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Sometimes Google Scholar points you to resources for which you have to pay to get the full text, but COM students faculty, and staff can get many articles from Google Scholar for Sometimes Google Scholar points you to resources for which you have to pay to get the full text, but COM students faculty, and staff can get many articles from Google Scholar for

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Applications and challenges of rare earth resources in China. In Proceedings of the 2013 3rd International Conference on Information Science, Automation and Material System, ISAM 2013, Guangzhou, China, 13–14 April 2013; pp. 159–162. [Google Scholar]Jordens, A.; Cheng, Y.P.; Waters, K.E. A review of the beneficiation of rare earth element bearing minerals. Miner. Eng. 2013, 41, 97–114. [Google Scholar] [CrossRef]Bhargava, S.K.; Ram, R.; Pownceby, M.; Grocott, S.; Ring, B.; Tardio, J.; Jones, L. A review of acid leaching of uraninite. Hydrometallurgy 2015, 151, 10–24. [Google Scholar] [CrossRef]Jaireth, S.; Hoatson, D.M.; Miezitis, Y. Geological setting and resources of the major rare-earth-element deposits in Australia. Ore Geol. Rev. 2014, 62, 72–128. [Google Scholar] [CrossRef]Clow, G.; Salmon, B.; Lavigne, M.; McDonough, B.; Pelletier, P.; Vallières, D. Technical Report on Expansion Options at the Niobec Mine, Québec, Canada; IAMGOLD Corporation: Toronto, ON, Canada, 2011. [Google Scholar]Bosserman, P.J. Recovery of Cerium; Google Patents: Mountain View, CA, USA, 1995. [Google Scholar]Zou, D.; Chen, J.; Li, D.Q. Separation chemistry and clean technique of cerium(IV): A review. J. Rare Earths 2014, 32, 681–685. [Google Scholar] [CrossRef]Simandl, G.J. Geology and economic sifnificance of current and future rare earth element sources. In Proceedings of the 51st Annual Conference of Metallurgists, Niagara Falls, ON, Canada, 30 September–3 October 2012. [Google Scholar]Mowafy, A.M. Biological leaching of rare earth elements. World J. Microbiol. Biotechnol. 2020, 36, 61. [Google Scholar] [CrossRef]Driscoll, M.O. An Overview of Rare Earth Minerals Supply and Applications. In Materials Science Forum; Trans Tech Publications Ltd.: Zurich, Switzerland, 1991; pp. 409–420. [Google Scholar]Jones, A.P.; Wall, F.; Williams, C.T. Rare Earth Minerals: Chemistry, Origin and Deposits; Springer: London, UK, 1996. [Google Scholar]Zhang, J.; Edwards, C. A Review of Rare Earth Mineral Processing Technology. In Proceedings of the 44th Annual Canadian Mineral Processors Operators Conference, Ottawa, ON, Canada, 19–21 January 2010. [Google Scholar]Chambers, D.B.; Lowe, L.M.; Feasby, D.G. Radiological aspects of naturally occuring radioactive materials (NORM) in the ore processing and production of rare earth element concentrates. In Proceedings of the 51st Annual Conference of Metallurgists, COM, Niagara Falls, ON, Canada, 30 September–3 October 2012. [Google Scholar]Feasby, D.G.; Chambers, D.B.; Lowe, L.M. Assesment and management of radioactivity in rare earth elements production. In Proceedings of the Rare Earth Elements (COM 2013), West Westmount, QC, Canada, 27–31 October 2013. [Google Scholar]Park, B.T. Management of thorium and uranium in mining and processing of rare earth minerals. In Proceedings of the 51st Annual Conference of Metallurgists, Niagara, ON, Canada, 30 September–3 October 2012; pp. 171–184. [Google Scholar]Cheng, J.; Hou, Y.; Che, L. Flotation separation on rare earth minerals and gangues. J. Rare Earths 2007, 25, 62–66. [Google Scholar]Fang, J.; Zhao, D. Separation of rare earth from tails of magnetite separation in Bao Steel’s concentrator. Met. Mine 2003,

