BEGIN:VCALENDAR VERSION:2.0 PRODID:-//UCLA - ECPv5.14.1//NONSGML v1.0//EN CALSCALE:GREGORIAN METHOD:PUBLISH X-WR-CALNAME:UCLA X-ORIGINAL-URL:https://www.chemistry.ucla.edu X-WR-CALDESC:Events for UCLA REFRESH-INTERVAL;VALUE=DURATION:PT1H X-Robots-Tag:noindex X-PUBLISHED-TTL:PT1H BEGIN:VTIMEZONE TZID:America/Los_Angeles BEGIN:DAYLIGHT TZOFFSETFROM:-0800 TZOFFSETTO:-0700 TZNAME:PDT DTSTART:20200308T100000 END:DAYLIGHT BEGIN:STANDARD TZOFFSETFROM:-0700 TZOFFSETTO:-0800 TZNAME:PST DTSTART:20201101T090000 END:STANDARD BEGIN:DAYLIGHT TZOFFSETFROM:-0800 TZOFFSETTO:-0700 TZNAME:PDT DTSTART:20210314T100000 END:DAYLIGHT BEGIN:STANDARD TZOFFSETFROM:-0700 TZOFFSETTO:-0800 TZNAME:PST DTSTART:20211107T090000 END:STANDARD END:VTIMEZONE BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210201T160000 DTEND;TZID=America/Los_Angeles:20210201T160000 DTSTAMP:20260615T191820 CREATED:20210104T181103Z LAST-MODIFIED:20210104T181103Z UID:13407-1612195200-1612195200@www.chemistry.ucla.edu SUMMARY:Chem 228: Prof. Benjamin J Eggleton DESCRIPTION:“Multidisciplinary (mission directed) research in nanotechnology at the University of Sydney” URL:https://www.chemistry.ucla.edu/seminars/chem-228-prof-benjamin-j-eggleton/ CATEGORIES:Physical Chemistry Seminar,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210129T153000 DTEND;TZID=America/Los_Angeles:20210129T153000 DTSTAMP:20260615T191820 CREATED:20210104T172053Z LAST-MODIFIED:20210104T172053Z UID:13399-1611934200-1611934200@www.chemistry.ucla.edu SUMMARY:Chem 268: Prof. Tanja Kortemme DESCRIPTION:“Switches\, sensors\, and new shapes: from design of new functions to cellular consequences of allostery” URL:https://www.chemistry.ucla.edu/seminars/chem-268-prof-tanja-kortemme/ CATEGORIES:Biochemistry,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210128T160000 DTEND;TZID=America/Los_Angeles:20210128T160000 DTSTAMP:20260615T191820 CREATED:20210112T010611Z LAST-MODIFIED:20210112T010611Z UID:13416-1611849600-1611849600@www.chemistry.ucla.edu SUMMARY:Prioritizing the patient - The discovery of lorlatinib\, a macrocyclic ALK inhibitor for the treatment of resistant and metastatic NSCLC DESCRIPTION:Abstract: Primary and secondary mutations in anaplastic lymphoma kinase (ALK) are oncogenic. Insights into ALK acquired resistance were used to define a drug design strategy that led to the discovery of lorlatinib (Lorbrena; PF-06463922)\, a novel ATP-competitive macrocyclic inhibitor of ALK and ROS1 kinases. Structure based drug design\, lipophilic efficiency and physicochemical property-based optimization provided inhibitors with overlapping broad-spectrum potency\, low transporter efflux\, and brain penetration. The small\, cyclic design provided a unique structure with unique properties. NMR and other analytical methods were used to study the unique molecular properties\, including atropisomerism for some analogues. Protein dynamics from x-ray crystallographic data and molecular dynamics simulations performed on ALK mutants shed light on the mechanisms of acquired resistance. Research culminated in the discovery of a first in patient candidate\, Lorbrena\, which was given Breakthrough Therapy status by the FDA in 2016 and approved in late 2018 for the treatment of patients with refractory ALK positive non-small cell lung cancer (NSCLC). Lorbrena is the first and only ALK tyrosine kinase inhibitor (TKI) approved for use after second-generation ALK TKIs. Recently\, a Phase 3 study of Lorbrena in patients with previously untreated ALK-positive\, advanced NSCLC met its primary endpoint by demonstrating significantly improved progression-free survival\, as compared to Xalkori\, which is currently primary standard of care. The FDA has accepted for Priority Review the supplemental New Drug Application (sNDA) for Lorbrena as a first-line treatment for patients with ALK-positive NSCLC based on the pivotal data from the CROWN study. URL:https://www.chemistry.ucla.edu/seminars/prioritizing-patient-discovery-lorlatinib-macrocyclic-alk-inhibitor-treatment-resistant-and/ CATEGORIES:Organic Colloquium,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210127T160000 DTEND;TZID=America/Los_Angeles:20210127T160000 DTSTAMP:20260615T191820 CREATED:20210106T193712Z LAST-MODIFIED:20210106T193712Z UID:13411-1611763200-1611763200@www.chemistry.ucla.edu SUMMARY:Special Bio-Inorganic Chemistry Seminar DESCRIPTION:“ Exploring Metalloenzymes for Therapeutics and Sustainable Catalysis”  \nAbstract: Metalloenzymes are at the heart of numerous biological processes ranging from respiration