| 查看: 885 | 回复: 3 | |||
| 本帖产生 1 个 翻译EPI ,点击这里进行查看 | |||
| 当前只显示满足指定条件的回帖,点击这里查看本话题的所有回帖 | |||
[交流]
物理方面英译汉
|
|||
|
TCOs are wide band gap (Eg) semiconducting oxides, with conductivity in the range 102 – 1.2106 (S). The conductivity is due to doping either by oxygen vacancies or by extrinsic dopants. In the absence of doping, these oxides become very good insulators, with > 1010 -cm. Most of the TCOs are n-type semiconductors. The electrical conductivity of n-type TCO thin films depends on the electron density in the conduction band and on their mobility: =ne, where is the electron mobility, n is its density, and e is the electron charge. The mobility is given by: where is the mean time between collisions, and m* is the effective electron mass. However, as n and are negatively correlated, the magnitude of is limited. Due to the large energy gap (Eg > 3 eV) separating the valence band from the conducting band, the conduction band can not be thermally populated at room temperature (kT~0.03 eV, where k is Boltzmann’s constant), hence, stoichiometric crystalline TCOs are good insulators. To explain the TCO characteristics, various population mechanisms and several models describing the electron mobility were proposed. Some characteristics of the mobility and the processes by which the conduction band is populated with electrons were shown to be interconnected by electronic structure studies, e.g., that the mobility is proportional to the magnitude of the band gap. In the case of intrinsic materials, the density of conducting electrons has often been attributed to the presence of unintentionally introduced donor centers, usually identified as metallic interstitials or oxygen vacancies that produced shallow donor or impurity states located close to the conduction band. The excess or donor electrons are thermally ionized at room temperature, and move into the host conduction band. However, experiments have been inconclusive as to which of the possible dopants was the predominant donor. Extrinsic dopants have an important role in populating the conduction band, and some of them have been unintentionally introduce. Thus, it has been conjectured in the case of ZnO that interstitial hydrogen, in the H+ donor state, could be responsible for the presence of carrier electrons. In the case of SnO2, the important role of interstitial Sn in populating the conducting band, in addition to that of oxygen vacancies, was conclusively supported by first-principle calculations of Kiliç and Zunger. They showed that Sn interstitials and O vacancies, which dominated the defect structure of SnO2 due to the multivalence of Sn, explained the natural nonstoichiometry of this material and produced shallow donor levels, turning the material into an intrinsic n-type semiconductor.10 The electrons released by these defects were not compensated because acceptor-like intrinsic defects consisting of Sn voids and O interstitials did not form spontaneously. Furthermore, the released electrons did not make direct optical transitions in the visible range due to the large gap between the Fermi level and the energy level of the first unoccupied states. Thus, SnO2 could have a carrier density with minor effects on its transparency.10 The conductivity is intrinsically limited for two reasons. First, n and cannot be