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Of digital collectibles. Int J Adv Comp Sci Appl 12(10):50–56 Google Scholar Amihud Y (2002) Illiquidity and stock returns: cross-section and time-series effects. J Financ Mark 5(1):31–56Article Google Scholar Bai J, Perron P (2003) Computation ad analysis of multiple structural change models. J Appl Econ 18(1):1–22. Google Scholar Bazán-Palomino W (2022) Interdependence, contagion and speculative bubbles in cryptocurrency markets. Fin Res Lett 49:103132. Google Scholar Brauneis A, Mestel R, Riordan R, Theissen E (2021) How to measure the liquidity of cryptocurrency markets? J Ban Fin 124:106041. Google Scholar Brock WA, Dechert WD, Scheinkman JA (1987) A Test for independence based on the correlation dimension. Univ Wisc Madison, Univ Houston, and Univ Chicago, Department of Economics Google Scholar Chen K, Luo P, Liu L, Zhang W (2018) News, search and stock co-movement: Investigating information diffusion in the financial market. Elec Com Res Appl 28:159–171. Google Scholar Cho JB, Serneels S, Matteson DS (2023) Non-fungible token transactions: data and challenges. Data Sci Sci 2(1):2151950. Google Scholar Chowdhury MAF, Abdullah M, Alam M, Abedin MZ, Shi B (2023) NFTs, DeFi, and other assets efficiency and volatility dynamics: an asymmetric multifractality analysis. Int Rev Fin Anal 87:102642. Google Scholar Dowling M (2022a) Is non-fungible token pricing driven by cryptocurrencies? Fin Res Lett 44:102097. Google Scholar Dowling M (2022b) Fertile LAND: pricing non-fungible tokens. Fin Res Lett 44:102096. Google Scholar Drake MS, Roulstone DT, Thornock JR (2012) Investor information demand: evidence from Google searches around earnings announcements. J Acc Res 50(4):1001–1040. Google Scholar Enoksen FA,

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Google Scholar Button: A Convenient Tool for Accessing Scholarly ArticlesGoogle Scholar Button is a free browser extension available for Chrome users. Developed by scholar-chrome-admin, this add-on falls under the category of Browsers and is classified as an Add-ons & Tools subcategory.This extension aims to make it easier for users to access scholarly articles while browsing the web. With just a click of a button, users can utilize the various features offered by Google Scholar Button. These features include finding full-text articles on the web or in university libraries, transferring web search queries to Scholar, formatting references in popular citation styles, and saving articles to the Scholar library for later use.Google Scholar Button is particularly useful for students, researchers, and academics who frequently rely on scholarly articles for their work. By seamlessly integrating with the browser, this extension streamlines the process of searching, accessing, and citing scholarly content.Please note that library links work best when users are on campus, but the extension provides instructions on how to configure them for off-campus use. Additionally, for those interested in searching US case law, the extension offers the option to configure preferred collections in Google Scholar Settings.Overall, Google Scholar Button is a valuable tool for anyone in need of quick and easy access to scholarly articles. Its user-friendly interface and range of features make it a must-have for those engaged in academic pursuits.Program available in other languagesScarica Google Scholar Button [IT]تنزيل Google Scholar Button [AR]Download do Google Scholar Button [PT]Google Scholar Button 다운로드 [KO]ダウンロードGoogle Scholar Button [JA]Google Scholar Button indir [TR]Descargar Google Scholar Button [ES]Скачать Google Scholar Button [RU]Tải xuống Google Scholar Button [VI]ดาวน์โหลด Google Scholar Button [TH]Download Google Scholar Button [NL]下载Google Scholar Button [ZH]Pobierz Google Scholar Button [PL]Unduh Google Scholar Button [ID]Télécharger Google Scholar Button [FR]Google Scholar Button