and photosynthesis to natural product biosynthesis. Research in the Bhagi-Damodaran lab focuses on investigating structure\, function and reaction mechanisms of metalloenzymes\, and developing rational approaches to modulate their biological activities. Drawing from the core disciplines of biological\, inorganic\, and computational chemistry\, our group utilizes protein engineering and small molecule discovery strategies to address pressing health and energy related challenges. In this seminar\, I will describe our research efforts towards rewiring metalloenzyme-dependent redox signal transduction pathways for next-generation tuberculosis therapeutics. I will also discuss our research efforts towards re-programing non-heme iron enzymes for modular\, versatile\, and sustainable C-H bond halogenation catalysis.   URL:https://www.chemistry.ucla.edu/seminars/special-bio-inorganic-chemistry-seminar-4/ CATEGORIES:Other,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210126T140000 DTEND;TZID=America/Los_Angeles:20210126T140000 DTSTAMP:20260615T191820 CREATED:20210114T233108Z LAST-MODIFIED:20210114T233108Z UID:13420-1611669600-1611669600@www.chemistry.ucla.edu SUMMARY:Theoretical Physical Chemistry Seminar - Dr. Henrik Larsson\, Caltech DESCRIPTION:Molecules in quantum motion \nIn order to fully understand the nature of chemical reactions and molecular properties\, we need to simulate both the electronic and vibrational motion quantum mechanically. However\, simulations of quantum many body systems\, such as molecules\, scale exponentially with system size. I will explain how to tame this ‘curse of dimensionality’ by combining methods from the traditionally disjoint fields of electronic structure and nuclear dynamics. This combination has enabled the simulation of complex systems with unprecedented accuracy and speed. I will demonstrate how these methods make it possible to solve a diverse set of problems\, ranging from characterizing hydrated protons on a molecular quantum level to the interaction of molecules with extreme short and intense light pulses on an attosecond time scale. I will demonstrate how these simulations provide new insight into complex experimental results. URL:https://www.chemistry.ucla.edu/seminars/theoretical-physical-chemistry-seminar-0/ CATEGORIES:Other,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210125T160000 DTEND;TZID=America/Los_Angeles:20210125T160000 DTSTAMP:20260615T191820 CREATED:20210120T182124Z LAST-MODIFIED:20210120T182124Z UID:13433-1611590400-1611590400@www.chemistry.ucla.edu SUMMARY:Chem 228: Clarice D. Aiello DESCRIPTION: URL:https://www.chemistry.ucla.edu/seminars/chem-228-clarice-d-aiello/ CATEGORIES:Physical Chemistry Seminar,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210122T120000 DTEND;TZID=America/Los_Angeles:20210122T120000 DTSTAMP:20260615T191820 CREATED:20210114T194007Z LAST-MODIFIED:20210114T194007Z UID:13419-1611316800-1611316800@www.chemistry.ucla.edu SUMMARY:Theoretical Physical Chemistry Seminar - Dr. Bingqing Cheng\, Cambridge DESCRIPTION:Predicting material properties with the help of machine learning \nA central goal of computational physics and chemistry is to predict material properties using first-principles methods based on the fundamental laws of quantum mechanics. However\, the high computational costs of these methods typically prevent rigorous predictions of macroscopic quantities at finite temperatures\, such as chemical potential\, heat capacity and thermal conductivity. \nIn this talk\, I will first discuss how to enable such predictions by combining advanced statistical mechanics with data-driven machine learning interatomic potentials. As an example\, for the omnipresent and technologically essential system of water\, a first-principles thermodynamic description not only leads to excellent agreement with experiments\, but also reveals the crucial role of nuclear quantum fluctuations in modulating the thermodynamic stabilities of different phases of water. As another example\, we simulated the high-pressure hydrogen system with converged system size and simulation length\, and found\, contrary to established beliefs\, supercritical behaviour of liquid hydrogen above the melting line. Besides thermodynamic properties\, I will talk about how to compute the heat conductivities of liquids just from equilibrium molecular dynamics trajectories. \nDuring the second part of the talk\, I will rationalize why machine learning potentials work at all\, and in particular\, the locality argument. I’ll show that