本文为您带来电荷的英文翻译，包括电荷用英语怎么说，电荷用英语怎么说，电荷的英语造句，电荷的英文原声例

本文为您带来电荷的英文翻译，包括电荷用英语怎么说，电荷用英语怎么说，电荷的英语造句，电荷的英文原声例句，电荷的相关英语短语等内容。

电荷的英文翻译，电荷的英语怎么说？

电荷的英语网络释义

I = C(dv/dt) 实际上，CEI的值比CISS高很多，必须要根据MOSFET生产商提供的栅极电荷（QG）指标计算。 QG是MOSFET栅极电容的一部分，计算公式如下： QG = QGS + QGD + QOD 其中： QG--总的栅极电荷 QGS--栅极-源极电荷 QG...

... effect of electric current in solutions 电流在溶液里的影响 electrical charge 电荷 electrical field 电场 ...

... effect t of electric current in solutions 电流在溶液里的影响 electrical l charge 电荷 electrical l field 电场 ...

电荷的汉英大词典

电荷[diàn hè]

• {物} electric charge; charge
• 短语:
  • 电荷半径 charge radius;
  • 电荷补偿 charge compensation;
  • 电荷捕捉剂 scavenger;
  • 电荷不对称参数 charge asymmetry parameter;
  • 电荷差 charge difference;
  • 电荷测量仪表 charge measuring instrument;
  • 电荷重正化 charge renormalization;
  • 电荷储存二级管 charge storage diode;
  • 电荷储存管 charge-storage tube;
  • 电荷储存系统 charge-storage [electric storage] system;
  • 电荷传递 charge transfer;
  • 电荷传输器件 charge-transfer device;
  • 电荷传送 charge transfer;
  • 电荷存储 charge storage; storage of charges;
  • 电荷存储触发器 charge-storage flip-flop;
  • 电荷存储电平 charge-storage level;
  • 电荷存储二极管 charge-storage diode;
  • 电荷存储管 charge storage tube;
  • 电荷存储效应 charge-storage effect;
  • 电荷单态 isosinglet;
  • 电荷单位 unit of charge;
  • 电荷单元 electric charge element;
  • 电荷电平 charge level;
  • 电荷电势 charge potential;
  • 电荷电阻炉 charge-resistance furnace;
  • 电荷定律 law of electric charges;
  • 电荷读出装置 charger-reader;
  • 电荷渡越时间 charge transition time;
  • 电荷对称 charge symmetry;
  • 电荷对称假设 charge-symmetry hypothesis;
  • 电荷对称介子 charge symmetric meson;
  • 电荷多重态 isomultiplet;
  • 电荷二重态 charge doublet;
  • 电荷发生电流charge generation current;
  • 电荷发生率 charge generation rate;
  • 电荷反演 charge reversal;
  • 电荷分布 charge distribution;
  • 电荷分布图 charge pattern;
  • 电荷分离 charge separation;
  • 电荷共轭 charge conjugation;
  • 电荷管 chargistor;
  • 电荷减少 loss of charge; decay;
  • 电荷减少法 loss-of-charge method;
  • 电荷交换 recharge; charge exchange;
  • 电荷交换反应 charge-exchange reaction;
  • 电荷交换相互作用 charge exchange interaction;
  • 电荷均衡模数转换器 charge equalizing A/D converter;
  • 电荷控制存储管 charge-controlled storage tube;
  • 电荷控制反应 charge controlled reaction;
  • 电荷控制分析 charge-control analysis;
  • 电荷控制理论 charge-control theory;
  • 电荷量 quantity of electric charge;
  • 电荷灵敏度 charge sensitivity;
  • 电荷漏泄 charge leakage;
  • 电荷密度 charge density; electric(-charge) density;
  • 电荷密度波 charge density wave;
  • 电荷耦合 charge coupled; charge coupling;
  • 电荷耦合成像器件 charge-coupled imaging device (CCID);
  • 电荷耦合存储器 CCD memory;
  • 电荷耦合横向滤波器 CCD transversal filter;
  • 电荷耦合器件 charge-coupled device (CCD);
  • 电荷耦合摄像传感器 {电子} charge-coupled image sensor; solidstate image sensor;
  • 电荷耦合摄像器（件） charge coupled imaging device;
  • 电荷耦合延迟线 charge-coupled delay line; CCD delay line;
  • 电荷耦合移位寄存器 CCD shift register;
  • 电荷谱 charge spectra;
  • 电荷谱仪 charge spectrometer;
  • 电荷起伏漏泄 charge pattern leakage;
  • 电荷迁移 charge migration;
  • 电荷容积效应 charge-volume effect;
  • 电荷守恒 charge conservation;
  • 电荷输运 charge transport;
  • 电荷数 charge number;
  • 电荷双重态 isodoublet;
  • 电荷位形 charge configuration;
  • 电荷位移 charge displacement;
  • 电荷无关（的） charge-independent;
  • 电荷徙动 charge migration;
  • 电荷像[起伏图] charge pattern;
  • 电荷宇称 charge parity;
  • 电荷云 charge cloud;
  • 电荷涨落 charge fluctuation;
  • 电荷-质量比 charge-to-mass ratio;
  • 电荷注入器件 {电} CID (charge-injection device);
  • 电荷贮存 charge storage;
  • 电荷转移 {物} {化} charge transfer;
  • 电荷转移过程 charge transfer process;
  • 电荷转移聚合 charge transfer polymerization;
  • 电荷转移络合物 charge transfer complex;
  • 电荷转移器件 {半} charge transfer device;
  • 电荷自旋 isospin