herunterladen [DE]Ladda ner Google Scholar Button [SV]Explore MoreLatest articlesLaws concerning the use of this software vary from country to country. We do not encourage or condone the use of this program if it is in violation of these laws.. Sometimes Google Scholar points you to resources for which you have to pay to get the full text, but COM students faculty, and staff can get many articles from Google Scholar for Sometimes Google Scholar points you to resources for which you have to pay to get the full text, but COM students faculty, and staff can get many articles from Google Scholar for

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Quality assessment in narrow-band telephony. International Telecommunication Union, Geneva Google Scholar ITU-T Recommendation P.862 (2001) Perceptual evaluation of speech quality (PESQ), an objective method for end-to-end speech quality assessment of narrow-band telephone networks and speech codecs. International Telecommunication Union, Geneva Google Scholar ITU-T Recommendation P.863 (2011) Perceptual objective listening quality assessment (POLQA). International Telecommunication Union, Geneva Google Scholar Jekosch U (1993) Speech quality assessment and evaluation. In: Proceedings of Eurospeech, Berlin, Germany, pp 1387–1394 Google Scholar Klatt DH (1980) Software for a cascade/parallel formant synthesizer. Journal of the Acoustical Society of America 67(3):971–995 Google Scholar Kraft V, Portele T (1995) Quality evaluation of five German speech synthesis systems. Acta Acustica 3:351–365 Google Scholar Mariniak A (1993) A global framework for the assessment of synthetic speech without subjects. In: Proceedings of the 3rd European conference on speech processing and technology (Eurospeech), Berlin, Germany, pp 1683–1686 Google Scholar Mayo C, Clark RAJ, King S (2005) Listener’s weighting of acoustic cues to synthetic speech naturalness: a multidimensional scaling analysis. In: Proceedings of the 6th annual conference of the international speech communication association (Interspeech), Lisbon, Portugal, pp 1725–1728 Google Scholar Minker W, Lee GG, Mariani J, Nakamura S (2010) Salient features for anger recognition in German and English IVR portals. Spoken dialogue systems technology and design. Springer Google Scholar Möller S, Hinterleitner F (2013) ITU-T Contribution COM 12–37: proposal for an appendix to Rec. P.85 of the evaluation of speech output for audiobook reading tasks. Deutsche Telekom AG, ITU-T SG12 meeting 19–28 Mar 2013, Geneva Google Scholar Möller S, Hinterleitner F, Falk TH, Polzehl T (2010) Comparison of approaches for instrumentally predicting the quality of text-to-speech systems. In: Proceedings of the 11th annual conference of the international speech communication association (Interspeech 2010), Makuhari, Japan, pp 1325–1328 Google Scholar Moulines E, Charpentier N (1990) Pitch-synchronous

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And Game, Fish Bull 169:123–133 Google Scholar Collins JW (1892) Report on the fisheries of the Pacific Coast of the United States. US Fish Com, Rept For 1888:3–269 Google Scholar Crawford K (2002) Culture method for in vitro fertilization to hatching of the squid, Loligo pealeii. Biol Bull 203:216–217Article Google Scholar Cronin E, Seymour R (2000) Respiration of the eggs of the giant cuttlefish Sepia apama. Mar Biol 136:863–870Article Google Scholar DʼAniello A, DʼOnofrio G, Pischetola M, Denucé JM (1987) Effect of the ionic concentration of calcium and potassium on hatching of the embryo of the squid, Loligo vulgaris. A preliminary study. Arch Int Phisiol Biochim 95, B66 Google Scholar DʼAniello A, DʼOnofrio G, Pischetola M, Denucé JM (1989) Effect of pH, salinity and Ca2+, Mg2+, K+ and SO4 2+ ions on hatching and viability of Loligo vulgaris