a machine learning potential trained on liquid water alone can predict the properties of diverse ice phases\, because all the local environments characterising the ice phases are found in liquid water. URL:https://www.chemistry.ucla.edu/seminars/theoretical-physical-chemistry-seminar-dr-bingqing-cheng-cambridge/ CATEGORIES:Other,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210121T160000 DTEND;TZID=America/Los_Angeles:20210121T160000 DTSTAMP:20260615T191820 CREATED:20210107T005013Z LAST-MODIFIED:20210107T005013Z UID:13414-1611244800-1611244800@www.chemistry.ucla.edu SUMMARY:Novel GABA- and Ornithine Aminotransferase Inactivators and Potential New Treatments for Epilepsy\, Addiction\, Neuropathic Pain\, and Hepatocellular Carcinoma DESCRIPTION:Abstract: An imbalance in the levels of the inhibitory neurotransmitter g-aminobutyric acid (GABA) and the excitatory neurotransmitter L-glutamate can lead to convulsions. Inhibition of g-aminobutyric acid aminotransferase (GABA-AT)\, the enzyme responsible for the degradation of GABA\, increases brain GABA levels\, which has been shown to produce an anticonvulsant effect. Reduced brain GABA concentration also is a feature of neuropathic pain. A sharp rise in dopamine release is associated with a variety of addictive behaviors. This dopamine release can be attenuated by an increase in GABA; therefore\, inactivation of GABA-AT also has an effect on addictive behavior. Inactivation of a related enzyme\, ornithine aminotransferase (OAT) in hepatocellular carcinoma (HCC) has been shown to slow the growth of this cancer. In this lecture the design and mechanism of some of our GABA-AT inactivators will be discussed and how these compounds led to the design and discovery of CPP-115 and OV329\, potent inactivators of GABA-AT\, which have been found to have excellent pharmacokinetic and pharmacological properties for the potential treatment of epilepsy\, neuropathic pain\, and addiction. An analog related to CPP-115 was identified that does not inactivate GABA-AT but is a potent inactivator of OAT. Enzyme inactivator design and mechanism studies will be discussed\, as well as in vitro and in vivo efficacy and pharmacokinetic results\, toxicology studies\, and a clinical trial with CPP-115. URL:https://www.chemistry.ucla.edu/seminars/novel-gaba-and-ornithine-aminotransferase-inactivators-and-potential-new-treatments/ CATEGORIES:Organic Colloquium,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210120T160000 DTEND;TZID=America/Los_Angeles:20210120T160000 DTSTAMP:20260615T191820 CREATED:20210106T191623Z LAST-MODIFIED:20210106T191623Z UID:13410-1611158400-1611158400@www.chemistry.ucla.edu SUMMARY:Special Bio-Inorganic Chemistry Seminar DESCRIPTION:“Chemical and Biological Design Approaches to Controlling Protons\, Electrons\, and Substrates for Sustainable Catalysis”  \nAbstract: The reductive transformation of small molecules into value-added products represents an attractive way to store sustainable energy in chemical bonds. Achieving this efficiently and selectively requires the careful management of not only the substrate and intermediates\, but also the proton and electron equivalents. Both the synthesis of small molecule catalysts and the de novodesign of metalloproteins offer the means to control these multi-component reactions. A commonly observed strategy in biological systems to lower the barrier to reductive protonation of small molecules is concerted proton-electron transfer (CPET). However\, the application of such a strategy to chemical catalysis has been lacking due to the paucity of approaches to generate CPET donors sufficiently reactive to functionalize molecules of interest ranging from N2 to ketones. Here\, I will discuss our discovery that under the protic conditions relevant to nitrogen fixation catalysis that metallocenes can serve as CPET reagents and our subsequent design of functionalized cobaltocenes suitable to electrocatalytic CPET applications. I will then finish by touching on the computational\, de novo design of non-heme iron proteins for O2-activation. These enzymes utilize a co-substrate to selectively generate a reactive metal-oxo intermediate that is useful for both C–H and olefin functionalization reactions. Nonetheless\, such enzymes have been thus far little explored in the context of protein engineering. URL:https://www.chemistry.ucla.edu/seminars/special-bio-inorganic-chemistry-seminar-3/ CATEGORIES:Other,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210119T130000 DTEND;TZID=America/Los_Angeles:20210119T130000 DTSTAMP:20260615T191820 CREATED:20210113T180558Z LAST-MODIFIED:20210113T180558Z UID:13417-1611061200-1611061200@www.chemistry.ucla.edu SUMMARY:NSF Center for Integrated Catalysis Webinar Series DESCRIPTION:The NSF Center for Integrated Catalysis is delighted to announce that it will be hosting a monthly webinar series. The next webinar of this series will be held on Tuesday\, January 19th\, 2021 at 1:00 PM.  