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Magnetic resonance imaging. Basic principles.

Minnesota medicine

Cramer H, Rust RJ.
PMID: 3951419
Minn Med. 1986 Jan;69(1):31-2.

No abstract available.

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Cramer H, Rust RJ. Magnetic resonance imaging. Basic principles. Minn Med. 1986;69(1):31-2
Cramer, H., & Rust, R. J. (1986). Magnetic resonance imaging. Basic principles. Minnesota medicine, 69(1), 31-2.
Cramer, H, and Rust, R J. "Magnetic resonance imaging. Basic principles." Minnesota medicine vol. 69,1 (1986): 31-2.
Cramer H, Rust RJ. Magnetic resonance imaging. Basic principles. Minn Med. 1986 Jan;69(1):31-2. PMID: 3951419.
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Experimental and computational study of a new wheel-shaped {[W5O21]3[(U(VI)O))2(μ-O2)]3}30- polyoxometalate.

Inorganic chemistry

Miró P, Ling J, Qiu J, Burns PC, Gagliardi L, Cramer CJ.
PMID: 22857707
Inorg Chem. 2012 Aug 20;51(16):8784-90. doi: 10.1021/ic3005536. Epub 2012 Aug 02.

A new wheel-shaped polyoxometalate {[W(5)O(21)](3)[(U(VI)O(2))(2)(μ-O(2))](3)}(30-) has been synthesized and structurally characterized. The calculated electrostatic potential reveals the protonation of several μ-oxo bridges reducing the polyoxometalate total charge. A protonated structure computed at the density functional level of theory (DFT)...

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Miró P, Ling J, Qiu J, et al. Experimental and computational study of a new wheel-shaped {[W5O21]3[(U(VI)O))2(μ-O2)]3}30- polyoxometalate. Inorg Chem. 2012;51(16):8784-90doi: 10.1021/ic3005536.
Miró, P., Ling, J., Qiu, J., Burns, P. C., Gagliardi, L., & Cramer, C. J. (2012). Experimental and computational study of a new wheel-shaped {[W5O21]3[(U(VI)O))2(μ-O2)]3}30- polyoxometalate. Inorganic chemistry, 51(16), 8784-90. https://doi.org/10.1021/ic3005536
Miró, Pere, et al. "Experimental and computational study of a new wheel-shaped {[W5O21]3[(U(VI)O))2(μ-O2)]3}30- polyoxometalate." Inorganic chemistry vol. 51,16 (2012): 8784-90. doi: https://doi.org/10.1021/ic3005536
Miró P, Ling J, Qiu J, Burns PC, Gagliardi L, Cramer CJ. Experimental and computational study of a new wheel-shaped {[W5O21]3[(U(VI)O))2(μ-O2)]3}30- polyoxometalate. Inorg Chem. 2012 Aug 20;51(16):8784-90. doi: 10.1021/ic3005536. Epub 2012 Aug 02. PMID: 22857707.
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Influence of CH···N Interaction in the Self-Assembly of an Oligo(isoquinolyne-ethynylyne) Molecule with Distinct Conformational States.

Langmuir : the ACS journal of surfaces and colloids

Nuermaimaiti A, Ning Y, Cramer JL, Svane KL, Hammer B, Gothelf KV, Linderoth TR.
PMID: 28968110
Langmuir. 2017 Oct 17;33(41):10782-10791. doi: 10.1021/acs.langmuir.7b02207. Epub 2017 Oct 02.

Molecular conformational flexibility can play an important role in supramolecular self-assembly on surfaces, affecting not least chiral molecular assemblies. To explicitly and systematically investigate the role of molecular conformational flexibility in surface self-assembly, we synthesized a three-bit conformational switch...

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Nuermaimaiti A, Ning Y, Cramer JL, et al. Influence of CH···N Interaction in the Self-Assembly of an Oligo(isoquinolyne-ethynylyne) Molecule with Distinct Conformational States. Langmuir. 2017;33(41):10782-10791doi: 10.1021/acs.langmuir.7b02207.
Nuermaimaiti, A., Ning, Y., Cramer, J. L., Svane, K. L., Hammer, B., Gothelf, K. V., & Linderoth, T. R. (2017). Influence of CH···N Interaction in the Self-Assembly of an Oligo(isoquinolyne-ethynylyne) Molecule with Distinct Conformational States. Langmuir : the ACS journal of surfaces and colloids, 33(41), 10782-10791. https://doi.org/10.1021/acs.langmuir.7b02207
Nuermaimaiti, Ajiguli, et al. "Influence of CH···N Interaction in the Self-Assembly of an Oligo(isoquinolyne-ethynylyne) Molecule with Distinct Conformational States." Langmuir : the ACS journal of surfaces and colloids vol. 33,41 (2017): 10782-10791. doi: https://doi.org/10.1021/acs.langmuir.7b02207
Nuermaimaiti A, Ning Y, Cramer JL, Svane KL, Hammer B, Gothelf KV, Linderoth TR. Influence of CH···N Interaction in the Self-Assembly of an Oligo(isoquinolyne-ethynylyne) Molecule with Distinct Conformational States. Langmuir. 2017 Oct 17;33(41):10782-10791. doi: 10.1021/acs.langmuir.7b02207. Epub 2017 Oct 02. PMID: 28968110.
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Length Scale of the Spin Seebeck Effect.