embryo. Comp Biochem Physiol A 94:477–481Article Google Scholar DeRusha RH, Forsythe JW, DiMarco FP, Hanlon RT (1989) Alternative diets for maintaining and rearing cephalopods in captivity. Lab Anim Sci 39:306–312CAS Google Scholar Drillet G, Jørgensen NOG, Sørensen TF, Ramløv H, Hansen BW (2006) Biochemical and technical observations supporting the use of copepods as live feed organisms in marine larviculture. Aquac Res 37:756–772Article CAS Google Scholar Fields WG (1950) A preliminary report on the fishery and on the biology of the squid Loligo opalescens. Calif Dept Fish Game 36:367–377 Google Scholar Fields WG (1965) The structure, development, food relation, reproduction and life history of the squid Loligo opalescens Berry. Dept Fish Game Calif, p 108 Google Scholar Forsythe JW, Van Heukelem WF (1987) Growth. In: Boyle PR (ed) Cephalopod life cycles, Vol II. Academic Press, London, pp 135–156 Google Scholar Franco-Santos RM, Vidal EAG (2014) Beak development of early squid paralarvae (Cephalopoda: Teuthoidea) may reflect an adaptation to a specialized feeding mode. Hydrobiol 725:85–103 Google Scholar Gilly WF, Lucero MT (1992) Behavioral responses to chemical stimulation of the olfactory organ in the squid Loligo opalescens. J Exp Biol 162:209–229CAS Google Scholar Grieb TM, Beeman RD (1978) A study of spermatogenesis in the spawning population of the squid, Loligo opalescens. In: Recksiek CW, Frey

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AbstractThis paper presents a method for computing the motions of a robot in dynamic environments, subject to the robot dynamics and its actuator constraints. This method is based on the concept of Velocity Obstacle, which defines the set of feasible robot velocities that would result in a collision between the robot and an obstacle moving at a given velocity. The avoidance maneuver at a specific time is thus computed by selecting robot’s velocities out of that set. A trajectory consisting of a sequence of avoidance maneuvers at discrete time intervals is generated by a search of a tree of avoidance maneuvers. An exhaustive search com-putes near minimum-time trajectories, whereas a heuristic search generates feasible trajectories for on-line applications. These trajectories are compared to the optimal trajectory computed by a dynamic optimization that minimizes motion time, subject to robot dynamics, its actuator limits and the state inequality constraints due to the moving obstacles. This approach is demonstrated for planning the trajectory of an automated vehicle in an Intelligent Vehicle Highway System scenario. Preview Unable to display preview. Download preview PDF. Similar content being viewed by others ReferencesJ.E. Bobrow, S. Dubowsky, and J.S. Gibson. Time-optimal control of robotic manipulators along specified paths. The International Journal of Robotics Research, 4 (3): 3–17, Fall 1985.Article Google Scholar A.E. Bryson and W.F. Denham. A steepest- ascent method for solving optimum programming problems. ASME Journal of Applied Mechanics, (29): 247–257, June 1962. Google Scholar A.E. Bryson, W.F. Denham, and S.E. Dreyfus. Optimal programming problems with inequality constraints i: Necessary conditions for extremal solutions. AIAA Journal, 1 (11): 2544–2550, November 1963.Article MathSciNet MATH Google Scholar A.E. Bryson and Y.C. Ho. Applied Optimal Control Hemisphere Publishing Corp., New York, NY, 1975. Google Scholar S. Cameron. A study of the clash detection problem in robotics. In IEEE International Conference on Robotics and Automation, pages 488–493, St. Louis, MO, March 25–28 1985. Google Scholar S. Cameron. Efficient intersection tests for objects defined constructively. The International Journal of Robotics Research, 8 (1): 3–25, February 1989.Article Google Scholar S. Cameron. Collision detection by four- dimensional intersection testing. IEEE Journal of Robotics and