We are pleased to invite all students\, postdocs\, faculty\, and staff. URL:https://www.chemistry.ucla.edu/seminars/nsf-center-integrated-catalysis-webinar-series-3/ CATEGORIES:Other,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210115T153000 DTEND;TZID=America/Los_Angeles:20210115T153000 DTSTAMP:20260615T191820 CREATED:20210104T171944Z LAST-MODIFIED:20210104T171944Z UID:13398-1610724600-1610724600@www.chemistry.ucla.edu SUMMARY:Chem 268: Prof. Elizabeth Villa DESCRIPTION:“Opening Windows into the Cell: Bringing Structure to Cell Biology Using Cryo-electron Tomography” URL:https://www.chemistry.ucla.edu/seminars/chem-268-prof-elizabeth-villa/ CATEGORIES:Biochemistry,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210114T120000 DTEND;TZID=America/Los_Angeles:20210114T120000 DTSTAMP:20260615T191820 CREATED:20210107T001313Z LAST-MODIFIED:20210107T001313Z UID:13413-1610625600-1610625600@www.chemistry.ucla.edu SUMMARY:Expanding the genetic code - new chemistries in living system DESCRIPTION:Abstract: Nature uses a limited set of twenty amino acids to synthesize proteins. In recent years it has become possible to site-specifically incorporate designer amino acids with tailored chemical properties into proteins in living cells by reprogramming the genetic code. Together with developments in designing chemical reactions that are applicable to and selective within living systems\, these strategies have begun to have a direct impact on studying biological processes. \nIn this talk I will present our lab’s efforts to expand the genetic code and to endow proteins with novel chemical moieties within their physiological environment. By site-specifically incorporating artificial designer amino acids into proteins\, we have developed tools to image and probe proteins\, to study protein-protein interactions and to re-engineer and manipulate molecular networks and biological pathways in living cells. \nWe envision that these approaches and technologies will enable the study of biological processes that are difficult or impossible to address by more classical methods. URL:https://www.chemistry.ucla.edu/seminars/expanding-genetic-code-new-chemistries-living-system/ CATEGORIES:Organic Colloquium,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210113T160000 DTEND;TZID=America/Los_Angeles:20210113T160000 DTSTAMP:20260615T191820 CREATED:20210105T015855Z LAST-MODIFIED:20210105T015855Z UID:13409-1610553600-1610553600@www.chemistry.ucla.edu SUMMARY:Special Bio-Inorganic Chemistry Seminar DESCRIPTION:“Tuning the Reactivity Landscape of Metalloenzymes: From Active Site Modifications to Long-range Dynamic Effects” \nAbstract: Metalloenzymes rely on transition metals within the protein scaffold to perform a wide variety of molecular transformations in biology. Synthetic models of metalloenzyme intermediates\, inspired by the enzyme active site and its secondary coordination sphere\, have provided systems for studying bond-forming/breaking events in well-controlled environments. However\, recent evidence has suggested that the dynamic nature of proteins is intimately linked to enzyme function and activity\, implying a reactivity landscape that is not only dependent on the ground state thermodynamics of the active site\, but also on the long-range protein motions that orient the active site for optimum catalysis. The first part of this presentation will focus on the synthesis and reactivity of high-valent metal-oxo and metal-hydroxo corroles and corrolazines as models for reactive intermediates in Cytochrome P450. The role of electronic structure\, peripheral ligand sterics\, and Lewis acid effects on oxygen atom transfer and hydroxyl radical rebound reactivities were evaluated in the context of how the active site microenvironment tunes the reactivity of heme enzymes. The second part of the presentation will focus on our current efforts on characterizing activity-related protein motions in the non-heme enzyme soybean lipoxygenase (SLO-1). SLO-1 utilizes a well-defined hydrogen tunneling mechanism that is intrinsically dependent on the motions of the protein scaffold. Collectively\, the