Your search keyword '"Parajuli, Prabin"' showing total 9 results

1. Quantum Shortcut to Adiabaticity for State Preparation in a Finite-Sized Jaynes-Cummings Lattice

Author

Cai, Kang, Parajuli, Prabin, Govindarajan, Anuvetha, and Tian, Lin

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

In noisy quantum systems, achieving high-fidelity state preparation using the adiabatic approach faces a dilemma: either extending the evolution time to reduce diabatic transitions or shortening it to mitigate decoherence effects. Here, we present a quantum shortcut to adiabaticity for state preparation in a finite-sized Jaynes-Cummings lattice by applying counter-diabatic (CD) driving along given adiabatic trajectories. Leveraging the symmetry of eigenstates in our system, we convert the CD driving to an implementable Hamiltonian that only involves local qubit-cavity couplings for a two-site lattice with one polariton excitation. Additionally, we derive a partial analytical form of the CD driving for the lattice with two excitations. Our numerical results demonstrate that circuit errors and environmental noise have negligible effects on our scheme under practical parameters. We also show that our scheme can be characterized through the detection of qubit operators. This approach can lead to a promising pathway to high-fidelity state preparation in a significantly reduced timescale when compared to conventional adiabatic methods., Comment: 12 pages, 7 figures

Published

2024

2. State Preparation in a Jaynes-Cummings Lattice with Quantum Optimal Control

Author

Parajuli, Prabin, Govindarajan, Anuvetha, and Tian, Lin

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

High-fidelity preparation of quantum states in an interacting many-body system is often hindered by the lack of knowledge of such states and by limited decoherence times. Here we study a quantum optimal control (QOC) approach for fast generation of quantum ground states in a finite-sized Jaynes-Cummings lattice with unit filling. Our result shows that the QOC approach can generate quantum many-body states with high fidelity when the evolution time is above a threshold time, and it can significantly outperform the adiabatic approach. We study the dependence of the threshold time on the parameter constraints and the connection of the threshold time with the quantum speed limit. We also show that the QOC approach can be robust against control errors. Our result can lead to advances in the application of the QOC for many-body state preparation., Comment: 10 pages, 6 figures, published

Published

2023

3. Database of semiconductor point-defect properties for applications in quantum technologies

Author

Ivanov, Vsevolod, Ivanov, Alexander, Simoni, Jacopo, Parajuli, Prabin, Kanté, Boubacar, Schenkel, Thomas, and Tan, Liang

Subjects

Quantum Physics, Condensed Matter - Materials Science, Physics - Applied Physics, Physics - Optics

Abstract

Solid-state point defects are attracting increasing attention in the field of quantum information science, because their localized states can act as a spin-photon interface in devices that store and transfer quantum information, which have been used for applications in quantum computing, sensing, and networking. In this work we have performed high-throughput calculations of over 50,000 point defects in various semiconductors including diamond, silicon carbide, and silicon. Focusing on quantum applications, we characterize the relevant optical and electronic properties of these defects, including formation energies, spin characteristics, transition dipole moments, zero-phonon lines. We find 2331 composite defects which are stable in intrinsic silicon, which are then filtered to identify many new optically bright telecom spin qubit candidates and single-photon sources. All computed results and relaxed defect structures are made publicly available online at quantumdefects.com, a living database of defect characteristics which will be continually expanded with new defects and properties, and will enable researchers to select defects tailored to their applications., Comment: 12 pages, 3 figures

Published

2023

4. Robust Preparation of Many-body Ground States in Jaynes-Cummings Lattices

Author

Cai, Kang, Parajuli, Prabin, Long, Guilu, Wong, Chee Wei, and Tian, Lin

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Strongly-correlated polaritons in Jaynes-Cummings (JC) lattices can exhibit quantum phase transitions between the Mott-insulating and superfluid phases at integer fillings. The prerequisite to observe such phase transitions is to pump polariton excitations into a JC lattice and prepare them into appropriate ground states. Despite previous efforts, it is still challenging to generate many-body states with high accuracy. Here we present an approach for the robust preparation of many-body ground states of polaritons in finite-sized JC lattices by optimized nonlinear ramping. We apply a Landau-Zener type of estimation to this finite-sized system and derive the optimal ramping index for selected ramping trajectories, which can greatly improve the fidelity of the prepared states. With numerical simulation, we show that by choosing an appropriate ramping trajectory, the fidelity in this approach can remain close to unity in almost the entire parameter space. This approach can shed light on high-fidelity state preparation in quantum simulators and advance the implementation of quantum simulation with practical devices., Comment: 9 pages, 7 figures