Physical review letters

Kehlberger A, Ritzmann U, Hinzke D, Guo EJ, Cramer J, Jakob G, Onbasli MC, Kim DH, Ross CA, Jungfleisch MB, Hillebrands B, Nowak U, Kläui M.
PMID: 26371671
Phys Rev Lett. 2015 Aug 28;115(9):096602. doi: 10.1103/PhysRevLett.115.096602. Epub 2015 Aug 28.

We investigate the origin of the spin Seebeck effect in yttrium iron garnet (YIG) samples for film thicknesses from 20 nm to 50  μm at room temperature and 50 K. Our results reveal a characteristic increase of the longitudinal...

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Kehlberger A, Ritzmann U, Hinzke D, et al. Length Scale of the Spin Seebeck Effect. Phys Rev Lett. 2015;115(9):096602doi: 10.1103/PhysRevLett.115.096602.
Kehlberger, A., Ritzmann, U., Hinzke, D., Guo, E. J., Cramer, J., Jakob, G., Onbasli, M. C., Kim, D. H., Ross, C. A., Jungfleisch, M. B., Hillebrands, B., Nowak, U., & Kläui, M. (2015). Length Scale of the Spin Seebeck Effect. Physical review letters, 115(9), 096602. https://doi.org/10.1103/PhysRevLett.115.096602
Kehlberger, Andreas, et al. "Length Scale of the Spin Seebeck Effect." Physical review letters vol. 115,9 (2015): 096602. doi: https://doi.org/10.1103/PhysRevLett.115.096602
Kehlberger A, Ritzmann U, Hinzke D, Guo EJ, Cramer J, Jakob G, Onbasli MC, Kim DH, Ross CA, Jungfleisch MB, Hillebrands B, Nowak U, Kläui M. Length Scale of the Spin Seebeck Effect. Phys Rev Lett. 2015 Aug 28;115(9):096602. doi: 10.1103/PhysRevLett.115.096602. Epub 2015 Aug 28. PMID: 26371671.
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An Internship May Not Be Enough: Enhancing Bioscience Industry Job Readiness through Practicum Experiences.

Journal of microbiology & biology education

Cramer JM, Hamilton PT.
PMID: 28512519
J Microbiol Biol Educ. 2017 Apr 21;18(1). doi: 10.1128/jmbe.v18i1.1248. eCollection 2017 Apr.

In contrast to the narrowing of options in academic careers, the bioscience industry offers robust employment opportunities for STEM-trained workers, especially those who display both scientific and business talent. Unfortunately, traditional science programs typically lack curricular features that develop...

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Cramer JM, Hamilton PT. An Internship May Not Be Enough: Enhancing Bioscience Industry Job Readiness through Practicum Experiences. J Microbiol Biol Educ. 2017;18(1)doi: 10.1128/jmbe.v18i1.1248.
Cramer, J. M., & Hamilton, P. T. (2017). An Internship May Not Be Enough: Enhancing Bioscience Industry Job Readiness through Practicum Experiences. Journal of microbiology & biology education, 18(1), . https://doi.org/10.1128/jmbe.v18i1.1248
Cramer, Jason M, and Hamilton, Paul T. "An Internship May Not Be Enough: Enhancing Bioscience Industry Job Readiness through Practicum Experiences." Journal of microbiology & biology education vol. 18,1 (2017). doi: https://doi.org/10.1128/jmbe.v18i1.1248
Cramer JM, Hamilton PT. An Internship May Not Be Enough: Enhancing Bioscience Industry Job Readiness through Practicum Experiences. J Microbiol Biol Educ. 2017 Apr 21;18(1). doi: 10.1128/jmbe.v18i1.1248. eCollection 2017 Apr. PMID: 28512519; PMCID: PMC5524464.
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The 4.

Chimia

Winter-Werner B, Heinis C, Cramer N.
PMID: 28978371
Chimia (Aarau). 2011 Oct 26;65(10):818-820. doi: 10.2533/chimia.2011.818.

No abstract available.

