物理学报
物理學報
물이학보
2013年
10期
303-308
,共6页
焦学敬%欧阳方平?%彭盛霖%李建平%段吉安%胡友旺?
焦學敬%歐暘方平?%彭盛霖%李建平%段吉安%鬍友旺?
초학경%구양방평?%팽성림%리건평%단길안%호우왕?
碳纳米管%Monte Carlo%Stone-Wales缺陷%分子动力学
碳納米管%Monte Carlo%Stone-Wales缺陷%分子動力學
탄납미관%Monte Carlo%Stone-Wales결함%분자동역학
carbon nanotube%Monte Carlo%stone-wales defect%molecular dynamic
基于Stone-Wales缺陷演变理论与分子动力学、Monte Carlo计算方法,进行了碳纳米管(CNTs)对接成异质结器件的计算模拟.首先,提出了一种模拟CNTs端帽位置变化的新算法,并计算模拟了单根CNT的端帽从开口到闭合的过程. Stone-Wales缺陷演变被设计模拟这些端帽变化的跃变过程,以模拟C—C键的生成与断裂,而分子动力学则作为跃变后构型弛豫的渐变模拟.同时,研究了不同管型CNTs的端帽打开并对接形成异质结的过程.研究结果显示,对接初期在对接处先产生大量的缺陷,以促进反应的发生.这些缺陷趋向于演变成稳定的六元环结构,或者五元环/七元环的结构,使异质结趋于稳定.
基于Stone-Wales缺陷縯變理論與分子動力學、Monte Carlo計算方法,進行瞭碳納米管(CNTs)對接成異質結器件的計算模擬.首先,提齣瞭一種模擬CNTs耑帽位置變化的新算法,併計算模擬瞭單根CNT的耑帽從開口到閉閤的過程. Stone-Wales缺陷縯變被設計模擬這些耑帽變化的躍變過程,以模擬C—C鍵的生成與斷裂,而分子動力學則作為躍變後構型弛豫的漸變模擬.同時,研究瞭不同管型CNTs的耑帽打開併對接形成異質結的過程.研究結果顯示,對接初期在對接處先產生大量的缺陷,以促進反應的髮生.這些缺陷趨嚮于縯變成穩定的六元環結構,或者五元環/七元環的結構,使異質結趨于穩定.
기우Stone-Wales결함연변이론여분자동역학、Monte Carlo계산방법,진행료탄납미관(CNTs)대접성이질결기건적계산모의.수선,제출료일충모의CNTs단모위치변화적신산법,병계산모의료단근CNT적단모종개구도폐합적과정. Stone-Wales결함연변피설계모의저사단모변화적약변과정,이모의C—C건적생성여단렬,이분자동역학칙작위약변후구형이예적점변모의.동시,연구료불동관형CNTs적단모타개병대접형성이질결적과정.연구결과현시,대접초기재대접처선산생대량적결함,이촉진반응적발생.저사결함추향우연변성은정적륙원배결구,혹자오원배/칠원배적결구,사이질결추우은정.
@@@@Based on Stone-Wales (SW) defect evolution theory and molecular dynamics, we simulate the docking process of two caped carbon nanotubes (CNTs) of different types to form a heterojunction using Monte Carlo methods. First, an algorithm for a fast simulation of the cap change in CNTs is put forward and the cap formation of single CNTs with open ends is simulated, by applying this method. SW defect evolution is designed as a leap change simulation of these caps, represents C–C bond formation and breakage, while molecular dynamics is used to simulate the gradient change of the relative bond distance between the C atoms. The coalescence process of forming heterojunction is also studied here. These simulations show that the process of docking is first to generate a large number of defects, which will precipitate the coalescence, then many defects disappear through the compound, finally the remaining defects transfer to the ends of this heterojunction in the form of pentagon/heptagon rings, thus leading to the reduced overall energy.