@article{sun_liu_wang_qin_schnedermann_maher_zheng_liu_chen_zhang_et al._2022, title={Syntheses and Properties of Metalated Tetradehydrocorrins}, volume={61}, ISSN={["1520-510X"]}, DOI={10.1021/acs.inorgchem.2c01642}, abstractNote={The monoanionic tetrapyrrolic macrocycle B,C-tetradehydrocorrin (TDC) resides chemically between corroles and corrins. This chemical space remains largely unexplored due to a lack of reliable synthetic strategies. We now report the preparation and characterization of Co(II)- and Ni(II)-metalated TDC derivatives ([Co-TDC]+ and [Ni-TDC]+, respectively) with a combination of crystallographic, electrochemical, computational, and spectroscopic techniques. [Ni-TDC]+ was found to undergo primarily ligand-centered electrochemical reduction, leading to hydrogenation of the macrocycle under cathodic electrolysis in the presence of acid. Transient absorption (TA) spectroscopy reveals that [Ni-TDC]+ and the two-electron-reduced [Ni-TDC]- possess long-lived excited states, whereas the excited state of singly reduced [Ni-TDC] exhibits picosecond dynamics. The Co(I) compound [Co-TDC] is air stable, highlighting the notable property of the TDC ligand to stabilize low-valent metal centers in contradistinction to other tetrapyrroles such as corroles, which typically stabilize metals in higher oxidation states.}, number={31}, journal={INORGANIC CHEMISTRY}, author={Sun, Rui and Liu, Mengran and Wang, Pengzhi and Qin, Yangzhong and Schnedermann, Christoph and Maher, Andrew G. and Zheng, Shao-Liang and Liu, Sijia and Chen, Boyang and Zhang, Shaofei and et al.}, year={2022}, month={Aug}, pages={12308–12317} }
 @article{jing_wang_chen_jiang_vairaprakash_liu_rong_chen_nalaoh_lindsey_2022, title={Synthesis of bacteriochlorins bearing diverse beta-substituents}, volume={3}, ISSN={["1369-9261"]}, DOI={10.1039/d1nj05852e}, abstractNote={Eleven bacteriochlorins have been prepared for surface attachment, bioconjugation, water-solubilization, vibrational studies, and elaboration into multichromophore arrays.}, journal={NEW JOURNAL OF CHEMISTRY}, author={Jing, Haoyu and Wang, Pengzhi and Chen, Boyang and Jiang, Jianbing and Vairaprakash, Pothiappan and Liu, Sijia and Rong, Jie and Chen, Chih-Yuan and Nalaoh, Phattananawee and Lindsey, Jonathan S.}, year={2022}, month={Mar} }
 @article{hafiz_chen_chen_queiroz_husain_2019, title={Utilising demand response for distribution service restoration to achieve grid resiliency against natural disasters}, volume={13}, ISSN={["1751-8695"]}, url={http://www.scopus.com/inward/record.url?eid=2-s2.0-85069476402&partnerID=MN8TOARS}, DOI={10.1049/iet-gtd.2018.6866}, abstractNote={The increased frequency of power outages due to natural disasters in recent years has highlighted the urgency of enhancing distribution grid resilience. The effective distribution service restoration (DSR) is an important measure for a resilient distribution grid. In this work, the authors demonstrate that DSR can be significantly improved by leveraging the flexibility provided by the inclusion of demand response (DR). The authors propose a framework for this by considering integrated control of household-level flexible appliances to vary the load demand at the distribution-grid level to improve DSR. The overall framework of the proposed system is modelled as a three-step method considering three optimization problems to (i) calculate feasible controllable aggregated load range for each bus, (ii) determine candidate buses to perform DR and their target load demand, and (iii) maintain the load level in each house through home energy management during the DSR, considering uncertainties in load and solar generation sequentially. The optimization problems are formulated as linear programming, mixed-integer linear programming, and multistage stochastic programming (solved using the stochastic dual dynamic programming) models. Case studies performed in the IEEE 123-node test feeder show improvements in resilience in terms of energy restored compared to the restoration process without DR.}, number={14}, journal={IET GENERATION TRANSMISSION & DISTRIBUTION}, publisher={Institution of Engineering and Technology (IET)}, author={Hafiz, Faeza and Chen, Bo and Chen, Chen and Queiroz, Anderson Rodrigo and Husain, Iqbal}, year={2019}, month={Jul}, pages={2942–2950} }