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Seismic actions and rules for buildings (Portuguese National Annex). Costa C, Figueiredo R, Silva V, Bazzurro P (2020) Application of open tools and datasets to probabilistic modeling of road traffic disruptions due to earthquake damage. Earthq Eng Struct Dyn. Google Scholar Crowley H, Eeri M, Despotaki V et al (2020) Exposure model for European seismic risk assessment. Earthq Spectr 36:252–273. Google Scholar Crowley H, Dabbeek J, Despotaki V, Rodrigues D, Martins L, Silva V, Romão X, Pereira N, Weatherill G, Danciu L (2021) European seismic risk model (ESRM20). EFEHR Tech Rep. Google Scholar D’Ayala D, Spence R, Oliveira C, Pomonis A (1997) Earthquake loss estimation for Europe’s historic town centres. Earthq Spectr 13:773–793. Google Scholar Danciu L, Nandan S, Reyes C, et al (2021) The 2020 update of the European seismic hazard model-ESHM20: model overviewDaniell JE, Schafer AM, Wenzel F (2017) Influence of secondary hazards in earthquake loss. Frontiers Built Environ. Google Scholar Delavaud E, Cotton F, Akkar S et al (2012) Toward a ground-motion logic tree for probabilistic seismic hazard assessment in Europe. J Seismol 16:451–473. Google Scholar Duarte JC, Schellart WP, Rosas FM (2018) The future of Earth’s oceans: consequences of subduction initiation in the Atlantic and implications for supercontinent formation. Geol Mag 155:45–58. Google Scholar Erdik M (2017) Earthquake risk assessment. Bull Earthq Eng 15:5055–5092. Google Scholar Estêvão JMC, Ferreira MA, Morales-Esteban A, et al (2018) Earthquake resilient schools in Algarve (Portugal) and Huelva (Spain). In: 16th European conference on earthquake engineering (16ECEE)Estevão J (2012) Efeitos da acção sísmica no comportamento de edifícios de betão armado com alvenaria de enchimento. PhD Thesis (in portuguese). Instituto Superior TécnicoFerrão C, Bezzeghoud M, Caldeira B, Borges JF (2016) The seismicity of Portugal and its adjacent Atlantic region from 1300 to 2014: maximum observed intensity (MOI) map. Seismol Res Lett 87:743–750. Google Scholar Fontiela J, Sousa Oliveira C, Rosset P (2018) Characterisation of seismicity of the azores archipelago: an overview of historical events and a detailed analysis for the period 2000–2012. Act Volcano World. Google Scholar Gkatzogias K, Crowley H, Veljkovic A, Pohoryles D A, Norlén H, Tsionis G, Bournas D. Sometimes Google Scholar points you to resources for which you have to pay to get the full text, but COM students faculty, and staff can get many articles from Google Scholar for Sometimes Google Scholar points you to resources for which you have to pay to get the full text, but COM students faculty, and staff can get many articles from Google Scholar for

What is Google Scholar? - Google Scholar - Guides at Gordon

Process for Separating Thorium Compounds from Monazite Sands; Iowa State University: Ames, IA, USA, 1953. [Google Scholar]Amer, T.E.; Abdella, W.M.; Wahab, G.M.A.; El-Sheikh, E.M. A suggested alternative procedure for processing of monazite mineral concentrate. Int. J. Miner. Process. 2013, 125, 106–111. [Google Scholar] [CrossRef]Chi, R.; Xu, Z. A solution chemistry approach to the study of rare earth element precipitation by oxalic acid. Met. Mater Trans B 1999, 30, 189–195. [Google Scholar] [CrossRef]Kul, M.; Topkaya, Y.; Karakaya, I. Rare earth double sulfates from pre-concentrated bastnasite. Hydrometallurgy 2008, 93, 129–135. [Google Scholar] [CrossRef]Fourest, B.; Lagarde, G.; Perrone, J.; Brandel, V.; Dacheux, N.; Genet, M. Solubility of thorium phosphate-diphosphate. New J. Chem. 1999, 23, 645–649. [Google Scholar] [CrossRef]Borai, E.H.; Abd El-Ghany, M.S.; Ahmed, I.M.; Hamed, M.M.; Shahr El-Din, A.M.; Aly, H.F. Modi fi ed acidic leaching for selective separation of thorium, phosphate and rare earth concentrates from Egyptian crude monazite. Int. J. Miner. Process. 