电荷的英语短语

电荷的英文例句

它们完全一样，除了电荷相反。

They are exactly alike, except that they have opposite electrical charges.

我怎么知道它的电荷分布呢？

How do I know its charge distribution?

空间内出现的微粒证明了电荷的存在。

The particles that materialize in the space make the charge manifest.

同性的电荷互相排斥。

Two like electric charges repel each other.

带负电荷的区域非常大：数百米厚，直径达几千米。

The negatively charged region is large: several hundred meters thick and several kilometers in diameter.

然后上升气流将轻盈的、带正电荷的冰晶带到云的顶部。

Then updraft wind currents carry the light, positively charged ice crystals up to the top of the cloud.

带负电荷的区域很大，有几百米厚，方圆直径达几公里。

The negatively charged region is large: several hundred meters thick andseveral kilometers in diameter.

我要说的是，完全相反，正电荷集中在中心，在一个非常非常小的体积内。

I'm going to say, quite to the contrary, the positive charge is concentrated at the center in a tiny, tiny, tiny volume.

在20世纪60年代早期，研究人员试图将火箭尾部的电线发射到雷云中，以便于为这些雷云产生的巨大电荷建立一个简单的放电路径。

In the early 1960s, researchers tried firing rockets trailing wires into thunderclouds to set up an easy discharge path for the huge electric charges that these clouds generate.

质子是带正电荷的物质的基本粒子。

A proton is an elementary particle of matter that possesses a positive charge.

由于这些电子都带负电荷，它们会相互排斥。

As these electrons are negatively charged they will attempt to repel each other.

大部分物体都是电荷平衡的——含等量的电子和质子。

Most things are balanced - with equal numbers of electrons and protons.

在暴风云的形成过程中，带正电荷的粒子与带负电荷的粒子相互分离。

The separation of positively and negatively charged particles takes place during the development of the storm cloud.

当这些负电荷距离地面不到100米时，会遇到一股来自地面的正电荷粒子流。

When a stream of these negatively charged electrons comes within 100 meters of the ground it is met by a stream of positively charged particles that comes up from the ground.

如果是原子质量一定，而电子很小，那么带正电荷的部分几乎占据了全部质量。

If the atom is fixed mass, and the electron is tiny, it must be the positives have all the mass.

带正电荷的粒子集中在云团的顶部和底部，但中间区域形成的是带负电荷的粒子。

Concentrations of positively charged particles develop at the top and bottom of the cloud, but the middle region becomes negatively charged.

为了利用这种基质金属蛋白酶，钱博士将他的荧光染料和一些正电荷一同连接在一个小的发夹形状的蛋白质分子的一端。

To make use of the MMPs, Dr. Tsien attaches his fluorescent dye, along with some positive charges, to one side of a small hairpin-shaped protein molecule.

当一只昆虫与它们擦身而过时，就会触发一种微小的电荷，电荷沿着树叶里的隧道向下移动，并打开泪液细胞膜上的小孔。

When an insect brushes against them, this triggers a tiny electric charge, which travels down tunnels in the leaf and opens up pores in the tear's cell membranes.

它们还是会掉下，尽管有电荷。

They will fall regardless of the charge.

磁场唯一的来源就是电荷和电流。

The only magnetism comes from electric charges and currents.

这是每电荷库伦,这是每摩尔库伦。

This is coulombs per charge and this is coulombs per mole.