independently increased for practical TCOs with relatively high carrier concentrations. At high conducting electron density, carrier transport is limited primarily by ionized impurity scattering, i.e., the Coulomb interactions between electrons and the dopants. Higher doping concentration reduces carrier mobility to a degree that the conductivity is not increased, and it decreases the optical transmission at the near-infrared edge. With increasing dopant concentration, the resistivity reaches a lower limit, and does not decrease beyond it, whereas the optical window becomes narrower. Bellingham et al.29 were the first to report that the mobility and hence the resistivity of transparent conductive oxides (ITO, SnO2, ZnO) are limited by ionized impurity scattering for carrier concentrations above 1020 cm-3. Ellmer also showed that in ZnO films deposited by various methods, the resistivity and mobility were nearly independent of the deposition method and limited to about 210-4 cm and 50 cm2/Vs, respectively. , In ITO films, the maximum carrier concentration was about 1.51021 cm-3, and the same conductivity and mobility limits also held . This phenomenon is a universal property of other semiconductors. , Scattering by the ionized dopant atoms that are homogeneously distributed in the semiconductor is only one of the possible effects that reduces the mobility. The all recently developed TCO materials, including doped and undoped binary, ternary, and quaternary compounds, also suffer from the same limitations. Only some exceptional samples had a resistivity of 10-4 cm. In addition to the above mentioned effects that limit the conductivity, high dopant concentration could lead to clustering of the dopant ions, which increases significantly the scattering rate, and it could also produce nonparabolicity of the conduction band, which has to be taken into account for degenerately doped semiconductors with filled conduction bands. |
回复此楼» 猜你喜欢
308求调剂
已经有3人回复
-
求b区院校调剂
已经有5人回复
-
0854AI CV方向招收调剂
已经有4人回复
-
296求调剂
已经有7人回复
-
302求调剂
已经有4人回复
-
086000生物与医药292求调剂
已经有5人回复
-
北科281学硕材料求调剂
已经有14人回复
-
材料与化工 322求调剂
已经有5人回复
-
333求调剂
已经有11人回复
-
材料专硕 335 分求调剂
已经有3人回复
» 抢金币啦!回帖就可以得到:
-
香港中文大学(深圳)靳羽华教授交叉实验室高薪诚聘博士后(光致变色方向)
+2/128
-
双一流南京医科大学招计算机、AI、统计、生物信息等方向26年9月入学博士
+1/79
-
欢迎环境科学与工程、水利工程专业研究生加入北师大珠海校区董越课题组
+2/76
-
北京-89175-事业单位-诚征女友
+1/68
-
南方油校——资源与环境专硕招生,化学环境生物类专业均可,就业好,有专业壁垒
+1/48
-
上海大学 “生物有机电子材料及器件”团队硕士、博士研究生招聘
+1/39
-
环境化学、地学、环境毒理方向,擅长污染物迁移转化降解、分析检测、计算模拟者优先
+1/35
-
【211博士招生】环境化学、地学、毒理方向,擅长污染物迁移转化降解、计算模拟者优先
+1/35
-
双一流大学湘潭大学“化工过程模拟与强化”国家地方联合工程研究中心招收各类博士生
+1/16
-
哈尔滨工业大学-大湾区大学2026年联合培养博士研究生春季招生-报名3月31号截至
+1/15
-
北京某研究院结构生物学相关专业接收调剂研究生
+1/13
-
南昌一本市政工程接受调剂
+1/11
-
临沂大学数学与统计学院招2026研究生
+1/11
-
三峡大学 计算力学课题组招收调剂(力学/水利/土木/材料/矿业)
+1/8
-
上海交通大学环境智能感知实验室招聘博士后
+1/6
-
宁波东方理工大学余鹏课题组2026年上海交大联培博士生、博士后、科研助理招聘
+1/5
-
深圳信息职业大学招聘联合培养硕博研究生(急)
+1/3
-
Top-88悉尼科技大学数据科学/AI 招收2027年入学 校奖 博士生1到2名(国际和本地学生)
+1/2
-
MTI 380调剂
+1/1
-
福建师范大学国家级人才团队招收2026年调剂的硕士研究生若干名
+1/1
3楼2011-03-18 12:15:11
2楼2011-03-16 16:51:22
zhengbiju1833(金币+5, 翻译EPI+1): 挺好,你继续翻译吧。都翻译完。金币都归你 2011-03-18 18:52:17
|
先翻两段试试,如果LZ觉得好久继续,不好的话就此打住。 TCO(透明导电氧化物)是能带很宽的半导体化合物,电导率为XXX。它们的高电导率是通过氧空穴掺杂或外部掺杂而获得的,如果没有掺杂,它们便是非常好的绝缘体。 因为价带和导带之间能带间隙较宽,室温下不能通过热方法填充,因此TCO是极好的绝缘材料。为了解释TCO的特征,研究者已经提出了多种填充机制和模型以期解释电子迁移率。研究发现,有些迁移率特征和导带的填充过程与电子结构研究无关,如迁移率与能带的级别成比例。 |
4楼2011-03-18 12:37:33
