quantum electrodynamics

To treat the problem fully requires the use of quantum electrodynamics .

完整地讨论这个问题需要应用量子电动力学。

" Explain quantum electrodynamics in two minutes , starting now . "

“用两分钟时间解释一下量子电动力学，现在开始。”

A door is called the cavity quantum electrodynamics research subject gradually establish and develop .

一门被称为腔量子电动力学的的研究学科逐步建立并发展起来。

Out of quantum electrodynamics come all known electrical mechanical , and chemical laws .

从量子电动力学可以得出所有已知的电学、力学和化学定律。

Thus , the results of cavity quantum electrodynamics can be reasonably utilized .

于是，腔量子电动力学的重要研究成果就可以被合理地利用起来。

Derivative to Express on Effective Potential in Quantum Electrodynamics

量子电动力学中有效势的积分表示式

Spontaneous symmetry Breakdown and an Integral Expression of the Effective Potential in Quantum Electrodynamics

自发对称性破缺与量子电动力学中有效势的积分表示式

Finally , the two-photon transition is studied using the research method of spontaneous emission in quantum electrodynamics .

最后用QED中研究光场辐射的方法研究此四能级系统的双光子跃迁。

Progress in the study on microcavities and cavity quantum electrodynamics

微腔与腔量子电动力学研究进展

Cesium Double Magneto - Optical Trap for Cavity - Quantum Electrodynamics

用于腔量子电动力学研究的铯原子双磁光阱

The formation of renormalization theory in quantum electrodynamics

量子电动力学重整化理论的形成

Interaction of the cavity field with an atom is expound by the cavity quantum electrodynamics .

由此发展起来的腔量子电动力学能够阐述腔场与原子的相互作用。

Based on the cavity quantum electrodynamics , a scheme to implement the transformations of quantum cloning is proposed .

基于腔量子电动力学，提出实现这类量子克隆幺正变换的实验方案。

These can be explained by the Quantum Electrodynamics .

这类影响能从量子电动力学得到说明。

Cavity quantum electrodynamics ( cavity QED ) is one of physical system which can realize the quantum entanglement .

腔量子电动力学（腔QED）是一种可以实现量子纠缠的物理体系，它具有非常好的前景。

Our numerical results are in agreement with the Quantum Electrodynamics ( QED ) prediction with in the error .

结果与量子电动力学（QED）的预言一致。

People have put forward several generation schemes of two-particle or several-particle entanglement using quantum electrodynamics method in recent years .

近年来人们利用腔量子电动力学方法提出了多种两粒子和多粒子纠缠的制备方案。

Quantum electrodynamics ( QED ) effect and the contribution of higher order relativistic effects are calculated by effective nuclear charge theory .

以有效核电荷方法计算量子电动力学（QED）效应和高阶相对论效应的贡献。

γ- matriees in quantum electrodynamics are derived from the metric equation .

在四元数空间中，从度规方程出发，也可导出量子电动力学中的γ矩阵；

Schemes for Realizing Parametric Down-conversions in Cavity Quantum Electrodynamics

基于腔QED来实现参量下转换过程的方案

Lightning by Cavity Quantum Electrodynamics ?

空洞的量子电动力能够引发闪电吗？（英文）

Scalar quantum electrodynamics with Chern-Simons term in ( 2 + 1 ) dimensions

含Chern-Simons项的（2+1）维标量量子电动力学

Cavity quantum electrodynamics ( C-QED ) is an experimental system to study the quantum behavior of interaction between atoms and photons .

腔量子电动力学（CavityQuantumElectrodynamics，简称CavityQED）是研究光子与原子相互作用的一种有力工具。

Quantum electrodynamics theory of high-order above-threshold ionization

高阶阈值上电离的量子电动力学理论

Quantum Electrodynamics without Gauges

无规范的量子电动力学

The general four-photon processes and coherent anti-Stokes Raman effect based on the basic principle for the quantum electrodynamics are discussed in some detail .

以量子电动力学的基本理论为依据，从最一般的四光子过程入手，给出了相干反StokesRaman效应的量子解积。

With the advent of the quantum electrodynamics and laser , the interactions between the material and light become the focal point of the academia .

随着量子电动力学的发展和激光的问世，光与物质相互作用成为人们关注的焦点。

Quantum electrodynamics formulas are applied to calculate the spontaneous emission rate of an excited atom in the vicinity of a perfect reflecting mirror .

利用腔量子电动力学计算了原子在全反射镜面附近的自发辐射率。

Cavity quantum electrodynamics ( CQED ), as one of the most conventional system in preparing entangled atoms , plays an important role in quantum information processing .

腔量子电动力学（QED）体系是制备多原子纠缠态的重要的工具，在量子信息过程中扮演重要角色。

The incredible success of quantum electrodynamics raises the question . What they can do : provide anti-aging protection by guarding against free radicals .

量子电动力学惊人的成功引起了这一问题。功效：通过阻止自由基活动起抗衰老的作用。