与T 5, T 8,T12和环形光管的形状、结构、电子特性和控制电路相同。
Same shape, structural and electrical characteristics and control circuits as for regular T5, T8, T12 and Circline lamps.
尽管这些元件的电子特性已经被充分了解,关于它们在实际中如何反转电阻还知之甚少。
While the electrical properties of these devices are now fairly well understood, very little has been known about how they actually undergo reversible changes in resistance.
富勒烯和碳纳米管以其独特的几何结构和丰富的电子特性引起了科研工作者的广泛关注。
Fullerene and carbon nanotubes have attracted much attention of the researchers due to their unique structure and rich electronic properties.
由于半导体量子点具有零维电子特性,它不仅成为基本物理研究的重要对象,也成为研制新一代量子器件的基础。
Quantum dots (QDs), with zero-dimensional electronic properties, have stimulated great interest due to their important roles in fundamental physical research and for developing novel devices.
在分析了电子重组的两大特性即电子特性与管理特性之后,针对常见的三种业务类型,提出了相应的电子重组模式。
Further, the paper analyzed two main attributes of ERBIT, electronic attribute and managerial attribute and then, put forward three patterns for typical business operation.
研究者们正在试图通过混合黑色的锰氧化物和其它的化学品,并且将它们加热到高的温度,来制造具有异常电子特性的化合物。
The researchers were trying to make compounds with novel electronic properties, mixing manganese oxide, which is black, with other chemicals and heating them to high temperatures.
石墨烯不仅是现今最薄的材料,而且具有非常奇特的电子性质,这些电子特性使石墨烯可以作为未来理想电子器件的首选材料。
Graphene not only is the thinnest material in the world, but also has a number of very peculiar electronic properties which make it a promising candidate for future electronic applications.
为了制备出高质量的、均匀的薄膜材料,这就要求我们对该系统中的等离子体特性,特别是对电子特性的空间分布规律进行深入的研究。
In order to deposit high quality and uniform thin films, it is necessary that we study the plasma characteristics in PECVD system, especially the spatial distribution of electron characteristics.
揭示了半导体表面微钠区城原子结构对其微纳区域表面和界面电子特性的影响,为认识半导体微纳区域表面和界面电子行为提供了新思路。
By using the adsorption of gas probe, we can understand the surface or interface electron character of functional semiconductor in micro-nano region in essentially from a new point of view.
但如果利用该特性建造电子显示屏,可研制出能改变形状或者质感的显示屏。
But by building the property into electronic displays, companies can now create screens that can change shape or texture.
由于这些特性,许多研究者认为,石墨烯可取代硅作为未来的电子材料。
Because of these properties, many researchers believe that graphene could replace silicon as the electronic material of the future.
如果您回想起有关该主题的上一篇文章,假定电子邮件地址是一个明确特性—用于合并来自不同源的描述。
If you recall from the previous article on this topic, the E-mail address is assumed to be an unambiguous property — used to merge descriptions from diverse sources.
实际上,可以使用一种称为模板图像的特性,从现有的纸质表单创建电子表单。
In fact, you can create an e-form from an existing paper form, using a feature called template image.
这些电子有着自旋特性,可能对地球磁场具有敏感性。
These electrons have a property called spin which may be sensitive to Earth's magnetic field.
但翻页的时候依然存在诡异的黑白闪烁过程——这是电子墨水无法避免的特性。
But the page turn moment still features a bizarre, black-white-black flashing sequence — a nonnegotiable characteristic of E Ink.
F-15SE拥有无与伦比的航空动力学技术、航空电子、雷达截面减少特性,为用户提供了适应多变高级威胁环境下的最大灵活度。
The F-15SE offers unique aerodynamic, avionic and Radar Cross Section reduction features that provide the user with maximum flexibility to dominate the ever-changing advanced threat environment.
基本上,在当时他只能通过大小,和特性来进行,但是现在我们已经知道了,我们还可以通过电子排布来对它们进行排序。
So basically, at the time he was just going on size and then traits, but what we actually know today is that we can also order things in the periodic table by electron configuration.
在您对其他人的描述中,引用他们的 mbox_sha1sum 特性而不是他们的电子邮件地址,对于您来说或许是有礼貌的。
In your descriptions of other people, it is probably courteous for you to reference their mbox_sha1sum property instead of their e-mail address.
TiO2因为是容易获取的单晶体并有易吸收电子的特性而被选中。
TiO2 was chosen because it is readily available as single crystals and can accept electrons easily.
Google最近的一些beta发行版(如日历和电子表应用程序)都具有这样的特性,这可能不是什么巧合。
It's probably no coincidence that this characterizes some of Google's recent beta releases, such as its Calendar and Spreadsheets applications.
LotusSametimeV7.5.1中另一个新增特性是安排Web会议自动向会议主持人和创建者发送包含会议详细内容的电子邮件通知。
Another plus in Lotus Sametime V7.5.1 is that scheduling a Web conference automatically sends email notification with the meeting details to the meeting moderator and creator.
像GoogleBooks这样的电子图书平台将很快成为一个对于本地搜索入口来说具有特性的替代工具。
Tools like Google Books and other ebook platforms will soon be serious alternatives to idiosyncratic, local search interfaces.
他们推测,此项技术,包括跳过有微波的电子对们来测试这种纠缠的影响,可以被用来应用于研究不同电子的纠缠的特性。
They surmise that the technique, which involves zapping the electron pairs with microwaves to test for entanglement, could be used to study the properties of entanglement in many different molecules.
然而,久而久之,由于人们更改电子邮件地址、离开项目等行为,该特性变得不是那么有用了。
However, over time, this feature becomes less useful as people change email addresses, leave the project, and so on.
在对本文中三个例子的详细讲解中,我们演示了如何使用ODFDOMAPI来创建文本、电子表格、演示odf文档的内容、样式、以及其他特性。
Using the three examples detailed in this article, we illustrated how to use the ODFDOM API to create the contents, styles, and other features of text, spreadsheet, and presentation ODF documents.
然后,学习了如何添加订阅特性,这样当用户订阅的文档类别中添加了新文档时,我们就可以通过电子邮件通知他们。
Then, you learned how to add a subscription feature so we can notify our users by email when new documents are added to the document category to which they are subscribed.
他们说,部分工具尚在开发中;其他的将会在已有的产品,像搜索、电子邮件、地图、照片、视频以及广告等上面添加特性。
Some of the tools are still being developed, they said; others will add features to existing products, like search, E-mail, maps, photos, video and ads.
社交网络,电子邮件,短信——这一切都拥有罕见的特性,就像是镇静剂,同时具备引发问题和解决问题的能力。
Social media, e-mail, text messaging—they all have that rare quality, like a narcotic, to be both the cause and the solution to a problem.
在先前的研究中得到其原子水平上的结构,精确的结构特性允许他们用激光脉冲瞄准目标分子,并且只持续千万一份之一秒以使分子处以单电子自旋状态。
That precise characterization allowed them to target molecules with laser pulses lasting for one-quadrillionth of a second, or just long enough to set single electrons spinning.
在先前的研究中得到其原子水平上的结构,精确的结构特性允许他们用激光脉冲瞄准目标分子,并且只持续千万一份之一秒以使分子处以单电子自旋状态。
That precise characterization allowed them to target molecules with laser pulses lasting for one-quadrillionth of a second, or just long enough to set single electrons spinning.
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