煤中的釩具有潛在的環(huán)境影響和經(jīng)濟(jì)意義,然而,關(guān)于煤礦區(qū)中釩的環(huán)境地球化學(xué),仍缺乏系統(tǒng)的研究。在本次研究中,通過搜集文獻(xiàn)中2900多個中國煤炭樣品數(shù)據(jù),全面調(diào)查了中國煤中釩的濃度和分布狀況;從中國九個省份采集了 21個不同煤級的煤樣,基于逐級提取和燃燒實(shí)驗(yàn)等方法,分析了煤中釩的化學(xué)形態(tài)和燃燒行為;在淮南和淮北煤礦區(qū)中采集了河流沉積物,土壤和魚類樣品,旨在探究煤礦區(qū)中釩的分布模式,賦存形態(tài),遷移轉(zhuǎn)化和環(huán)境效應(yīng);與煤礦區(qū)作對比,在石油開采業(yè)密集的黃河三角洲地區(qū)采集了土壤和水生生物樣品,探討了石油產(chǎn)區(qū)中釩的環(huán)境地球化學(xué)。本研究的主要結(jié)果如下:（1）以各省煤炭儲量為權(quán)重因子,更新了中國煤中釩的加權(quán)平均濃度為35.81 μg/g。根據(jù)釩在不同聚煤區(qū)域的濃度系數(shù),劃分出中國煤中釩分布的貧乏,正常和富集區(qū)域。（2）煤中的釩主要以硅酸鹽結(jié)合態(tài)存在,隨著煤級的增加,有機(jī)質(zhì)結(jié)合態(tài)的釩的比重呈下降趨勢。煤樣中的釩和鉻呈高度正相關(guān),這可能歸因于煤中釩和鉻賦存的主要形式都是硅酸鹽結(jié)合態(tài)和有機(jī)結(jié)合態(tài)。（3）估算了近十年由中國燃煤造成的釩排放量,及從1990年至2035年世界不同生產(chǎn)部門的釩排放量,發(fā)電廠是最主要的釩... 

