漫步石馬公園櫻花隧道, 花海映襯在藍天與翠綠茶園中, 如大地織錦,令人驚歎! 當地傳說「石馬與孟宗竹」 在大快朵頤極富盛名的鱒魚、竹筍特產時,更添趣味! 位於鹿谷山谷中的小半天 半山腰終年雲霧繚繞, 遠觀宛如人間仙境, 故得「小半天」美名〜 想像空間團隊應變施工、氣候等條件 將作品進行「室內創作、戶外組裝」的應變方式。 無論您是慕名前往、初來乍到的訪客 抑或是感嘆景色美不勝收、意猶未盡的遊人, 皆能為眼前想像空間團隊所詮釋的在地意象, 感到莞爾一笑〜 我們是想像空間藝術設計工作室 我們創作每個人心中的「小半天」!
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Quantum Information Science
Quantum Information Science banenr
Our work in the quantum information subfield follows the integrated approach to quantum science embodied in the NarangLab. At the hardware level we work on many of the most promising quantum computing technologies - from the well established super-conducting platforms to photonic architectures with their promise of faster, potentially room-temperature devices - in collaboration with partners across industry and academia. Higher up the quantum technology stack, we work on quantum firmware-level circuit optimization and compilation tasks, while at the software level our work on classical preprocessing enables fruitful utilization of otherwise limited near term Noisy Intermediate-Scale Quantum hardware.
Prof. Narang’s newly developed class (ES 170, Quantum Engineering) at Harvard covers many of these topics in an immediate and practical fashion, and uses IBM's open-source quantum platforms to run NISQ algorithms and simulate molecules and materials. Course materials are readily available at request.
Our work on building blocks and quantum hardware
Optical quantum hardware promises much higher clock-rates compared to more mature platforms, as well as the potential to work at non-cryogenic temperatures. However, it also faces challenges due to the difficulty to create nonlinear interactions between photonic qubits. The group is exploring multiple lines of attack to these challenges, including the design of novel quantum defects, exotic vacancies in diamond lattices, and strongly nonlinear optical materials. At the same time, we are exploring quantum control schemes and corresponding bosonic error correcting codes that simplify the material requirements for such devices.
Our work on quantum compilation and circuit optimization
In the era of noisy-intermediate-scale quantum computers, we expect to see quantum devices with increasing numbers of qubits emerge. However, the connectivity between qubits will remain restricted, necessitating careful allocation of quantum registers to avoid costly operations, moving qubits between sparsely connected regions of the quantum chip. In the NarangLab we are developing compilation and circuit-optimization classical algorithms to optimize this allocation task, enabling the use of the hardware for otherwise prohibitive tasks.
Our work on algorithms for small quantum devices
QAOA, VQE and other variational quantum-classical quantum algorithms have gained a great deal of attention as some of the most promising algorithms able to be run on near-term noisy quantum devices. However, improperly chosen initialization parameters for these algorithms can severely hamper their performance. By employing both classical and quantum optimization techniques for the pre- and post-processing steps, we develop methods to significantly improve the performance of these hybrid algorithms.
Building Blocks and Hybrid Quantum Systems for Quantum Information Science
Recent Papers:
Tian, X., Kim, D.S., Yang, S., Ciccarino, C.J., Gong, Y., Yang, Y., Yang, Y., Duschatko, B., Ajayan, P.M., Idrobo, J-C., Narang, P., & Miao, J. (2020). Correlating 3D crystal defects and electronic properties of 2D materials at the single-atom level. Nature Materials 19, 867 - 873, published March 2020, highlighted in ‘News and Views’ Article titled ‘A 3D map of atoms in 2D materials’.
Hayee, F., Yu, L., Zhang, J.L., Ciccarino, C.J., Nguyen, M., Marshall, F., Aharonovich, I., Vuckovic, J., Narang, P., Heinz, T.F, & Dionne, J.A. (2020). Correlated optical and electron microscopy reveal the role of multiple defect species and local strain on quantum emission. Nature Materials 19 (5), 534 - 539.
Head-Marsden, K., Flick, J., Ciccarino, C.J. & Narang, P. (2021). Quantum Information and Algorithms for Correlated Quantum Matter. Chemical Reviews, 121, 5, 3061-3120.
Neuman, T., Wang, D.S., & Narang, P. (2020). Nanomagnonic cavities for strong spin-magnon coupling. Physical Review Letters 125 (24), 247702.