2016, 149. [Google Scholar] [CrossRef]Krebs, D.G.I.; Furfaro, D. The Kvanefjeld process. In Proceedings of the Alta 2013 Uranium-REE Conference, Perth, Australia, 25 May–1 June 2013. [Google Scholar]Pawlik, C. Recovery of rare earth elements from complex and low grade deposits. In Proceedings of the ALTA 2013 Uranium-REE Conference, Perth, Australia, 25 May–1 June 2013. [Google Scholar]Vijayalakshmi, R.; Mishra, S.L.; Singh, H.; Gupta, C.K. Processing of xenotime concentrate by sulphuric acid digestion and selective thorium precipitation for separation of rare earths. Hydrometallurgy 2001, 61, 75–80. [Google Scholar] [CrossRef]Bearse, A.E.; Calkins, G.D.; Clegg, J.W.; Filbert, J.R.B. Thorium and rare earths from monazite. Chem. Eng. Prog. 1954, 50, 235–239. [Google Scholar]Mackowski, S.J.; Raiter, R.; Soldenhoff, K.H.; Ho, E.M. Recovery of Rare Earth Elements. U.S. Patent 7,993,612 B2, 9 August 2011. [Google Scholar]Yu, B.; Verbaan, N.; Pearse, G.; Britt, S. Beneficiation and extraction of REE from GEOMEGA resources’ Montviel project. In Proceedings of the Rare Earth Elements (COM 2013), West Westmount, QC, Canada, 30 September–3 October 2013. [Google Scholar]Grimaldi, F.S. The analytical chemistry of uranium and thorium. In Proceedings of the United Nations International Conference on Peaceful Uses of Atomic Energy, Geneva, Switzerland, 8 August 1995; pp. 605–617. [Google Scholar]Tomazic, B.; Branica, M. Separation of uranium(VI) from rare earths(III) by hydrolytic precipitation. Inorg. Nucl. Chem. Lett. 1968, 4, 377–380. [Google Scholar] [CrossRef]Kang, M.J.; Han, B.E.; Hahn, P.S. Precipitation and adsorption of uranium (VI) under various aqueous conditions. Environ. Eng. Res. 2002, 7, 149–157. [Google Scholar]Abreu, R.D.; Morais, C.A. Purification of rare earth elements from monazite sulphuric acid leach liquor and the production of high-purity ceric oxide. Miner. Eng. 2010, 23, 536–540. [Google Scholar] [CrossRef]Carter, G.; Everest, D.A.; Wells, R.A. Selective oxalate precipitation of thorium from sulfate leach solutions derived from monazite sands. J. Appl. Chem. 1960, 10, 149–155. [Google Scholar] [CrossRef]Sozanski, A. Separation of

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201, 295 (2009). ADS Google Scholar D. Nesvorný, D. Janches, D. Vokrouhlický, P. Pokorný, W.F. Bottke, P. Jenniskens, Astrophys. J. 743(2), 129 (2011). ADS Google Scholar A.C. Levasseur-Regourd, J. Agarwal, H. Cottin, C. Engrand, G. Flynn, M. Fulle, T. Gombosi, Y. Langevin, J. Lasue, T. Mannel, Space Sci. Rev. 214(3), 64 (2018). ADS Google Scholar V.A. Bronshten, Physics of Meteoric Phenomena (D. Reidel, Dordrecht, 1983)Book Google Scholar L. Jacchia, Astron. J. 60, 165 (1955). Google Scholar F. Verniani, Space Sci. Rev. 10, 230 (1969). ADS Google Scholar R.L. Hawkes, J. Jones, Mon. Not. R. Astron. Soc. 173, 339 (1975). ADS Google Scholar P.B. Babadzhanov, Astron. Astrophys. 384, 317 (2002). ADS Google Scholar Z. Ceplecha, P. Spurny, J. Borovička, J. Keclikova, Astron. Astrophys. 279, 615 (1993)ADS Google Scholar Z. Ceplecha, Smithsonian Contributions Astrophys. 11, 35 (1967)ADS Google Scholar F. Verniani, Smithsonian Contributions Astrophys. 11, 61 (1967)ADS Google Scholar R. Weryk, Simultaneous radar and video meteors. Ph.D. Thesis, The University of Western Ontario (2012) Google Scholar L.A. Rogers, K.A. Hill, R.L. Hawkes, Planet. Space Sci. 53(13), 1341 (2005). ADS Google Scholar F.L. Whipple, Proc. Am. Philos. Soc. 79, 499 (1938) Google Scholar B.J. Levin, Bull. Astron. Inst. Czechoslovakia 7, 58 (1956)ADS Google Scholar I. Halliday, Publ. Dominion Obs. Ottawa 25, 3 (1961) Google Scholar Z. Ceplecha, Bull. Astron. Inst. Czechoslovakia 22, 219 (1971)ADS Google Scholar J. Borovička, Astron. Astrophys. 