量子蒙地卡羅是一個數值方法,可用來模擬量子多體系統,像是自旋模型以及強關聯電子系統。這個模擬可以得到在虛數時間軸上的兩點關聯函數,然而真實實驗卻只能量測在實數時間軸上的動態特徵,像是能量激發態的頻譜。為了更容易比較模擬與實驗的結果,利用解析延拓將虛數軸上的關聯函數延伸到實數軸上是一個常見且重要的過程。 在這篇論文中,我們將探討如何使用隨機採樣的方法來完成這個解析延拓。藉由設計不同的採樣過程,我們可以在不同型態的頻譜上都得到相當精準的解析結果,而我們更進一步使用這些方法來研究一維海森堡自旋模型的動態結構因子。 除此之外,我們提出了一個新的架構,將哈密頓蒙地卡羅用於採樣方法上,結果顯示這是一個值得未來繼續研究的方向。
Quantum Monte Carlo (QMC) is a useful numerical method for simulating quantum many body systems, such as spin models and strongly correlated electronic systems. Most QMC simulations provide two point correlation functions in imaginary time, however, most experiments only probe real-time dynamical properties such as dynamical susceptibilities and elementary excitations in energy (or frequency) domain. To bridge the gap, analytic continuation is an essential tool. In this thesis, we demonstrate how to perform analytic continuation by using stochastic methods. We get resulting spectrum in high precision through many strategies of proposing updates in the sampling process. Therefore, we further employ it to study the dynamical structure factor in Heisenberg spin chain under zero and non-zero magnetic field. Besides, we also demonstrated a HMC-SAC scheme which exploits Hamiltonian Monte Carlo to generate global updates in the sampling process. Results show that this scheme is a promising direction for future study.
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