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Winter-Werner B, Heinis C, Cramer N. The 4. Chimia (Aarau). 2011;65(10):818-820doi: 10.2533/chimia.2011.818.
Winter-Werner, B., Heinis, C., & Cramer, N. (2011). The 4. Chimia, 65(10), 818-820. https://doi.org/10.2533/chimia.2011.818
Winter-Werner, Barbara, et al. "The 4." Chimia vol. 65,10 (2011): 818-820. doi: https://doi.org/10.2533/chimia.2011.818
Winter-Werner B, Heinis C, Cramer N. The 4. Chimia (Aarau). 2011 Oct 26;65(10):818-820. doi: 10.2533/chimia.2011.818. PMID: 28978371.
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Chiral cyclopentadienyl iridium(III) complexes promote enantioselective cycloisomerizations giving fused cyclopropanes.

Angewandte Chemie (International ed. in English)

Dieckmann M, Jang YS, Cramer N.
PMID: 26310394
Angew Chem Int Ed Engl. 2015 Oct 05;54(41):12149-52. doi: 10.1002/anie.201506483. Epub 2015 Aug 27.

The cyclopentadienyl (Cp) group is a very important ligand for many transition-metal complexes which have been applied in catalysis. The availability of chiral cyclopentadienyl ligands (Cp(x) ) lags behind other ligand classes, thus hampering the investigation of enantioselective processes....

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Dieckmann M, Jang YS, Cramer N. Chiral cyclopentadienyl iridium(III) complexes promote enantioselective cycloisomerizations giving fused cyclopropanes. Angew Chem Int Ed Engl. 2015;54(41):12149-52doi: 10.1002/anie.201506483.
Dieckmann, M., Jang, Y. S., & Cramer, N. (2015). Chiral cyclopentadienyl iridium(III) complexes promote enantioselective cycloisomerizations giving fused cyclopropanes. Angewandte Chemie (International ed. in English), 54(41), 12149-52. https://doi.org/10.1002/anie.201506483
Dieckmann, Michael, et al. "Chiral cyclopentadienyl iridium(III) complexes promote enantioselective cycloisomerizations giving fused cyclopropanes." Angewandte Chemie (International ed. in English) vol. 54,41 (2015): 12149-52. doi: https://doi.org/10.1002/anie.201506483
Dieckmann M, Jang YS, Cramer N. Chiral cyclopentadienyl iridium(III) complexes promote enantioselective cycloisomerizations giving fused cyclopropanes. Angew Chem Int Ed Engl. 2015 Oct 05;54(41):12149-52. doi: 10.1002/anie.201506483. Epub 2015 Aug 27. PMID: 26310394.
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Space Environment Effects on Flexible, Low-Voltage Organic Thin-Film Transistors.

ACS applied materials & interfaces

Basiricò L, Basile AF, Cosseddu P, Gerardin S, Cramer T, Bagatin M, Ciavatti A, Paccagnella A, Bonfiglio A, Fraboni B.
PMID: 28925264
ACS Appl Mater Interfaces. 2017 Oct 11;9(40):35150-35158. doi: 10.1021/acsami.7b08440. Epub 2017 Sep 29.

Organic electronic devices fabricated on flexible substrates are promising candidates for applications in environments where flexible, lightweight, and radiation hard materials are required. In this work, device parameters such as threshold voltage, charge mobility, and trap density of 13-bis(triisopropylsilylethynyl)pentacene...

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Basiricò L, Basile AF, Cosseddu P, et al. Space Environment Effects on Flexible, Low-Voltage Organic Thin-Film Transistors. ACS Appl Mater Interfaces. 2017;9(40):35150-35158doi: 10.1021/acsami.7b08440.
Basiricò, L., Basile, A. F., Cosseddu, P., Gerardin, S., Cramer, T., Bagatin, M., Ciavatti, A., Paccagnella, A., Bonfiglio, A., & Fraboni, B. (2017). Space Environment Effects on Flexible, Low-Voltage Organic Thin-Film Transistors. ACS applied materials & interfaces, 9(40), 35150-35158. https://doi.org/10.1021/acsami.7b08440
Basiricò, Laura, et al. "Space Environment Effects on Flexible, Low-Voltage Organic Thin-Film Transistors." ACS applied materials & interfaces vol. 9,40 (2017): 35150-35158. doi: https://doi.org/10.1021/acsami.7b08440
Basiricò L, Basile AF, Cosseddu P, Gerardin S, Cramer T, Bagatin M, Ciavatti A, Paccagnella A, Bonfiglio A, Fraboni B. Space Environment Effects on Flexible, Low-Voltage Organic Thin-Film Transistors. ACS Appl Mater Interfaces. 2017 Oct 11;9(40):35150-35158. doi: 10.1021/acsami.7b08440. Epub 2017 Sep 29. PMID: 28925264.
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Proteomic analysis of the medicinal plant Artemisia annua: Data from leaf and trichome extracts.

Data in brief

Bryant L, Patole C, Cramer R.
PMID: 26977431
Data Brief. 2016 Feb 23;7:325-31. doi: 10.1016/j.dib.2016.02.038. eCollection 2016 Jun.