findings from these research efforts have led to several fundamental insights regarding how reactivity is tuned from the active site and beyond\, providing a possible blueprint for the design of efficient catalysts for biological and industrial applications. URL:https://www.chemistry.ucla.edu/seminars/special-bio-inorganic-chemistry-seminar-1/ CATEGORIES:Other,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20210111T160000 DTEND;TZID=America/Los_Angeles:20210111T160000 DTSTAMP:20260615T191820 CREATED:20210104T180919Z LAST-MODIFIED:20210104T180919Z UID:13406-1610380800-1610380800@www.chemistry.ucla.edu SUMMARY:Chem 228: Michelle Y. Simmons\, Ph.D. DESCRIPTION:“Engineering qubits in silicon with atomic precision” URL:https://www.chemistry.ucla.edu/seminars/chem-228-michelle-y-simmons-phd/ CATEGORIES:Physical Chemistry Seminar,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201215T130000 DTEND;TZID=America/Los_Angeles:20201215T130000 DTSTAMP:20260615T191820 CREATED:20201203T171431Z LAST-MODIFIED:20201203T171431Z UID:13397-1608037200-1608037200@www.chemistry.ucla.edu SUMMARY:NSF Center for Integrated Catalysis Webinar Series DESCRIPTION:The NSF Center for Integrated Catalysis is delighted to announce that it will be hosting a monthly webinar series. The Fourth day of this series will be held on Tuesday\, December 15th at 1:00 PM.  We are pleased to invite all students\, postdocs\, faculty\, and staff. URL:https://www.chemistry.ucla.edu/seminars/nsf-center-integrated-catalysis-webinar-series-2/ CATEGORIES:Other,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201210T160000 DTEND;TZID=America/Los_Angeles:20201210T160000 DTSTAMP:20260615T191820 CREATED:20201116T215657Z LAST-MODIFIED:20201116T215657Z UID:13392-1607616000-1607616000@www.chemistry.ucla.edu SUMMARY:Harnessing Conformational Dynamics to Engineer New Enzymes: Prof. Lynn Kamerlin\, Uppsala University DESCRIPTION:Harnessing Conformational Dynamics to Engineer New Enzymes\nUnderstanding how new enzyme functions evolve\, either on existing scaffolds\, or completely de novo on previously non-catalytic scaffolds\, is of great interest both from a fundamental biochemistry perspective\, and from a biotechnological perspective. Several hypotheses have been put forward to rationalize enzyme evolution\, one of which is that their conformational dynamics plays an important role in facilitating the emergence of new enzyme functions.[1-3] My team and I have invested substantial research effort into understanding enzyme multifunctionality in catalytically promiscuous enzymes\,[4-7] as well as the structure-function-dynamics relationships shaping the evolution of new enzyme functions\, in both natural and engineered active sites.[8-12] In this talk\, I will discuss recent progress in this area\, and illustrate how we have engineered conformational dynamics to generate a a de novo active site capable of catalyzing a non-natural reaction\,[9] and then subsequently enhanced this activity using a simple computational approach\, reaching catalytic efficiency comparable to that of naturally occurring enzymes.[13] \n[1] James & Tawfik\, Trends Biochem. Sci.\, 2003\, 28\, 361. [2] Tokuriki & Tawfik\, Science\, 2009\, 324\, 203. [3] Crean et al.\, J. Am. Chem. Soc.\, 2020\, 142\, 11324. [4] Barrozo et al.\, J. Am. Chem. Soc.\, 2015\, 137\, 9061. [5] Ben-David et al.\, J. Mol. Biol.\, 2015\, 427\, 1359. [6] Blaha-Nelson et al.\, J. Am. Chem. Soc.\, 2017\, 139\, 1155. [7] Purg et al.\, J. Am. Chem. Soc.\, 2017\, 139\, 17533. [8] Ma et al.\, Chem. Sci.\, 2016\, 7\, 1415. [9] Risso et al.\, Nat. Commun.\, 2017\, 8\, 16113. [10] Petrović et al.\, ACS Catal.\, 2017\, 6\, 6188. [11] Baier et al.\, eLife\, 2019\, 8\, e40789. [12] Kaltenbach et al.\, Nat. Chem. Biol.\, 2018\, 14\, 548. [13] Risso et al.\, Chem. Sci. 2020\, 11\, 6134. URL:https://www.chemistry.ucla.edu/seminars/harnessing-conformational-dynamics-engineer-new-enzymes-prof-lynn-kamerlin-uppsala/ CATEGORIES:Other,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201210T120000 DTEND;TZID=America/Los_Angeles:20201210T120000 DTSTAMP:20260615T191820 CREATED:20201117T190317Z LAST-MODIFIED:20201117T190317Z UID:13394-1607601600-1607601600@www.chemistry.ucla.edu SUMMARY:Chem 218 Student Exit Seminar: Victoria Basile DESCRIPTION:“Nanostructured Nickel-Rich Cathode Materials for High-Capacity and Fast-Charging Lithium-Ion Batteries” \nABSTRACT: Fast-charging lithium-ion batteries are desired for use in personal electronics and electric vehicles\, potentially allowing systems to charge