Abstract The combustion phenomenon is characterized by rapid self-sustaining reactions, which can occur in the solid, liquid, or gas phase. Specific types of these reactions are used to produce valuable materials by different combustion synthesis (CS) routes. In this article, all three CS approaches, i.e. solid-phase, solution, and gas-phase flame, are reviewed to demonstrate their attractiveness for fabrication of zero-, one-, two-, and three-dimensional nanostructures of a large variety of inorganic compounds. The review involves five sections. First, a brief classification of combustion synthesis methods is given along with the scope of the article. Second, the state of art in the field of solid-phase combustion synthesis is described. Special attention is paid to the relationships between combustion parameters and structure/properties of the produced nanomaterials. The third and fourth sections describe details for controlling material structures through solution combustion synthesis and gas-phase flame synthesis, respectively. A variety of properties (e.g., thermal, electronic, electrochemical, and catalytic) associated with different types of CS nanoscale materials are discussed. The conclusion focuses on the most promising directions for future research in the field of advanced nanomaterial combustion synthesis.

中文翻译：

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零维、一维、二维和三维纳米结构的燃烧合成：当前趋势和未来展望

摘要 燃烧现象的特点是快速的自持反应，可以发生在固相、液相或气相中。这些反应的特定类型用于通过不同的燃烧合成 (CS) 路线生产有价值的材料。在本文中，所有三种 CS 方法，即固相、溶液和气相火焰，都进行了审查，以证明它们在制造各种零维、一维、二维和三维纳米结构方面的吸引力。无机化合物。审查包括五个部分。首先，结合文章的范围给出了燃烧合成方法的简要分类。其次，描述了固相燃烧合成领域的现有技术。特别注意燃烧参数与生产的纳米材料的结构/性能之间的关系。第三节和第四节分别描述了通过溶液燃烧合成和气相火焰合成控制材料结构的细节。讨论了与不同类型的 CS 纳米级材料相关的各种特性（例如，热、电子、电化学和催化）。结论集中在先进纳米材料燃烧合成领域未来研究最有希望的方向。和催化）与不同类型的 CS 纳米材料相关的讨论。结论集中在先进纳米材料燃烧合成领域未来研究最有希望的方向。和催化）与不同类型的 CS 纳米材料相关的讨论。结论集中在先进纳米材料燃烧合成领域未来研究最有希望的方向。