This article contains raw and processed data related to research published by Bryant et al.[1]. Data was obtained by MS-based proteomics, analysing trichome-enriched, trichome-depleted and whole leaf samples taken from the medicinal plant Artemisia annua and searching the acquired...

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Bryant L, Patole C, Cramer R. Proteomic analysis of the medicinal plant Artemisia annua: Data from leaf and trichome extracts. Data Brief. 2016;7:325-31doi: 10.1016/j.dib.2016.02.038.
Bryant, L., Patole, C., & Cramer, R. (2016). Proteomic analysis of the medicinal plant Artemisia annua: Data from leaf and trichome extracts. Data in brief, 7325-31. https://doi.org/10.1016/j.dib.2016.02.038
Bryant, Laura, et al. "Proteomic analysis of the medicinal plant Artemisia annua: Data from leaf and trichome extracts." Data in brief vol. 7 (2016): 325-31. doi: https://doi.org/10.1016/j.dib.2016.02.038
Bryant L, Patole C, Cramer R. Proteomic analysis of the medicinal plant Artemisia annua: Data from leaf and trichome extracts. Data Brief. 2016 Feb 23;7:325-31. doi: 10.1016/j.dib.2016.02.038. eCollection 2016 Jun. PMID: 26977431; PMCID: PMC4781977.
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Excited-State Absorption from Real-Time Time-Dependent Density Functional Theory: Optical Limiting in Zinc Phthalocyanine.

The journal of physical chemistry letters

Fischer SA, Cramer CJ, Govind N.
PMID: 27007445
J Phys Chem Lett. 2016 Apr 07;7(7):1387-91. doi: 10.1021/acs.jpclett.6b00282. Epub 2016 Mar 28.

Optical-limiting materials are capable of attenuating light to protect delicate equipment from high-intensity light sources. Phthalocyanines have attracted a lot of attention for optical-limiting applications due to their versatility and large nonlinear absorption. With excited-state absorption (ESA) being the...

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Fischer SA, Cramer CJ, Govind N. Excited-State Absorption from Real-Time Time-Dependent Density Functional Theory: Optical Limiting in Zinc Phthalocyanine. J Phys Chem Lett. 2016;7(7):1387-91doi: 10.1021/acs.jpclett.6b00282.
Fischer, S. A., Cramer, C. J., & Govind, N. (2016). Excited-State Absorption from Real-Time Time-Dependent Density Functional Theory: Optical Limiting in Zinc Phthalocyanine. The journal of physical chemistry letters, 7(7), 1387-91. https://doi.org/10.1021/acs.jpclett.6b00282
Fischer, Sean A, et al. "Excited-State Absorption from Real-Time Time-Dependent Density Functional Theory: Optical Limiting in Zinc Phthalocyanine." The journal of physical chemistry letters vol. 7,7 (2016): 1387-91. doi: https://doi.org/10.1021/acs.jpclett.6b00282
Fischer SA, Cramer CJ, Govind N. Excited-State Absorption from Real-Time Time-Dependent Density Functional Theory: Optical Limiting in Zinc Phthalocyanine. J Phys Chem Lett. 2016 Apr 07;7(7):1387-91. doi: 10.1021/acs.jpclett.6b00282. Epub 2016 Mar 28. PMID: 27007445.
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Direct X-ray photoconversion in flexible organic thin film devices operated below 1 V.

Nature communications

Basiricò L, Ciavatti A, Cramer T, Cosseddu P, Bonfiglio A, Fraboni B.
PMID: 27708274
Nat Commun. 2016 Oct 06;7:13063. doi: 10.1038/ncomms13063.

The application of organic electronic materials for the detection of ionizing radiations is very appealing thanks to their mechanical flexibility, low-cost and simple processing in comparison to their inorganic counterpart. In this work we investigate the direct X-ray photoconversion...

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Basiricò L, Ciavatti A, Cramer T, et al. Direct X-ray photoconversion in flexible organic thin film devices operated below 1 V. Nat Commun. 2016;7:13063doi: 10.1038/ncomms13063.
Basiricò, L., Ciavatti, A., Cramer, T., Cosseddu, P., Bonfiglio, A., & Fraboni, B. (2016). Direct X-ray photoconversion in flexible organic thin film devices operated below 1 V. Nature communications, 713063. https://doi.org/10.1038/ncomms13063
Basiricò, Laura, et al. "Direct X-ray photoconversion in flexible organic thin film devices operated below 1 V." Nature communications vol. 7 (2016): 13063. doi: https://doi.org/10.1038/ncomms13063
Basiricò L, Ciavatti A, Cramer T, Cosseddu P, Bonfiglio A, Fraboni B. Direct X-ray photoconversion in flexible organic thin film devices operated below 1 V. Nat Commun. 2016 Oct 06;7:13063. doi: 10.1038/ncomms13063. PMID: 27708274; PMCID: PMC5059709.
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Dielectron mass spectra from Au+Au collisions at √[s(NN)]=200  GeV.