devices in minutes rather than hours. Fast-charging can be achieved by nanostructuring battery materials\, which decreases lithium-ion diffusion lengths and can suppress slow\, rate-limiting phase transitions. This method of nanostructuring battery materials to enhance fast-charging performance has been shown in many anode materials. However\, lithium-ion batteries are usually limited by the capacity of their cathodes (< 200 mAh/g). Unfortunately\, fewer fast-charging cathode materials have been identified\, and those that have been suffer from capacity loss upon nanostructuring. Here\, we studied the nickel-rich cathode material LiNi0.80Co0.15Al0.05O2 (NCA)\, which has high-capacity and shows solid-solution behavior without a phase transitions in bulk materials. Because phase transitions do not limit intercalation kinetics in bulk NCA\, materials only need to be nanostructured to decrease lithium-ion diffusion lengths to the point that solid-state diffusion is not rate limiting. Here we demonstrated the use of polymer templating\, combined with sol-gel synthesis\, to produce nanoporous NCA with medium and small particle sizes. We can then study the effect of size on the material’s electrochemical properties. Interestingly\, we found that NCA materials with medium particle sizes perform best at fast rates. Their performance is better than that of bulk materials because of their decreased lithium-ion diffusion lengths\, which allows for fast-charging. NCA materials with medium sized particles also out-perform materials with small particles\, however\, and this is because nickel-rich materials are highly air-sensitive\, and the smaller particles have higher surface areas\, leading to more undesirable reactions with air that produce insulating surface layers that can hinder lithium-ion diffusion at fast rates. These results indicate that the smallest particle sizes are not always optimal and that a balance exists between lithium-ion diffusion distances and surface reactivity for nickel-rich cathode materials. URL:https://www.chemistry.ucla.edu/seminars/chem-218-student-exit-seminar-victoria-basile/ CATEGORIES:Other,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201209T163000 DTEND;TZID=America/Los_Angeles:20201209T163000 DTSTAMP:20260615T191820 CREATED:20201007T183210Z LAST-MODIFIED:20201007T183210Z UID:13383-1607531400-1607531400@www.chemistry.ucla.edu SUMMARY:Chem 278: Prof. Michael T. Yeung DESCRIPTION:“Metallic and Covalent Bonding in Materials: Role in Properties\, Structure\, and Stability” \n Abstract: The search for new ultraincompressible\, superhard materials has been performed largely through trial and error. Despite the difficulties in synthesizing such materials\, interest in this field has blossomed with recent experimental and theoretical results. Such progress has led to the development of superhard metal borides\, ultraincompressible nitrides\, and strong carbides. By studying the origin of strength from previously discovered ultraincompressible\, hard materials\, we hope to gain new insight into this rapidly growing field. In particular\, we propose a focus on bonding and microstructure to understand why some materials are ultraincompressible and superhard. URL:https://www.chemistry.ucla.edu/seminars/chem-278-prof-michael-t-yeung/ CATEGORIES:Inorganic Chemistry,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201208T160000 DTEND;TZID=America/Los_Angeles:20201208T160000 DTSTAMP:20260615T191820 CREATED:20200922T223648Z LAST-MODIFIED:20200922T223648Z UID:13365-1607443200-1607443200@www.chemistry.ucla.edu SUMMARY:Midstream Presentation: Keaton Barr DESCRIPTION:Keaton Barr \nChanfreau Group \n“Transcriptional Roadblocks Protect Against Pervasive Transcription\, and the Regulation of a Manganese Transporter via the Endoribonuclease Rnt1p” URL:https://www.chemistry.ucla.edu/seminars/midstream-presentation-keaton-barr/ CATEGORIES:Biochemistry,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201207T160000 DTEND;TZID=America/Los_Angeles:20201207T160000 DTSTAMP:20260615T191820 CREATED:20200922T231202Z LAST-MODIFIED:20200922T231202Z UID:13374-1607356800-1607356800@www.chemistry.ucla.edu SUMMARY:Chem 228: Prof. Theodore Goodson DESCRIPTION: URL:https://www.chemistry.ucla.edu/seminars/chem-228-prof-theodore-goodson/ CATEGORIES:Physical Chemistry Seminar,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201204T153000 DTEND;TZID=America/Los_Angeles:20201204T153000 DTSTAMP:20260615T191820 CREATED:20200922T223440Z LAST-MODIFIED:20200922T223440Z