用於替代能源技術的半導體：機會和市場

Semiconductors for Alternative Energy Technologies: Opportunities and Markets

出版日期: 2024年10月01日 | 出版商:

Information Network | 英文 | 商品交期: 2-3個工作天內

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簡介目錄圖表

半導體是現代電子產品的支柱，準備在替代能源技術中發揮同樣的變革作用。其獨特的特性和功能能夠為再生能源的利用、儲存和利用開發和優化高效、可靠和具有成本效益的解決方案。從太陽能電池板和風力渦輪機到電動車 (EV) 和智慧電網，半導體是有望重塑我們能源基礎設施的創新的核心。

對替代能源技術的需求源於減少碳排放和減輕氣候變遷影響的全球共識。太陽能、風能、水力發電和地熱等再生能源在全球能源結構中變得越來越重要，需要先進的技術來更有效、更可靠地利用、轉換和儲存能源。

半導體以其獨特的導電性和控制性，處於這場技術革命的前沿，有助於開發更智慧、更有效率的能源系統和設備。

趨勢

報告中概述的主要趨勢之一是加速從化石燃料轉向太陽能、風能、水力發電和地熱能等再生能源的轉變。這種轉變是由於再生能源技術的成本降低、效率提高和可近性提高。

另一個重要趨勢是對儲能技術日益增長的關注。隨著電網中再生能源的增加，對高效儲能解決方案的需求不斷增長，以解決間歇性問題並確保可靠的能源供應。

交通電氣化正在成為一個重要趨勢，而電動車（EV）作為內燃機汽車的可行替代品正在蓬勃發展。

本報告研究和分析了全球替代能源市場，並考慮了半導體在太陽能、風能和電動車等領域的作用。

The "Semiconductors for Alternative Energy Technologies: Opportunities and Markets" report is a comprehensive resource for understanding the critical intersection of semiconductor technology and renewable energy. It offers a roadmap for navigating the future of energy, highlighting the transformative potential of semiconductors to power a more sustainable world.

Semiconductors, the bedrock of modern electronics, are poised to play a similarly transformative role in alternative energy technologies. Their unique properties and capabilities enable the development and optimization of efficient, reliable, and cost-effective solutions for harnessing, storing, and utilizing renewable energy. From solar panels and wind turbines to electric vehicles (EVs) and smart grids, semiconductors are at the heart of innovations that promise to reshape our energy infrastructure.

The imperative for alternative energy technologies stems from the global consensus on reducing carbon emissions and mitigating the effects of climate change. Renewable energy sources such as solar, wind, hydro, and geothermal have become increasingly vital in the global energy mix, necessitating advanced technologies that can harness, convert, and store energy more efficiently and reliably.

Semiconductors, with their inherent properties of electrical conductivity and control, stand at the forefront of this technological revolution, enabling the development of smarter, more efficient energy systems and devices.

Trends

One of the primary trends outlined in the report is the accelerating shift from fossil fuels to renewable energy sources such as solar, wind, hydro, and geothermal power. This transition is driven by the decreasing cost of renewable energy technologies, enhanced by advancements in efficiency and accessibility. The report underscores the increasing competitiveness of solar photovoltaic (PV) systems and wind turbines, which are becoming more cost-effective than traditional coal or gas-fired power plants in many regions around the globe.

Another significant trend is the growing emphasis on energy storage technologies. As the penetration of renewable energy in the power grid increases, the demand for efficient storage solutions to address intermittency issues and ensure a reliable energy supply is highlighted. The report examines various energy storage technologies, including batteries, pumped hydro storage, community nuclear storate, and geothermal energy, discussing their roles in enabling a smoother integration of renewable sources into the energy mix.

The electrification of transportation emerges as a crucial trend, with electric vehicles (EVs) gaining momentum as a viable alternative to internal combustion engine vehicles. The report explores the implications of this shift for the energy sector, including the increased demand for electricity and the need for advanced charging infrastructure. It also discusses the potential for EVs to act as mobile energy storage units, further integrating the transportation and energy sectors.

About This Report

This report delves into the various segments of the alternative energy market, examining how semiconductor technologies are being applied to advance renewable energy sources. It discusses the pivotal role of semiconductors in photovoltaic cells for solar power, power electronics for wind energy conversion, and batteries and charging infrastructure for electric mobility. Additionally, it covers the significance of semiconductors in emerging areas such as energy harvesting, which encompasses technologies that capture and convert ambient energies into usable electrical energy.