Published

2020

5. Quantum state preparation in Jaynes-Cummings lattices.

Author

Tian, Lin, Govindarajan, Anuvetha, Parajuli, Prabin, and Cai, Kang

Published

2024

6. Many-body Ground State Preparation in Jaynes-Cummings Lattices

Author

Parajuli, Prabin

Subjects

Physics

Abstract

In recent years, due to unprecedented success in controlling and manipulating an individual quantum system, simulation of quantum systems using quantum simulators or a quantum computer is becoming reality. In this thesis, the main goal is to study many-body correlations in quantum simulators and their impact on quantum information science. In particular, we focus on high fidelity many-body ground state preparation in Jaynes-cummings lattices in coupled cavity arrays. In the first work, we show that by combining quantum engineering and nonlinear adiabatic ramping, high fidelity many-body ground state can be prepared in a targeted region either in the Mott insulating phase or in the Superfluid phase. In the second project, we use the shortcuts to adiabaticity (STA) method for the fast and efficient many-body state preparation. We compare the fidelity obtained by using the simple adiabatic method and the STA method to show the advantage of the STA method over the adiabatic method. In the third project, we apply the quantum optimal control (QOC) technique with a chopped random basis (CRAB) algorithm to prepare high fidelity many-body ground states in minimal time in the Jaynes-Cummings lattices. The methods we used are general and can be used for state preparation in other quantum simulators or quantum computers.

Published

2022

7. State preparation in a Jaynes-Cummings lattice with quantum optimal control

Author

Parajuli, Prabin, primary, Govindarajan, Anuvetha, additional, and Tian, Lin, additional

Published

2023

8. Robust preparation of many-body ground states in Jaynes–Cummings lattices

Author

Cai, Kang, primary, Parajuli, Prabin, additional, Long, Guilu, additional, Wong, Chee Wei, additional, and Tian, Lin, additional

Published

2021

9. A comparative study of usability and accessibility of Norwegian educational institute websites for screen reader users based on user experience and automated assessment

Author

Parajuli, Prabin and Eika, Evelyn

Subjects

Web accessibility, Web usability, WCAG, Teknologi: 500::Informasjons- og kommunikasjonsteknologi: 550 [VDP], Norwegian universities, Universal designs, Web content accessibility guidelines, VDP::Teknologi: 500::Informasjons- og kommunikasjonsteknologi: 550, Screen readers, University websites

Abstract

Master i universell utforming av IKT A website is an essential part of the education system, mainly in schools or universities, as it aids the students with diverse abilities to access the information offering the flexibility in times and locations for learning and personal growth (Kuakiatwong & Whittier, 2011). However, due to the lack of accessibility and usability of the websites, the students with disabilities who solely rely on screen reader software faces challenges accessing the contents on the webpage. This study aims to assess the current level of accessibility and usability issues, screen reader students frequently encounter while interacting with the Norwegian University webpages. To address the research question, this study performed the sequential explanatory design approach to collect the data in two different phases. Quantitative data were collected at first using two automated tools and questionnaire to assess the accessibility and usability level of the selected websites. In the second phase, the study implemented follow-up interviews with the participants to address the further issues which were not discovered in the first phase. Sixteen visually impaired participants were recruited and were assigned the 5 usability tasks on 4 different university websites to analyze the usability and accessibility of sampled websites. Analysis from the qualitative and quantitative data demonstrated that none of the selected Norwegian University websites (N=4) met the minimum checkpoint requirement of WCAG 2.1. The findings further depicted that the average usability level of the educational websites in Norway was below average and, only one of the 4 evaluated websites came close to average usability score. In addition, based on the interview, the most remarkable accessibility issues discovered on Norwegian University webpages were poorly design of heading and link-list structure, screen reader incompatibility with the browsers, ambiguous link structure, and inaccessible keyboard navigation. Likewise, the majority of the participant response to most common usability issues they experienced on the webpages were poor labeling of the forms, duplication of page titles, awful labeling of links, inconsistent breadcrumb trail, and inadequate keyboard access on webpages. Further, correlating the results reported by two automated tools concluded that there was inconsistent between the two automated tools result. On this basis, it is recommended that manual accessibility evaluation of the website should be implemented to confirm the quantitative findings. It is further recommended that universities need to give emphasis to make a website to be accessible and usable to screen reader users. Further study is necessary to explore and overcome the limitations of the current study.

Published

2019