UID:13364-1607095800-1607095800@www.chemistry.ucla.edu SUMMARY:Chem 268: Joe Loo DESCRIPTION: URL:https://www.chemistry.ucla.edu/seminars/chem-268-joe-loo/ CATEGORIES:Biochemistry,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201203T160000 DTEND;TZID=America/Los_Angeles:20201203T160000 DTSTAMP:20260615T191820 CREATED:20201030T163609Z LAST-MODIFIED:20201030T163609Z UID:13388-1607011200-1607011200@www.chemistry.ucla.edu SUMMARY:Lessons from molecular evolution: from origin of life to phage-based nanomaterials DESCRIPTION:Abstract: \nMolecular evolution is a walk over a fitness landscape\, in which populations explore sequence space through mutation and ‘climb’ up fitness peaks. The topography of the fitness landscape governs potential pathways for evolution and determines whether fitness can be optimized by natural selection. We are making exhaustive maps of fitness landscapes for catalytic RNA (ribozymes) by combining in vitro selection with a massively parallel kinetic assay using high-throughput sequencing. In addition\, we take advantage of the ongoing natural selection of phages in order to engineer phage-based nanomaterials for detection and killing of pathogenic bacteria. These nanomaterials combine evolutionarily optimized attachment strategies of phages with the controllable nature of nanomaterials to circumvent some obstacles to phage therapy. URL:https://www.chemistry.ucla.edu/seminars/lessons-molecular-evolution-origin-life-phage-based-nanomaterials/ CATEGORIES:Organic Colloquium,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201203T120000 DTEND;TZID=America/Los_Angeles:20201203T120000 DTSTAMP:20260615T191820 CREATED:20201124T234330Z LAST-MODIFIED:20201124T234330Z UID:13396-1606996800-1606996800@www.chemistry.ucla.edu SUMMARY:Chem 218: First Principles Many-Body Theory and Quantum Dynamics for Materials Prediction - Prof. Yuan Ping\, UCSC DESCRIPTION:First Principles Many-Body Theory and Quantum Dynamics for Materials Prediction  \nMaterials prediction is the ultimate solution for ending blind experimental search within an expansive material parameter space. First-principles theory entirely based on quantum mechanics without prior input parameters is the perfect tool for new material design. In order to predict exotic quantum materials and out-of-equilibrium processes\, many-body physics and quantum kinetic theory are needed to bridge with first-principles methods. \nIn this talk\, I will discuss the past development on theory and numerical codes of solving the Bethe-Salpeter equation without explicit empty states\, for accurate prediction of optical excitation and exciton recombination. I will show the recent developments on radiative and phonon-assisted nonradiative exciton recombination in two-dimensional materials and spin defects.  Next\, I will show our recent method development on real-time quantum dynamics with coupled spins\, electrons\, photons and phonons based on first-principles density-matrix approach. This method will offer new and unbiased insights for spin relaxation and decoherence in general systems\,  and determine design rules for new quantum materials with ideal physical properties for spintronics and quantum information science. URL:https://www.chemistry.ucla.edu/seminars/chem-218-first-principles-many-body-theory-and-quantum-dynamics-materials-prediction-prof/ CATEGORIES:Other,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201202T163000 DTEND;TZID=America/Los_Angeles:20201202T163000 DTSTAMP:20260615T191820 CREATED:20201117T184718Z LAST-MODIFIED:20201117T184718Z UID:13393-1606926600-1606926600@www.chemistry.ucla.edu SUMMARY:Chem 278: Dr. Evan Doud DESCRIPTION:“Beyond Traditional Superatom Ligands and Cores” \n Abstract: As technological development continues to advance at a rapid pace\, there is an increasing need for next-generation materials. There are several fundamental challenges associated with developing these novel materials\, including understanding the nature of the electronic contacts and tuning the specific properties of a material. In the context of novel ligands and core compositions of superatoms\, this talk will first describe how Near Edge X-ray Absorption Fine Structure (NEXAFS) and X-ray Photoelectron Spectroscopy (XPS) coupled with Density Functional Theory (DFT) calculations were used to determine the geometry and structure of N-heterocyclic carbenes (NHCs) on a Au(111) surface. Followed by a demonstration of how a novel in situ reduction technique was used to probe the conductance of NHCs on the single molecule level using the