那么氦原子核的电荷量是多少呢？

So what is the charge on a helium nucleus?

它们也许是带有正电荷的粒子。

They would be particles of positive charge.

单位电荷乘以单位电压会得到什么呢？

Unit charge times unit voltage then would give me what?

然后我们得到了净电荷。

And so now we have net charge.

它具有较高的电荷密度。

It is a high charged density.

原子核的电荷量是多少？

What is the charge of the nucleus?

这些电荷最终以闪电的形式释放。

This is eventually discharged as bolts of lightning.

这是一个负电荷，这是一个正电荷。

This is a point that's negative, and this is the point that's positive.

正电荷在这儿，负电荷在周围。

You've got a positive charge here with a negative charge around it.

电荷的原声例句

so, essentially, they're establishing or controlling or changing the difference between the charge inside the cell and the charge outside cell.

因此本质上来说，它们制造或者控制或者改变,细胞内外电荷之间的电位差。

So, when we get really close together, granted, there is a net positive negative charge with a Coulombic force of attraction.

当它们真正离得很近时，假设有一个带正负电的电荷,带有库仑引力。

And in this case, the tie-breaker goes to the molecule in which the negative charge is on the most electronegative atom.

而在这种情况下，我们需要进行“附加赛“,也就是看看分子中带有负的,形式电荷的原子是不是电负性最高的。

He found a distribution. And, if you look more closely at the distribution, here is what he found.

他发现了分布，如果你仔细观察电荷分布的话，这就是他发现的。

So we'll talk specifically about drawing Lewis structures and then about formal charge and resonance, which are within Lewis structures.

因此我们会专门讲一讲,如何来画路易斯结构,然后再讨论形式电荷与共振论，它们也属于路易斯结构的范畴。

So now that we have enough practice drawing Lewis structures let's talk about actually figuring out this formal charge.

那么现在我们已经做了足够多的画路易斯结构的练习,让我们来讨论一下如何得出形式电荷。

So, an energy deficit, accelerating charge, the accelerating negative charge, because it's the negatives that are orbiting the positive center.

能量的损失，加速电荷，加速的负电荷，因为这是负电荷,围绕在正电荷中心的周围。

And since we don't have to charge compensate, we can add or subtract neutrons at liberty.

因为我们没有电荷补偿，我们就可以随意地加上火减少中子。

So if we add them all up, there should be no net charge on the molecule, if the molecule is neutral.

因此如果我们把它们都加起来，这个分子上应该没有净电荷，如果这个分子是中性的话。

So that means that the more stable molecule is going to be this molecule here, which actually puts the negative charge on be more electronegative atom.

因此这意味着更稳定的分子,应该是这一个，它真正把负的电荷放到了,电负性更高的原子上。

And let's say our second electron now is really far away, such that it's actually not going to shield any of the nuclear charge at all from that first electron.

距离原子核非常非常近,我们说第二个电子处于非常远的位置,这样它不会对第一个电子,感受到的来自原子核的电荷量有任何屏蔽作用,我们最后要说的是。

And this spin is an intrinsic quality of the electron, it's a property that is intrinsic in all particles, just like we would say mass is intrinsic or charge is intrinsic.

自旋是电子的本征量，它是所有粒子的本征性质，就像我们说质量是本征的或者电荷是本征的。

So for example, that might have a formal charge of negative 1, because to some extent it has gained that much electron density that it now has a formal charge that's negative.

比如，可能它的形式电荷为负一，因为在一定程度上它得到了这么多的共用电子密度,那么它现在就有了负的形式电荷。

So let's do this considering, for example, what it would look like if we were to write out the electron configuration for oxygen where z is going to be equal to 8.

我们来做这个考虑，举例来说,如果我们写出,有效电荷量为8的氧的电子构型。

But what's important is not where that most probable radius is when we're talking about the z effective it feels, what's more important is how close the electron actually can get the nucleus.

但重要的不是,最可能半径,当我们谈论它感到的有效电荷量的时候，更重要的是,电子实际上。

So if you have some charge in the nucleus, but you also have repulsion with another electron, the net attractive charge that a given electron going to feel is actually less than that total charge in the nucleus.

所以如果在原子核中，有一些电荷但是你也有来自，另一个电子的排斥力,那么一个给定电子的,吸引电荷感觉到的事实上,小于原子核中的总电荷。

So we can do this for any final charge we have, if we have a molecule that has a charge of plus 2, then all of the formal charges should add up to plus 2 and so on.