Beyond the technical aspects, the report also addresses the market dynamics shaping the semiconductor industry's involvement in alternative energy. It analyses trends in investment, research and development efforts, and regulatory environments across different geographies. The analysis includes a look at the competitive landscape, identifying key players and innovators driving the integration of semiconductor technologies into renewable energy solutions.

In essence, the "Semiconductors for Alternative Energy Technologies: Opportunities and Markets" report serves as a comprehensive resource for those vested in the future of energy. It underscores the indispensable role of semiconductors in facilitating the transition towards more sustainable, efficient, and innovative energy solutions. Through detailed market insights, technological reviews, and strategic advice, the report charts a course for stakeholders aiming to navigate the evolving landscape of alternative energy technologies, driving the global shift towards a more sustainable and energy-efficient future.

Chapter 1. Introduction

Chapter 2. Solar Energy

2.1. Solar Infrastructure
- 2.1.1. Current developments
- 2.1.2. Worldwide installed photovoltaic totals
- 2.1.3. Applications of PV
  - 2.1.3.1. PV Power Stations
  - 2.1.3.2. PV in Buildings
  - 2.1.3.3. PV in Transport
  - 2.1.3.4. PV in Standalone Devices
  - 2.1.3.5. Rural Electrification
  - 2.1.3.6. Solar Roadways
- 2.1.4. Economics of PV
  - 2.1.4.1. Power Costs
  - 2.1.4.2. Grid Parity
  - 2.1.4.3. Financial Incentives
- 2.1.5. Solar Forecast
2.2. Semiconductor Technology
- 2.2.1. Inverter/Converter Devices
- 2.2.2. Inverter Analysis
- 2.2.3. Inverter Pricing

Chapter 3. Wind Energy

3.1. Wind Energy Infrastructure
- 3.1.1. Electricity Generation
  - 3.1.1.1. Grid Management System
  - 3.1.1.2. Capacity Factor
- 3.1.2. Turbine Placement
- 3.1.3. Offshore Wind Farms
- 3.1.4. Utilization Of Wind Power
- 3.1.5. Economics And Feasibility
  - 3.1.5.1. Growth And Cost Trends
  - 3.1.5.2. Theoretical Potential
  - 3.1.5.3. Direct Costs
  - 3.1.5.4. External Costs
  - 3.1.5.5. Incentives
3.2. Semiconductor Technology
- 3.2.1. Key Component Semiconductor Devices
- 3.2.2. Semiconductor Analysis

Chapter 4. Fuel Cells

4.1. Fuel Cell Infrastructure
- 4.1.1. Fuel Cell Design
- 4.1.2. History
- 4.1.3. Types of fuel cells
  - 4.1.3.1. Polymer Electrolyte Membrane
  - 4.1.3.2. Phosphoric Acid
  - 4.1.3.3. Direct Methanol
  - 4.1.3.4. Alkaline
  - 4.1.3.6. Molten Carbonate
  - 4.1.3.7. Solid Oxide
  - 4.1.3.8. Proton Exchange Fuel Cells
  - 4.1.3.9. Regenerative (Reversible) Fuel Cells
- 4.1.4. Efficiency
  - 4.1.4.1. Fuel cell efficiency
  - 4.1.4.2. In practice
- 4.1.5. Fuel cell applications
  - 4.1.5.1. Applications
  - 4.1.5.2. Hydrogen Transportation And Refueling
- 4.1.6. Fuel Cell Manufacturers
4.2. Semiconductor Technology
- 4.2.1. Key Component Semiconductor Devices

Chapter 5. Storage/Electric Vehicle Technology

5.1. Storage/Electric Vehicle Infrastructure
- 5.1.1. Usage And Applications
- 5.1.2. Charging And Discharging
- 5.1.3. Active Components
  - 5.1.3.1. Common Rechargeable Battery Types
  - 5.1.3.2. Less Common Types
- 5.1.4. Recent Developments
- 5.1.5. Batteries for Electric Vehicles
  - 5.1.5.1. NiMH Batteries
  - 5.1.5.2. EV Li-Ion Rechargeable Batteries
- 5.1.6. Vehicle Charging
  - 5.1.6.1. Grid Impacts
  - 5.1.6.2. Communication
5.2. Forecasts
- 5.2.1. HEV/EV Forecast
- 5.2.2. Key Component Semiconductor Devices - HEV/EV
- 5.2.3. ADAS (Advanced Driver-Assistance Systems)