【文章來源】：中國科學(xué)技術(shù)大學(xué)安徽省 211工程院校 985工程院校

【文章頁數(shù)】：182 頁

【學(xué)位級別】：博士

【文章目錄】：
摘要
ABSTRACT
英文部分
    Chapter 1 Introduction
        1.1 Physiochemical properties of V
        1.2 The resources and usage of V
        1.3 Toxicity of V and its compounds
        1.4 Environmental fate of V
        1.5 Research progress of V in coal and coal mining areas
        1.6 Overall objective
        1.7 Research strategy and technical route
    Chapter 2 Samples and methodology
        2.1 Introduction of the research area
            2.1.1 Huaibei coal mining area
            2.1.2 Huai River in Huainan coal mining area
            2.1.3 Typical petroleum-producing region
        2.2 Samples
            2.2.1 Coal samples
            2.2.2 Coal gangue samples
            2.2.3 Sediment core
            2.2.4 Soil samples
            2.2.5 Aquatic organism samples
        2.3 Methodology
            2.3.1 Proximate and ultimate analysis
            2.3.2 Elemental analysis
            2.3.3 Leaching test
            2.3.4 Simulated combustion experiment
            2.3.5 Sequential chemical extraction procedure
            2.3.6 Stable isotope analysis
            2.3.7 Geochronology
            2.3.8 Quality control
            2.3.9 Statistical analysis
            2.3.10 Data analysis
    Chapter 3 Abundance, distribution,and enrichment of V in Chinesecoals
        3.1 Introduction
        3.2 Average V abundance in Chinese coals
        3.3 Distribution of V in Chinese coals
            3.3.1 Distribution of V in coals from different regions
            3.3.2 Vanadium abundance in coals of different ages
            3.3.3 Vanadium abundance in coals of different ranks
        3.4 The enrichment of V in Chinese coals
            3.4.1 Highly-elevated V in Chinese coals
            3.4.2 Enrichment mechanism of V in Chinese coals
        3.5 Summary
    Chapter 4 Modes of Occurrence of V in coals
        4.1 Introduction
        4.2 Correlation of V with ash yield
        4.3 Correlation of V with major elements
        4.4 Modes of occurrence of V in studied coal by sequential extraction
            4.4.1 Inorganically associated V
            4.4.2 Association with organic matter
        4.5 The factors influencing the occurrence of V in coals
            4.5.1 Coal rank
            4.5.2 Coal-forming environment
        4.6 Comparison of chemical speciation between V and Cr
            4.6.1 Correlation between V and Cr
            4.6.2 Correlation of the chemical speciation of V and Cr
        4.7 Summary
    Chapter 5 The behavior of V during coal combustion
        5.1 Introduction
        5.2 Emission inventory of V by coal consumption
            5.2.1 The V emission flux by Chinese and global coal consumption
            5.2.2 The global V emission flux by different sectors
        5.3 The combustion behavior of V in coal
            5.3.1 The distribution of V among different coal combustion products
            5.3.2 Volatility of V during coal combustion
        5.4 Comparison of the combustion behavior between V and Cr
        5.5 Summary
    Chapter 6 Environmental geochemistry of V in coal mining areas
        6.1 Introduction
        6.2 Vanadium concentration in coal gangue from Huaibei and Huainan coalmining areas
        6.3 Vanadium concentration in soils from Huaibei coal mining area
        6.4 Vanadium in sediments in Huai River from Huainan coal mining area
            6.4.1 Sedimentation rate
            6.4.2 Vanadium concentrations in surface sediments
            6.4.3 Temporal characteristics of V in sediments
            6.4.4 The fractionation of V in sediments
            6.4.5 Enrichment factor and geo-accumulation index
        6.5 Vanadium concentration in fish from the Huaibei coal mining area
        6.6 Summary
    Chapter 7 Environmental geochemistry of V in petroleum-producingareas
        7.1 Introduction
        7.2 Vanadium concentration in soil from the Yellow River Delta