103, 83 (1994)ADS Google Scholar J. Borovička, Planet. Space Sci. 42, 145 (1994). ADS Google Scholar A.F. Cook, C.L. Hemenway, P.M. Millman, A. Swider, NASA Spec. Publ. 319, 153 (1973)ADS Google Scholar J. Borovička, J. Boček, Earth Moon Planet. 71, 237 (1995). ADS Google Scholar J.J. Papike, Planetary Materials, vol. 36 (Mineralogical Society of America, Chantilly, 1998) Google Scholar D. Brownlee, D. Joswiak, G. Matrajt, Meteorit. Planet. Sci. 47(4), 453 (2012). ADS Google Scholar Y. Langevin, M. Hilchenbach, N. Ligier, S. Merouane, K. Hornung, C. Engrand, R. Schulz, J. Kissel, J. Rynö, P. Eng, Icarus 271, 76 (2016). ADS Google Scholar D. Ozdín, J. Plavčan, M. Horåáčková, P. Uher, V. Porubčan, P. Veis, J. Rakovský, J. Tóth, P. Konečný, J. Svoreå, Meteorit. Planet. Sci. 50, 864 (2015). ADS Google Scholar S. Messenger, L.P. Keller, F.J. Stadermann, R.M. Walker, E. Zinner, Science 300(5616), 105 (2003). ADS Google Scholar T. Noguchi, N. Ohashi, S. Tsujimoto, T. Mitsunari, J.P. Bradley, T. Nakamura, S. Toh, T. Stephan, N. Iwata, N. Imae, Earth Planet. Sci. Lett. 410, 1 (2015). ADS Google Scholar V. Vojáček, J. Borovička, P. Koten, P. Spurný, R. Štork, Astron. Astrophys. 580, A67 (2015). ADS Google Scholar R. Rudawska, J. Tóth, D. Kalmančok, P. Zigo, P. Matlovič, Planet. Space Sci. 123, 25 (2016). ADS Google Scholar P. Matlovič, J. Tóth, R. Rudawska, L. Kornoš, A.. Sometimes Google Scholar points you to resources for which you have to pay to get the full text, but COM students faculty, and staff can get many articles from Google Scholar for

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Lensink MF, Orengo CA, Wodak SJ (2008) Nucleic Acids Res 36:D667CAS PubMed Google Scholar Dhakal A, McKay C, Tanner JJ, Cheng J (2022) Brief Bioinform 23:bbab476PubMed Google Scholar Meng EC, Shoichet BK, Kuntz ID (1992) J Comput Chem 13:505CAS Google Scholar Makino S, Kuntz ID (1997) J Comput Chem 18:1812CAS Google Scholar Goodsell DS, Morris GM, Olson AJ (1996) J Mol Recognit 9:1CAS PubMed Google Scholar Muegge I, Martin YC (1999) J Med Chem 42:791CAS PubMed Google Scholar Gohlke H, Hendlich M, Klebe G (2000) J Mol Biol 295:337CAS PubMed Google Scholar DeWitte RS, Shakhnovich EI (1996) J Am Chem Soc 118:11733CAS Google Scholar Huang S-Y, Zou X (2006) J Comput Chem 27:1876CAS PubMed Google Scholar Zheng Z, Merz KM (2013) J Chem Inf Model 53:1073CAS PubMed PubMed Central Google Scholar Trott O, Olson AJ (2010) J Comput Chem 31:455CAS PubMed PubMed Central Google Scholar Yang C, Zhang Y (2021) J Chem Inf Model 61:4630CAS PubMed PubMed Central Google Scholar Rarey M, Kramer B, Lengauer T, Klebe G (1996) J Mol Biol 261:470CAS PubMed Google Scholar Wang R, Liu L, Lai L, Tang Y (1998) J Mol Model 4:379CAS Google Scholar Rognan D, Lauemoller SL, Holm A, Buus S, Tschinke V (1999) J Med Chem 42:4650CAS PubMed Google Scholar Wang R, Lai L, Wang S (2002) J Comput Aided Mol Des 16:11CAS PubMed Google Scholar Stanzione F, Giangreco I, Cole JC (2021) Prog Med Chem 60:273PubMed Google Scholar Kroemer RT, Vulpetti A, McDonald JJ, Rohrer DC, Trosset JY, Giordanetto F, Cotesta S, McMartin C, Kihlén M, Stouten PF (2004) J Chem Inf Comput Sci 44:871CAS PubMed Google Scholar Plewczynski D, Łaźniewski M, Augustyniak R, Ginalski K (2011) J Comput Chem 32:742CAS PubMed Google Scholar Onodera K, Satou K, Hirota H (2007) J Chem Inf Model 47:1609CAS PubMed Google Scholar Perola E, Walters WP, Charifson PS (2004) Proteins 56:235CAS PubMed Google Scholar Seeliger D, de Groot BL (2010) J Comput Aided Mol Des 24:417CAS PubMed PubMed Central Google Scholar Humphrey W, Dalke A, Schulten K (1996) J Mol Graph 14:33CAS PubMed Google Scholar Li Y, Su M, Liu Z, Li J,