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引用次数: 0
摘要
摘要 利用外部变形单体振荡器势的三维量子系统的挤压过程也可以用 d 方法来描述,但不需要外部场,而且维数可以取非整数值。在这项工作中,我们首先将这两种方法推广到 N 个粒子和低于 3 维的任何转换。一旦做到这一点,利用粒子之间的谐振子相互作用,就可以得到这两种方法的完整解析解,从而可以对它们进行直接比较。假设这两种方法描述的是相同的过程,导致相同的基态能量和波函数,那么这两种方法之间就会产生分析等价性。我们首先对两个相同玻色子、从三维到二维和一维的挤压跃迁以及从二维到一维的挤压跃迁检验了这两种方法之间的等价性以及它们之间推导出的解析关系的有效性。我们还研究了由三个相同玻色子组成的系统从 3 维到 1 维的对称挤压。我们发现,在所有情况下,这两种方法之间的推导分析关系都非常有效。在这种情况下,从数值的角度来看,使用外部场的蛮力数值计算要求过高,特别是对于有两个以上粒子的系统。
Confinement of N-Body Systems and Non-integer Dimensions
The squeezing process of a three-dimensional quantum system by use of an external deformed one-body oscillator potential can also be described by the d-method, without external field and where the dimension can take non-integer values. In this work we first generalize both methods to N particles and any transition between dimensions below 3. Once this is done, the use of harmonic oscillator interactions between the particles allows complete analytic solutions of both methods, and a direct comparison between them is possible. Assuming that both methods describe the same process, leading to the same ground state energy and wave function, an analytic equivalence between the methods arises. The equivalence between both methods and the validity of the derived analytic relation between them is first tested for two identical bosons and for squeezing transitions from 3 to 2 and 1 dimensions, as well as from 2 to 1 dimension. We also investigate the symmetric squeezing from 3 to 1 dimensions of a system made of three identical bosons. We have in all the cases found that the derived analytic relations between the two methods work very well. This fact permits to relate both methods also for large squeezing scenarios, where the brute force numerical calculation with the external field is too much demanding from the numerical point of view, especially for systems with more than two particles.
期刊介绍:
The journal Few-Body Systems presents original research work – experimental, theoretical and computational – investigating the behavior of any classical or quantum system consisting of a small number of well-defined constituent structures. The focus is on the research methods, properties, and results characteristic of few-body systems. Examples of few-body systems range from few-quark states, light nuclear and hadronic systems; few-electron atomic systems and small molecules; and specific systems in condensed matter and surface physics (such as quantum dots and highly correlated trapped systems), up to and including large-scale celestial structures.
Systems for which an equivalent one-body description is available or can be designed, and large systems for which specific many-body methods are needed are outside the scope of the journal.
The journal is devoted to the publication of all aspects of few-body systems research and applications. While concentrating on few-body systems well-suited to rigorous solutions, the journal also encourages interdisciplinary contributions that foster common approaches and insights, introduce and benchmark the use of novel tools (e.g. machine learning) and develop relevant applications (e.g. few-body aspects in quantum technologies).
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