Physical review letters

Adamczyk L, Adkins JK, Agakishiev G, Aggarwal MM, Ahammed Z, Alekseev I, Alford J, Anson CD, Aparin A, Arkhipkin D, Aschenauer EC, Averichev GS, Banerjee A, Barnovska Z, Beavis DR, Bellwied R, Bhasin A, Bhati AK, Bhattarai P, Bichsel H, Bielcik J, Bielcikova J, Bland LC, Bordyuzhin IG, Borowski W, Bouchet J, Brandin AV, Brovko SG, Bültmann S, Bunzarov I, Burton TP, Butterworth J, Caines H, Calderón de la Barca Sánchez M, Cebra D, Cendejas R, Cervantes MC, Chaloupka P, Chang Z, Chattopadhyay S, Chen HF, Chen JH, Chen L, Cheng J, Cherney M, Chikanian A, Christie W, Chwastowski J, Codrington MJ, Cramer JG, Crawford HJ, Cui X, Das S, Davila Leyva A, De Silva LC, Debbe RR, Dedovich TG, Deng J, Derevschikov AA, Derradi de Souza R, Dhamija S, di Ruzza B, Didenko L, Dilks C, Ding F, Djawotho P, Dong X, Drachenberg JL, Draper JE, Du CM, Dunkelberger LE, Dunlop JC, Efimov LG, Engelage J, Engle KS, Eppley G, Eun L, Evdokimov O, Fatemi R, Fazio S, Fedorisin J, Filip P, Finch E, Fisyak Y, Flores CE, Gagliardi CA, Gangadharan DR, Garand D, Geurts F, Gibson A, Girard M, Gliske S, Grosnick D, Guo Y, Gupta A, Gupta S, Guryn W, Haag B, Hajkova O, Hamed A, Han LX, Haque R, Harris JW, Heppelmann S, Hirsch A, Hoffmann GW, Hofman DJ, Horvat S, Huang B, Huang HZ, Huang X, Huck P, Humanic TJ, Igo G, Jacobs WW, Jang H, Judd EG, Kabana S, Kalinkin D, Kang K, Kauder K, Ke HW, Keane D, Kechechyan A, Kesich A, Khan ZH, Kikola DP, Kisel I, Kisiel A, Koetke DD, Kollegger T, Konzer J, Koralt I, Korsch W, Kotchenda L, Kravtsov P, Krueger K, Kulakov I, Kumar L, Kycia RA, Lamont MA, Landgraf JM, Landry KD, Lauret J, Lebedev A, Lednicky R, Lee JH, LeVine MJ, Li C, Li W, Li X, Li X, Li Y, Li ZM, Lima LM, Lisa MA, Liu F, Ljubicic T, Llope WJ, Longacre RS, Luo X, Ma GL, Ma YG, Madagodagettige Don DM, Mahapatra DP, Majka R, Margetis S, Markert C, Masui H, Matis HS, McDonald D, McShane TS, Minaev NG, Mioduszewski S, Mohanty B, Mondal MM, Morozov DA, Munhoz MG, Mustafa MK, Nandi BK, Nasim M, Nayak TK, Nelson JM, Nogach LV, Noh SY, Novak J, Nurushev SB, Odyniec G, Ogawa A, Oh K, Ohlson A, Okorokov V, Oldag EW, Oliveira RA, Pachr M, Page BS, Pal SK, Pan YX, Pandit Y, Panebratsev Y, Pawlak T, Pawlik B, Pei H, Perkins C, Peryt W, Pile P, Planinic M, Pluta J, Plyku D, Poljak N, Porter J, Poskanzer AM, Pruthi NK, Przybycien M, Pujahari PR, Qiu H, Quintero A, Ramachandran S, Raniwala R, Raniwala S, Ray RL, Riley CK, Ritter HG, Roberts JB, Rogachevskiy OV, Romero JL, Ross JF, Roy A, Ruan L, Rusnak J, Sahoo NR, Sahu PK, Sakrejda I, Salur S, Sandacz A, Sandweiss J, Sangaline E, Sarkar A, Schambach J, Scharenberg RP, Schmah AM, Schmidke WB, Schmitz N, Seger J, Seyboth P, Shah N, Shahaliev E, Shanmuganathan PV, Shao M, Sharma B, Shen WQ, Shi SS, Shou QY, Sichtermann EP, Singaraju RN, Skoby MJ, Smirnov D, Smirnov N, Solanki D, Sorensen P, deSouza UG, Spinka HM, Srivastava B, Stanislaus TD, Stevens JR, Stock R, Strikhanov M, Stringfellow B, Suaide AA, Sumbera M, Sun X, Sun XM, Sun Y, Sun Z, Surrow B, Svirida DN, Symons TJ, Szanto de Toledo A, Takahashi J, Tang AH, Tang Z, Tarnowsky T, Thomas JH, Timmins AR, Tlusty D, Tokarev M, Trentalange S, Tribble RE, Tribedy P, Trzeciak BA, Tsai OD, Turnau J, Ullrich T, Underwood DG, Van Buren G, van Nieuwenhuizen G, Vanfossen JA, Varma R, Vasconcelos GM, Vasiliev AN, Vertesi R, Videbæk F, Viyogi YP, Vokal S, Vossen A, Wada M, Wang F, Wang G, Wang H, Wang JS, Wang XL, Wang Y, Wang Y, Webb G, Webb JC, Westfall GD, Wieman H, Wissink SW, Witt R, Wu YF, Xiao Z, Xie W, Xin K, Xu H, Xu N, Xu QH, Xu Y, Xu Z, Yan W, Yang C, Yang Y, Yang Y, Ye Z, Yepes P, Yi L, Yip K, Yoo IK, Zawisza Y, Zbroszczyk H, Zha W, Zhang JB, Zhang JL, Zhang S, Zhang XP, Zhang Y, Zhang ZP, Zhao F, Zhao J, Zhong C, Zhu X, Zhu YH, Zoulkarneeva Y, Zyzak M.
PMID: 25062167
Phys Rev Lett. 2014 Jul 11;113(2):022301. doi: 10.1103/PhysRevLett.113.022301. Epub 2014 Jul 09.

