Aqueous chemistry and biochemistry of silicon

硅的水化学和生物化学

• 批准号: RGPIN-2014-06497
• 负责人: Kinrade, Stephen
• 金额: $ 2.19万
• 依托单位: Lakehead University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=632331
• 关键词: Aqueous; chemistry; biochemistry; silicon

Silicates – compounds of silicon (Si) and oxygen – are fundamentally important in both nature and industry. These two elements alone constitute 75 wt% of the Earth’s crust, while elements which fit into silicate frameworks represent another 22.5%. Erosion, migration and deposition of silicates are all controlled by aqueous chemistry. Yet it is biology that controls the overall global Si cycle. Primitive organisms such as diatoms and sponges take up the greatest share, using it to construct silicified cell walls and skeletal structures and, in so doing, sequester a major percentage of global CO2 production. Plants, including all grain crops, require a constant Si supply to defend against myriad biological and non-biological stresses. In mammals, dietary Si intake correlates with healthy connective tissue growth. Despite its appreciable biological importance, however, remarkably little is known about silicon’s interaction with organisms at the molecular level. Better knowledge of aqueous silicate chemistry is also needed in materials science to achieve sustainable production and improved properties of key industrial commodities such as concrete, zeolite catalysts, ceramics, semiconductors, coatings and paper. For example, concrete, a low-cost low-energy aggregate of silicates, is the most widely used man-made substance on Earth, with an annual production of nearly 40 billion tons (ca. 20 km3) and quickly rising. Because nearly a ton of CO2 is released during the manufacture of every ton of cement, concrete accounts for some 7-10% of man-made greenhouse gas emissions. Decreasing its environmental impact without sacrificing performance will necessitate changes being made to the chemistry of cement. The long-term goals of my research program are to unravel the fundamental chemistry of aqueous silicon and to translate that knowledge for the benefit of agriculture, human nutrition, medicine and materials science.

硅酸盐-硅（Si）和氧的化合物-在自然界和工业中都非常重要。仅这两种元素就占地壳的75%，而适合硅酸盐框架的元素占另外22.5%。硅酸盐的侵蚀、迁移和沉积均受水化学控制。然而，正是生物学控制着整个全球硅循环。硅藻和海绵等原始生物占据了最大的份额，用它来构建硅化细胞壁和骨骼结构，并在这样做的过程中，封存了全球二氧化碳产量的主要百分比。植物，包括所有粮食作物，需要恒定的硅供应，以抵御无数的生物和非生物胁迫。在哺乳动物中，膳食Si摄入量与健康的结缔组织生长相关。尽管硅在生物学上有着重要的意义，但人们对硅在分子水平上与生物体的相互作用知之甚少。材料科学也需要更好地了解含水硅酸盐化学，以实现可持续生产和改善关键工业商品的性能，如混凝土，沸石催化剂，陶瓷，半导体，涂料和纸张。例如，混凝土，一种低成本低能量的硅酸盐聚合物，是地球上使用最广泛的人造物质，年产量近400亿吨（约1000万吨）。20 km 3），并迅速上升。由于每吨水泥的生产过程中会释放近一吨二氧化碳，因此混凝土约占人为温室气体排放量的7-10%。在不牺牲性能的情况下减少其对环境的影响将需要改变水泥的化学性质。我的研究计划的长期目标是解开水硅的基本化学，并将这些知识转化为农业，人类营养，医学和材料科学的利益。