对于任意净电荷的情况,我们都可以这样做，比如假设我们有一个带两个正电荷的分子，那么所有的形式电荷加起来应该等于正二，等等。

All right. So formal charge can actually help us out when we're trying to decide between several Lewis structures that look like they might be comparable in terms of which might be the lower energy or the more stable structure.

好的，形式电荷真的可以,帮助我们决定,在几种路易斯结构中,哪个更可能符合能量更低,或者结构更稳定的要求。

And it does, so we know that we're probably on target in terms of calculating our formal charge.

而它确实是这样，因此我们知道我们很有可能,算对了我们的形式电荷。

And our eighth step in the process, again, is formal charge, which we will talk about very soon.

而我们流程中的第八步，同样是，形式电荷，我们很快就会讨论它。

Charge is quantized. And, secondly,he was able to measure the value of the elemental charge.

电荷是量子化的，第二，他能,测量出电荷基本的量值。

Of course, if we saw no shielding at all what we would end up with 3 is a z effective of 3.

当然如果我们说没有任何屏蔽,我们最后得到的,有效电荷量是。

And then we end up having 6 shared electrons, 2 from each of the bonds, so we end up with a formal charge on sulfur of plus 1.

然后我们有六个共用电子，每个键两个，因此最终硫的形式电荷量为正一。

So again, when we check these, what we want to see is that our z effective falls in between the two extreme cases that we could envision for shielding.

所以当我们再一次检查这些时，我们想看到的是,有效电荷量处于两种极端案例中,这两种极端案例。

What people did is they said let's define a unit of energy that represents a unit charge accelerated across a unit potential difference, and let's call that the electron volt.

前人们所做的就是他们说让我们确定,一个能量单位用来代表一单位电荷,加速穿过形成的一单位电势差，我们叫它电子伏特。

Again we have the charge of the nucleus on plus 2, +2 but let's say this time the electron now is going to be very, very close to the nucleus.

对于我们的氦原子，我们有一次得到了原子核电荷量为,但是我们说这次电子。

But I want you to tell me in terms of thinking about formal charge, which Lewis structure would you predict to be the most stable?

但我想让大家告诉我,从形式电荷的角度考虑，你会预测哪一个路易斯结构是最稳定的？

So, these are the different ways that we can actually go ahead and use formal charge when we're choosing between different types of Lewis structures.

那么，这些就是在我们需要在,不同的路易斯结构之间做选择的时候,我们如何用形式电荷来进行判断的各种方法。

The smallest charge I could put here would be 1.6 times 10 to the minus 19 coulombs.

能放在这里的最小电荷,是1。6*10^-19，库仑。

But what I'm going to tell you already is this is a case where, in fact, it's an exception to the idea that the lowest energy structure has the lowest ionization energy in the middle, and we can figure this out when we look at formal charge.

但是我已经告诉大家这个例子，实际上，是中心原子电离能最低的结构,的能量最低这一思路的一个例外，我们可以通过形式电荷看出这一点。

电荷的网络释义

电荷 电荷（electric charge），为物体或构成物体的质点所带的正电或负电，带正电的粒子叫正电荷（表示符号为“+”），带负电的粒子叫负电荷（表示符号为“﹣”）。也是某些基本粒子(如电子和质子)的属性，同种电荷相互排斥，异种电荷相互吸引。 在电磁学里，电荷diànhè（Electric charge）是物质的一种物理性质。称带有电荷的物质为“带电物质”。两个带电物质之间会互相施加作用力于对方，也会感受到对方施加的作用力，所涉及的作用力遵守库仑定律。电荷分为两种，“正电荷”与“负电荷”。带有正电荷的物质称为“带正电”；带有负电荷的物质称为“带负电”。假若两个物质都带有正电或都带有负电，则称这两个物质“同电性”，否则称这两个物质“异电性”。两个同电性物质会相互感受到对方施加的排斥力；两个异电性物质会相互感受到对方施加的吸引力。同种电荷互相排斥，异种电荷互相吸引。 电荷是许多次原子粒子所拥有的一种基本守恒性质。称带有电荷的粒子为“带电粒子”。电荷决定了带电粒子在电磁方面的物理行为。静止的带电粒子会产生电场，移动中的带电粒子会产生电磁场，带电粒子也会被电磁场所影响。一个带电粒子与电磁场之间的相互作用称为电磁力或电磁相互作用。这是四种基本相互作用中的一种。

以上关于电荷的英语翻译来自英汉大词典，希望对您学习电荷的英语有帮助。