We report the STAR measurements of dielectron (e(+)e(-)) production at midrapidity (|y(ee)|

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Adamczyk L, Adkins JK, Agakishiev G, et al. Dielectron mass spectra from Au+Au collisions at √[s(NN)]=200  GeV. Phys Rev Lett. 2014;113(2):022301doi: 10.1103/PhysRevLett.113.022301.
Adamczyk, L., Adkins, J. K., Agakishiev, G., Aggarwal, M. M., Ahammed, Z., Alekseev, I., Alford, J., Anson, C. D., Aparin, A., Arkhipkin, D., Aschenauer, E. C., Averichev, G. S., Banerjee, A., Barnovska, Z., Beavis, D. R., Bellwied, R., Bhasin, A., Bhati, A. K., Bhattarai, P., Bichsel, H., Bielcik, J., Bielcikova, J., Bland, L. C., Bordyuzhin, I. G., Borowski, W., Bouchet, J., Brandin, A. V., Brovko, S. G., Bültmann, S., Bunzarov, I., Burton, T. P., Butterworth, J., Caines, H., Calderón de la Barca Sánchez, M., Cebra, D., Cendejas, R., Cervantes, M. C., Chaloupka, P., Chang, Z., Chattopadhyay, S., Chen, H. F., Chen, J. H., Chen, L., Cheng, J., Cherney, M., Chikanian, A., Christie, W., Chwastowski, J., Codrington, M. J., Cramer, J. G., Crawford, H. J., Cui, X., Das, S., Davila Leyva, A., De Silva, L. C., Debbe, R. R., Dedovich, T. G., Deng, J., Derevschikov, A. A., Derradi de Souza, R., Dhamija, S., di Ruzza, B., Didenko, L., Dilks, C., Ding, F., Djawotho, P., Dong, X., Drachenberg, J. L., Draper, J. E., Du, C. M., Dunkelberger, L. E., Dunlop, J. C., Efimov, L. G., Engelage, J., Engle, K. S., Eppley, G., Eun, L., Evdokimov, O., Fatemi, R., Fazio, S., Fedorisin, J., Filip, P., Finch, E., Fisyak, Y., Flores, C. E., Gagliardi, C. A., Gangadharan, D. R., Garand, D., Geurts, F., Gibson, A., Girard, M., Gliske, S., Grosnick, D., Guo, Y., Gupta, A., Gupta, S., Guryn, W., Haag, B., Hajkova, O., Hamed, A., Han, L. X., Haque, R., Harris, J. W., Heppelmann, S., Hirsch, A., Hoffmann, G. W., Hofman, D. J., Horvat, S., Huang, B., Huang, H. Z., Huang, X., Huck, P., Humanic, T. J., Igo, G., Jacobs, W. W., Jang, H., Judd, E. G., Kabana, S., Kalinkin, D., Kang, K., Kauder, K., Ke, H. W., Keane, D., Kechechyan, A., Kesich, A., Khan, Z. H., Kikola, D. P., Kisel, I., Kisiel, A., Koetke, D. D., Kollegger, T., Konzer, J., Koralt, I., Korsch, W., Kotchenda, L., Kravtsov, P., Krueger, K., Kulakov, I., Kumar, L., Kycia, R. A., Lamont, M. A., Landgraf, J. M., Landry, K. D., Lauret, J., Lebedev, A., Lednicky, R., Lee, J. H., LeVine, M. J., Li, C., Li, W., Li, X., Li, X., Li, Y., Li, Z. M., Lima, L. M., Lisa, M. A., Liu, F., Ljubicic, T., Llope, W. J., Longacre, R. S., Luo, X., Ma, G. L., Ma, Y. G., Madagodagettige