Scanning Tunneling Microscopy – Break Junction (STM-BJ) technique. Finally\, the synthesis of nickel phosphinidene superatoms from the uncommon organocyclophosphine precursor will be discussed URL:https://www.chemistry.ucla.edu/seminars/chem-278-dr-evan-doud/ CATEGORIES:Inorganic Chemistry,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201201T160000 DTEND;TZID=America/Los_Angeles:20201201T160000 DTSTAMP:20260615T191820 CREATED:20200922T223303Z LAST-MODIFIED:20200922T223303Z UID:13363-1606838400-1606838400@www.chemistry.ucla.edu SUMMARY:Midstream Presentation: Troy Lucas Lowe DESCRIPTION:Troy Lucas Lowe\nS. Clarke Group \n“Responses of a Protein Arginine Methyltransferase (PRMT7) to Intracellular Stress” URL:https://www.chemistry.ucla.edu/seminars/midstream-presentation-troy-lucas-lowe/ CATEGORIES:Biochemistry,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201130T160000 DTEND;TZID=America/Los_Angeles:20201130T160000 DTSTAMP:20260615T191820 CREATED:20200922T231059Z LAST-MODIFIED:20200922T231059Z UID:13373-1606752000-1606752000@www.chemistry.ucla.edu SUMMARY:Chem 228: Prof. Amber Krummel DESCRIPTION:“Exploiting Molecular Vibrations to Visualize Chemical Structures & Dynamics in Advanced Materials” URL:https://www.chemistry.ucla.edu/seminars/chem-228-prof-amber-krummel/ CATEGORIES:Physical Chemistry Seminar,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201124T160000 DTEND;TZID=America/Los_Angeles:20201124T160000 DTSTAMP:20260615T191820 CREATED:20200922T223101Z LAST-MODIFIED:20200922T223101Z UID:13362-1606233600-1606233600@www.chemistry.ucla.edu SUMMARY:Midstream Presentation: Maria Flores and Logan Scott Richards DESCRIPTION:Maria Flores\nRodriguez Group \n“Investigating the atomic structures of prion-like assemblies formed by CPEB3” \nand \nLogan Scott Richards \nRodriguez Group \n“Structural Characterization of LECT2 Systemic Amyloidosis” URL:https://www.chemistry.ucla.edu/seminars/midstream-presentation-maria-flores-and-logan-scott-richards/ CATEGORIES:Biochemistry,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201123T160000 DTEND;TZID=America/Los_Angeles:20201123T160000 DTSTAMP:20260615T191820 CREATED:20201117T223245Z LAST-MODIFIED:20201117T223245Z UID:13395-1606147200-1606147200@www.chemistry.ucla.edu SUMMARY:Interfacial Chemistry of Colloidal Nanocrystals to Direct Energy Conversion: Prof. Brandi Cossairt\, University of Washington DESCRIPTION:Interfacial Chemistry of Colloidal Nanocrystals to Direct Energy Conversion \nWe are interested in developing colloidal nanocrystals for wide-ranging applications in energy interconversion. Our approach leverages the extraordinary properties of nanoscale systems and applies design principles of molecular inorganic chemistry. This talk will focus on two key research themes. First\, we will explore how interfacial chemistry can be used to control the photophysics and emissive properties of colloidal semiconductor nanocrystals. Second\, we will explore interfacial chemistry concepts to control the inner-sphere reactivity of colloidal electrocatalysts for multi-proton\, multi-electron transformations. Ligand etching\, ligand exchange\, and covalent functionalization will be presented as complementary methods to alter electrocatalytic interfaces by tuning the activity\, selectivity\, and bulk interfacial properties. Ultimately\, we are viewing nanocrystal interfaces as platforms for coordination chemistry that will direct function. URL:https://www.chemistry.ucla.edu/seminars/interfacial-chemistry-colloidal-nanocrystals-direct-energy-conversion-prof-brandi-cossairt/ CATEGORIES:Physical Chemistry Seminar,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201123T160000 DTEND;TZID=America/Los_Angeles:20201123T160000 DTSTAMP:20260615T191820 CREATED:20200922T230951Z LAST-MODIFIED:20200922T230951Z UID:13372-1606147200-1606147200@www.chemistry.ucla.edu SUMMARY:Chem 228: Prof. Brandi Cossairt DESCRIPTION:“Interfacial Chemistry of Colloidal Nanocrystals to Direct Energy Conversion” URL:https://www.chemistry.ucla.edu/seminars/chem-228-prof-brandi-cossairt/ CATEGORIES:Physical Chemistry Seminar,Seminars END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/Los_Angeles:20201120T153000 DTEND;TZID=America/Los_Angeles:20201120T153000 DTSTAMP:20260615T191820 CREATED:20200922T222814Z LAST-MODIFIED:20200922T222814Z UID:13361-1605886200-1605886200@www.chemistry.ucla.edu SUMMARY:Chem 268: Steve Clarke DESCRIPTION: URL:https://www.chemistry.ucla.edu/seminars/chem-268-steve-clarke-1/ CATEGORIES:Biochemistry,Seminars END:VEVENT END:VCALENDAR