        7.3 Vanadium in fish from the Yellow River Estuary
            7.3.1 Concentrations of V in fish from the Yellow River Estuary
            7.3.2 Stable isotope values of fish from the Yellow River Estuary
            7.3.3 Estimated daily intake of V via fish consumption
            7.3.4 The relationship between V and geographical environment
        7.4 Vanadium in aquatic organisms from Laizhou Bay
            7.4.1 Concentrations of V in aquatic organisms
            7.4.2 Stable isotope values of aquatic organisms from Laizhou Bay
            7.4.3 Estimated daily intake of V via aquatic organism consumption
        7.5 Summary
    Chapter 8 Major conclusions and innovations
        8.1 Major conclusions
            8.1.1 The environmental geochemistry of V in coals
            8.1.2 Contamination level and potential risk of V in coal mining areas
            8.1.3 Comparison of the environmental geochemistry of V betweenpetroleum-producing areas and coal mining areas
        8.2 Innovations
中文部分
    第一章 緒論
        1.1 研究背景和意義
            1.1.1 研究背景
            1.1.2 研究意義
        1.2 國內(nèi)外研究進(jìn)展
            1.2.1 煤中釩的研究進(jìn)展
            1.2.2 煤礦區(qū)中的釩的研究進(jìn)展
        1.3 研究目標(biāo)和內(nèi)容
        1.4 研究思路、技術(shù)路線和工作量
            1.4.1 研究思路和技術(shù)路線
            1.4.2 主要工作量
    第二章 采樣與測試
        2.1 研究區(qū)概況
            2.1.1 淮北煤礦區(qū)
            2.1.2 淮南煤礦區(qū)及淮河淮南段
            2.1.3 典型石油產(chǎn)區(qū)
        2.2 樣品采集
            2.2.1 煤樣品
            2.2.2 煤矸石樣品
            2.2.3 沉積物樣品
            2.2.4 土壤樣品
            2.2.5 水生生物樣品
        2.3 樣品分析與測試
            2.3.1 煤樣的工業(yè)分析
            2.3.2 元素分析
            2.3.3 淋濾實(shí)驗(yàn)
            2.3.4 模擬燃燒實(shí)驗(yàn)
            2.3.5 逐級化學(xué)提取實(shí)驗(yàn)
            2.3.6 穩(wěn)定同位素分析
            2.3.7 地質(zhì)年代學(xué)
            2.3.8 質(zhì)量控制
            2.3.9 統(tǒng)計(jì)分析
            2.3.10 數(shù)據(jù)分析
    第三章 中國煤中釩的含量,分布和富集
        3.1 前言
        3.2 中國煤中釩的平均豐度
        3.3 中國煤中釩的分布
            3.3.1 不同地區(qū)煤中釩的分布
            3.3.2 不同成煤時期煤中釩的豐度
            3.3.3 不同煤級煤中釩的豐度
        3.4 中國煤中釩的富集
            3.4.1 中國的富釩煤
            3.4.2 中國煤中釩的富集機(jī)制
        3.5 小結(jié)
    第四章 煤中釩的賦存狀態(tài)
        4.1 前言
        4.2 釩和灰分的關(guān)系
        4.3 釩與主量元素的關(guān)系
        4.4 通過逐級提取得到的煤中釩的賦存狀態(tài)
            4.4.1 無機(jī)結(jié)合態(tài)的釩
            4.4.2 有機(jī)結(jié)合態(tài)的釩
        4.5 影響煤中釩賦存狀態(tài)的因素
            4.5.1 煤級
            4.5.2 成煤環(huán)境
        4.6 釩與鉻的化學(xué)形態(tài)的比較
            4.6.1 釩和鉻的相關(guān)性
            4.6.2 鉻與釩化學(xué)形態(tài)的相互關(guān)系
        4.7 小結(jié)
    第五章 煤中釩的燃燒行為
        5.1 前言
        5.2 煤消耗產(chǎn)生的釩釋放清單
            5.2.1 中國和世界煤消耗中釩的釋放
            5.2.2 世界不同部門釩的釋放清單
        5.3 煤中釩的燃燒行為
            5.3.1 煤燃燒產(chǎn)物中釩的分布
            5.3.2 煤燃燒過程中釩的揮發(fā)
        5.4 釩和鉻的燃燒行為的比較
        5.5 小結(jié)
    第六章 煤礦區(qū)中釩的環(huán)境地球化學(xué)研究
        6.1 前言
        6.2 淮南淮北煤礦區(qū)煤矸石中的釩
        6.3 淮北煤礦區(qū)土壤中釩的濃度
        6.4 淮南煤礦區(qū)淮河沉積物中的釩
            6.4.1 沉積速率
            6.4.2 表層沉積物中釩的濃度
            6.4.3 沉積物中釩的年代變化特征
            6.4.4 沉積物中釩的化學(xué)形態(tài)
            6.4.5 富集系數(shù)和地累積指數(shù)
        6.5 淮北煤礦區(qū)塌陷塘中魚的釩含量
        6.6 小結(jié)
    第七章 石油產(chǎn)區(qū)中釩的環(huán)境地球化學(xué)
        7.1 前言
        7.2 黃河三角洲土壤中的釩
        7.3 黃河口魚中的釩
            7.3.1 黃河口魚的釩含量
            7.3.2 黃河口魚中的碳氮同位素
            7.3.3 通過魚消費(fèi)的每日釩攝入量
            7.3.4 釩含量與地理環(huán)境的關(guān)系
        7.4 萊州灣水生生物中的釩
            7.4.1 水生生物中的釩含量
            7.4.2 萊州灣水生生物中的碳氮同位素
            7.4.3 水生生物消費(fèi)引發(fā)的釩攝入量
        7.5 小結(jié)
    第八章 主要結(jié)論和創(chuàng)新點(diǎn)
        8.1 主要結(jié)論
            8.1.1 煤中釩的環(huán)境地球化學(xué)
            8.1.2 煤礦區(qū)中釩的污染水平和潛在風(fēng)險(xiǎn)
            8.1.3 石油產(chǎn)區(qū)與煤礦區(qū)中釩的環(huán)境地球化學(xué)的比較
        8.2 主要創(chuàng)新點(diǎn)
參考文獻(xiàn)
附錄
致謝
Acknowledgements
學(xué)位申請者簡介


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