Don, D. M., Mahapatra, D. P., Majka, R., Margetis, S., Markert, C., Masui, H., Matis, H. S., McDonald, D., McShane, T. S., Minaev, N. G., Mioduszewski, S., Mohanty, B., Mondal, M. M., Morozov, D. A., Munhoz, M. G., Mustafa, M. K., Nandi, B. K., Nasim, M., Nayak, T. K., Nelson, J. M., Nogach, L. V., Noh, S. Y., Novak, J., Nurushev, S. B., Odyniec, G., Ogawa, A., Oh, K., Ohlson, A., Okorokov, V., Oldag, E. W., Oliveira, R. A., Pachr, M., Page, B. S., Pal, S. K., Pan, Y. X., Pandit, Y., Panebratsev, Y., Pawlak, T., Pawlik, B., Pei, H., Perkins, C., Peryt, W., Pile, P., Planinic, M., Pluta, J., Plyku, D., Poljak, N., Porter, J., Poskanzer, A. M., Pruthi, N. K., Przybycien, M., Pujahari, P. R., Qiu, H., Quintero, A., Ramachandran, S., Raniwala, R., Raniwala, S., Ray, R. L., Riley, C. K., Ritter, H. G., Roberts, J. B., Rogachevskiy, O. V., Romero, J. L., Ross, J. F., Roy, A., Ruan, L., Rusnak, J., Sahoo, N. R., Sahu, P. K., Sakrejda, I., Salur, S., Sandacz, A., Sandweiss, J., Sangaline, E., Sarkar, A., Schambach, J., Scharenberg, R. P., Schmah, A. M., Schmidke, W. B., Schmitz, N., Seger, J., Seyboth, P., Shah, N., Shahaliev, E., Shanmuganathan, P. V., Shao, M., Sharma, B., Shen, W. Q., Shi, S. S., Shou, Q. Y., Sichtermann, E. P., Singaraju, R. N., Skoby, M. J., Smirnov, D., Smirnov, N., Solanki, D., Sorensen, P., deSouza, U. G., Spinka, H. M., Srivastava, B., Stanislaus, T. D., Stevens, J. R., Stock, R., Strikhanov, M., Stringfellow, B., Suaide, A. A., Sumbera, M., Sun, X., Sun, X. M., Sun, Y., Sun, Z., Surrow, B., Svirida, D. N., Symons, T. J., Szanto de Toledo, A., Takahashi, J., Tang, A. H., Tang, Z., Tarnowsky, T., Thomas, J. H., Timmins, A. R., Tlusty, D., Tokarev, M., Trentalange, S., Tribble, R. E., Tribedy, P., Trzeciak, B. A., Tsai, O. D., Turnau, J., Ullrich, T., Underwood, D. G., Van Buren, G., van Nieuwenhuizen, G., Vanfossen, J. A., Varma, R., Vasconcelos, G. M., Vasiliev, A. N., Vertesi, R., Videbæk, F., Viyogi, Y. P., Vokal, S., Vossen, A., Wada, M., Wang, F., Wang, G., Wang, H., Wang, J. S., Wang, X. L., Wang, Y., Wang, Y., Webb, G., Webb, J. C., Westfall, G. D., Wieman, H., Wissink, S. W., Witt, R., Wu, Y. F., Xiao, Z., Xie, W., Xin, K., Xu, H., Xu, N., Xu, Q. H., Xu, Y., Xu, Z., Yan, W., Yang, C., Yang, Y., Yang, Y., Ye, Z., Yepes, P., Yi, L., Yip, K., Yoo, I. K., Zawisza, Y., Zbroszczyk, H., Zha, W., Zhang, J. B., Zhang, J. L., Zhang, S., Zhang, X. P., Zhang, Y., Zhang, Z. P., Zhao, F., Zhao, J., Zhong, C., Zhu, X., Zhu, Y. H., Zoulkarneeva, Y., Zyzak, M. (2014). Dielectron mass spectra from Au+Au collisions at √[s(NN)]=200  GeV. Physical review letters, 113(2), 022301. https://doi.org/10.1103/PhysRevLett.113.022301
Adamczyk, L, et al. "Dielectron mass spectra from Au+Au collisions at √[s(NN)]=200  GeV." Physical review letters vol. 113,2 (2014): 022301. doi: https://doi.org/10.1103/PhysRevLett.113.022301
Adamczyk L, Adkins JK, Agakishiev G, Aggarwal MM, Ahammed Z, Alekseev I, Alford J, Anson CD, Aparin A, Arkhipkin D, Aschenauer EC, Averichev GS, Banerjee A, Barnovska Z, Beavis DR, Bellwied R, Bhasin A, Bhati AK, Bhattarai P, Bichsel H, Bielcik J, Bielcikova J, Bland LC, Bordyuzhin IG, Borowski W, Bouchet J, Brandin AV, Brovko SG, Bültmann S, Bunzarov I, Burton TP, Butterworth J, Caines H, Calderón de la Barca Sánchez M, Cebra D, Cendejas