Ciccarino, C.J., Flick, J., Harris, I.B., Trusheim, M.E., Englund, D., & Narang, P. (2020). Strong Spin-Orbit Quenching via the Product Jahn-Teller Effect in Neutral Group IV Artificial Atom Qubits in Diamond. npj Quantum Materials, 5, 75.
Wang, D.S., Neuman, T., & Narang, P. (2020). Dipole-Coupled Defect Pairs as Deterministic Entangled Photon Pair Sources. Physical Review Research, 2 (4),043328.
Harris, I.B., Ciccarino, C.J., Flick, J., Englund, D.R. & Narang, P. (2020). Group III Quantum Defects in Diamond are Stable Spin-1 Color Centers. Physical Review B, 102 (19), 195206.
Wang, D.S., Ciccarino, C.J., Flick, J., & Narang, P. (2021). Hybridized defects in solid-state materials as artificial molecules. ACS Nano.
Neuman, T., Wang, D.S., & Narang, P. (2021). Spin emitters beyond the point dipole approximation in nanomagnonic cavities. arXiv preprint, arXiv:2012.04662. The Journal of Physical Chemistry.
Krastanov, S., Heuck, M., Shapiro, J.H., Narang, P., Englund, D.R., & Jacobs, K. (2021). Room-temperature photonic logical qubits via second-order nonlinearities. Nature Communications, 12, 191.
Reidy, K., Varnavides, G., Dahl Thomsen, J., Kumar, A., Pham, T., Blackburn, A.M., Anikeeva, P., Narang, P., LeBeau, J.M. & Ross, F.M. (2021). Direct Imaging and Electronic Structure Modulation of Double Moiré Superlattices at the 2D/3D Interface. Nature Communications, 12, 1290.
Quantum Algorithms and Quantum Network Science
Recent Papers:
Head-Marsden, K., Krastanov, S., Mazziotti, D.A., & Narang, P. (2021). Capturing Non-Markovian Dynamics on Near-Term Quantum Computers. Physical Review Research, 3 (1), 013182.
Neuman, T., Trusheim, M., & Narang, P. (2020). Selective acoustic control of photon-mediated qubit-qubit interactions. Physical Review A, 101 (5), 052342.
Neuman, T., Eichenfield, M., Trusheim, M., Hackett, L., Narang, P., & Englund, D. (2020). A Phononic Bus for Coherent Interfaces Between a Superconducting Quantum Processor, Spin Memory, and Photonic Quantum Networks. arXiv preprint, arXiv:2003.08383. To appear at npj Quantum Information.
Krastanov, S., Head-Marsden, K., Zhou, S., Flammia, S.T., Jiang, L., & Narang, P. (2020). Unboxing Quantum Black Box Models: Learning Non-Markovian Dynamics. arXiv preprint, arXiv:2009.03902. Under revisions.
Krastanov, S., Sanchez de la Cerda, A. & Narang, P. (2021). Heterogeneous Multipartite Entanglement Purification for Size-Constrained Quantum Devices. arXiv preprint, arXiv:2011.11640. Under revisions.
疑求復合不成 嘉義23歲役男涉槍殺前女友
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2021年6月16日 週三 下午8:52·1 分鐘 (閱讀時間)
疑似感情糾紛釀悲劇!嘉義縣水上鄉今天下午發生一起槍擊案,23歲現役軍人梁姓嫌犯持改造手槍槍擊前女友致死;警方表示,疑男方要求復合不成憤而朝女方胸口開槍;已在案發現場逮捕嫌犯,全案尚在調查中。
嘉義縣警局水上分局表示,23歲尚在服役中的梁姓嫌犯,與22歲王姓女子發生感情糾紛,今天從北部南下,下午5時許到水上鄉柳鄉村找王女談判,要求復合不成,梁男竟對王女開槍,一槍打中胸口,王女阿姨見狀立刻報警,員警到場逮捕兇嫌,並叫救護車將傷者送醫。
台中榮總嘉義分院表示,王女胸口遭槍傷,到院時已無呼吸心跳,經搶救仍宣告不治。
水上分局表示,現場起獲犯案改造槍枝1把及子彈7發,嫌犯訊後將依違反刑法殺人罪、槍砲彈藥刀械管制條例罪嫌,移送嘉義地檢署偵辦。