基于第一性原理的方锰矿及(001) 表面电子结构与浮选行为研究#br#

金属矿山 ›› 2026, Vol. 55 ›› Issue (3): 89-95.

基于第一性原理的方锰矿及(001) 表面电子结构与浮选行为研究#br#

朱　峰^1,2,3　袁　帅^1,2,3　赵　冰^1,2,3　刘　杰^1,2,3　谢瑞琦⁴

1. 东北大学矿物加工科学与技术全国重点实验室,辽宁沈阳 110819;2. 东北大学资源与土木工程学院,辽宁沈阳 110819;
3. 难采选铁矿资源高效开发利用技术国家地方联合工程研究中心,辽宁沈阳 110819;
4. 昆明理工大学国土资源工程学院,云南昆明 650093

出版日期:2026-03-15 发布日期:2026-03-31
通讯作者: 袁　帅(1990—),男,教授,博士,博士研究生导师。
作者简介:朱　峰(2001—),男,硕士研究生。
基金资助:
国家重点研发计划青年科学家项目(编号:2023YFC2909000);国家自然科学基金-面上项目(编号:52174240);新疆维吾尔自治区重大
科技专项(编号:2023A03003-2);兴辽英才计划青年拔尖人才项目(编号:XYC2203167)。

Study on Electronic Structure and Flotation Behavior of Manganosite and Its (001) Surface Based on First-Principles Calculations#br#

ZHU Feng^1,2,3　YUAN Shuai^1,2,3　ZHAO Bing^1,2,3　LIU Jie^1,2,3　XIE Ruiqi⁴

1. State Key Laboratory of Mineral Processing,Northeastern University,Shenyang 110819,China;
2. School of Resources and Civil Engineering,Northeastern University,Shenyang 110819,China;3. National-local Joint
Engineering Research Center of High-efficient Exploitation Technology for Refractory Iron Ore Resources,Shenyang 110819,China;
4. Faculty of Land and Resources Engineering,Kunming University of Science and Technology,Kunming 650093,China

Online:2026-03-15 Published:2026-03-31

摘要/Abstract

摘要： 锰是支撑钢铁冶金与新能源产业的关键战略金属,其高效提取关乎国家经济安全。方锰矿(MnO)作为
锰氧化物基础相态,其表面Mn2+位点的电子特性对浮选分离效率具有决定性影响,且原子尺度机制尚不明确。本研
究基于密度泛函理论,采用GGA-PBESOL 泛函、650 eV 截断能和6×6×6 k 点取样密度优化计算参数,构建方锰矿体相
及(001)表面模型,通过Mulliken 电荷布居、能带结构和态密度分析揭示其电子结构与浮选机制。结果显示,方锰矿
晶格参数优化误差仅0. 84%,Mn—O 键布居值-0. 03,键长0. 220~0. 222 nm,呈离子键特性;态密度分析表明其O-2p
轨道主导价带电子态,而Mn-3 d 轨道在导带中贡献显著。表面分析发现,(001)面Mn2+ 位点因配位数减少引发晶格
畸变导致电子去局域化,其未占据3 d 轨道易与阴离子捕收剂发生p-d 杂化,而O2-位点因2p 轨道活性较低对阳离子
药剂亲和力弱。浮选行为预测表明,弱酸性至中性条件下,阴离子捕收剂可通过静电作用与Mn2+ 形成稳定吸附,而碱
性环境因表面羟基化抑制吸附。研究为方锰矿浮选分离提供原子尺度理论依据,建议采用磺酸基/ 磷酸基捕收剂协
同活化剂提升选择性吸附效率。

关键词: 方锰矿　第一性原理　浮选行为　阴离子捕收剂

Abstract: Manganese is a critical strategic metal supporting the steel metallurgy and new energy industries,and its efficient
extraction is vital to national economic security. As a fundamental phase in manganese oxide systems,manganosite
(MnO) exhibits surface Mn2+ sites whose electronic properties decisively influence flotation separation efficiency,yet the atomic-
scale mechanisms remain unclear. In this study,first-principles calculations based on density functional theory were performed
using the GGA-PBESOL functional,a cutoff energy of 650 eV,and a 6×6×6 k-point sampling density to optimize computational
parameters. Bulk and (001) surface models of manganosite were constructed,and their electronic structures and flotation
mechanisms were investigated through Mulliken charge population,band structure,and density of states (DOS) analysis.
The results show that the optimized lattice parameters of manganosite exhibit only a 0. 84% deviation from experimental values,
with Mn—O bond populations of -0. 03 and bond lengths from 0. 220 to 0. 222 nm,indicating ionic bonding characteristics.
DOS analysis reveals that the valence band is dominated by O-2p orbitals,while the conduction band is primarily contributed by Mn-3d orbitals. Surface analysis demonstrates that the reduced coordination number of Mn2+ sites on the (001) surface
leads to electron delocalization,with unoccupied 3d orbitals facilitating p-d hybridization with anionic collectors,whereas O2-
sites exhibit weak affinity for cationic reagents due to the low activity of 2p orbitals. Flotation behavior predictions suggest that
under weakly acidic to neutral conditions,anionic collectors can form stable adsorption on Mn2+ sites via electrostatic interactions,
while alkaline conditions inhibit adsorption due to surface hydroxylation. This study provides atomic-scale theoretical insights
into the flotation separation of manganosite from gangue minerals and proposes the use of sulfonic/ phosphonic acid-based
collectors combined with activators to enhance selective adsorption efficiency.

Key words: manganosite,first-principles calculation,flotation behavior,anionic collectors

中图分类号:

TD923
TD95

朱　峰, 　袁　帅, 　赵　冰, 　刘　杰, 　谢瑞琦. 基于第一性原理的方锰矿及(001) 表面电子结构与浮选行为研究#br#[J]. 金属矿山, 2026, 55(3): 89-95.

ZHU Feng, 　YUAN Shuai, 　ZHAO Bing, 　LIU Jie, 　XIE Ruiqi. Study on Electronic Structure and Flotation Behavior of Manganosite and Its (001) Surface Based on First-Principles Calculations#br#[J]. Metal Mine, 2026, 55(3): 89-95.

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