more—compound financial risks, especially considering fluctuating discount rates and market conditions. Additionally, the environmental impacts of electromagnetic fields and alterations in marine ecosystems pose concerns, demanding rigorous research to understand long-term ecological effects. The scarcity of comprehensive data and pilot projects also hampers widespread adoption and technological refinement.

Potential for Sustainable Development

Given its renewable and environmentally benign profile, tidal energy holds promise as a key component in global efforts to reduce reliance on fossil fuels. Countries with extensive coastlines and significant tidal ranges, such as the United Kingdom, Canada, and South Korea, have begun investing in tidal projects, signaling industry recognition of its potential (Katramados et al., 2018). Large-scale deployment could contribute to energy security, provide stable electricity prices, and stimulate local economies through technological innovation and job creation. Moreover, advancing tidal technology aligns with international commitments to reduce greenhouse gas emissions under agreements like the Paris Accord.

The Role of Government and Industry in Tidal Energy Development

To translate the potential of tidal energy into tangible benefits, supportive government policies and industry cooperation are indispensable. Governments can facilitate research and development through grants, subsidies, and tax incentives, reducing financial risks and encouraging private investment. Public-private partnerships can accelerate technological innovation and infrastructure deployment. Policy frameworks should prioritize environmental safeguards, ensuring that ecological impacts are minimized and ecosystem health is preserved. Additionally, international collaboration can foster knowledge exchange, cost-sharing, and harmonization of regulatory standards to scale up tidal power projects globally (Khan et al., 2019).

Conclusion

Tidal wave renewable energy presents a promising pathway toward a cleaner, sustainable energy future. While challenges linked to high capital costs, ecological impacts, and technological maturity exist, these can be mitigated through strategic investments, research, and policy support. As global consciousness about climate change grows, tidal power’s predictability and environmental friendliness make it a compelling option for diversification of energy portfolios. Ultimately, integrating tidal energy into the global renewable landscape requires concerted efforts from governments, industry stakeholders, and research institutions to unlock its full potential and foster a sustainable future.

References

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