R, Cervantes MC, Chaloupka P, Chang Z, Chattopadhyay S, Chen HF, Chen JH, Chen L, Cheng J, Cherney M, Chikanian A, Christie W, Chwastowski J, Codrington MJ, Cramer JG, Crawford HJ, Cui X, Das S, Davila Leyva A, De Silva LC, Debbe RR, Dedovich TG, Deng J, Derevschikov AA, Derradi de Souza R, Dhamija S, di Ruzza B, Didenko L, Dilks C, Ding F, Djawotho P, Dong X, Drachenberg JL, Draper JE, Du CM, Dunkelberger LE, Dunlop JC, Efimov LG, Engelage J, Engle KS, Eppley G, Eun L, Evdokimov O, Fatemi R, Fazio S, Fedorisin J, Filip P, Finch E, Fisyak Y, Flores CE, Gagliardi CA, Gangadharan DR, Garand D, Geurts F, Gibson A, Girard M, Gliske S, Grosnick D, Guo Y, Gupta A, Gupta S, Guryn W, Haag B, Hajkova O, Hamed A, Han LX, Haque R, Harris JW, Heppelmann S, Hirsch A, Hoffmann GW, Hofman DJ, Horvat S, Huang B, Huang HZ, Huang X, Huck P, Humanic TJ, Igo G, Jacobs WW, Jang H, Judd EG, Kabana S, Kalinkin D, Kang K, Kauder K, Ke HW, Keane D, Kechechyan A, Kesich A, Khan ZH, Kikola DP, Kisel I, Kisiel A, Koetke DD, Kollegger T, Konzer J, Koralt I, Korsch W, Kotchenda L, Kravtsov P, Krueger K, Kulakov I, Kumar L, Kycia RA, Lamont MA, Landgraf JM, Landry KD, Lauret J, Lebedev A, Lednicky R, Lee JH, LeVine MJ, Li C, Li W, Li X, Li X, Li Y, Li ZM, Lima LM, Lisa MA, Liu F, Ljubicic T, Llope WJ, Longacre RS, Luo X, Ma GL, Ma YG, Madagodagettige Don DM, Mahapatra DP, Majka R, Margetis S, Markert C, Masui H, Matis HS, McDonald D, McShane TS, Minaev NG, Mioduszewski S, Mohanty B, Mondal MM, Morozov DA, Munhoz MG, Mustafa MK, Nandi BK, Nasim M, Nayak TK, Nelson JM, Nogach LV, Noh SY, Novak J, Nurushev SB, Odyniec G, Ogawa A, Oh K, Ohlson A, Okorokov V, Oldag EW, Oliveira RA, Pachr M, Page BS, Pal SK, Pan YX, Pandit Y, Panebratsev Y, Pawlak T, Pawlik B, Pei H, Perkins C, Peryt W, Pile P, Planinic M, Pluta J, Plyku D, Poljak N, Porter J, Poskanzer AM, Pruthi NK, Przybycien M, Pujahari PR, Qiu H, Quintero A, Ramachandran S, Raniwala R, Raniwala S, Ray RL, Riley CK, Ritter HG, Roberts JB, Rogachevskiy OV, Romero JL, Ross JF, Roy A, Ruan L, Rusnak J, Sahoo NR, Sahu PK, Sakrejda I, Salur S, Sandacz A, Sandweiss J, Sangaline E, Sarkar A, Schambach J, Scharenberg RP, Schmah AM, Schmidke WB, Schmitz N, Seger J, Seyboth P, Shah N, Shahaliev E, Shanmuganathan PV, Shao M, Sharma B, Shen WQ, Shi SS, Shou QY, Sichtermann EP, Singaraju RN, Skoby MJ, Smirnov D, Smirnov N, Solanki D, Sorensen P, deSouza UG, Spinka HM, Srivastava B, Stanislaus TD, Stevens JR, Stock R, Strikhanov M, Stringfellow B, Suaide AA, Sumbera M, Sun X, Sun XM, Sun Y, Sun Z, Surrow B, Svirida DN, Symons TJ, Szanto de Toledo A, Takahashi J, Tang AH, Tang Z, Tarnowsky T, Thomas JH, Timmins AR, Tlusty D, Tokarev M, Trentalange S, Tribble RE, Tribedy P, Trzeciak BA, Tsai OD, Turnau J, Ullrich T, Underwood DG, Van Buren G, van Nieuwenhuizen G, Vanfossen JA, Varma R, Vasconcelos GM, Vasiliev AN, Vertesi R, Videbæk F, Viyogi YP, Vokal S, Vossen A, Wada M, Wang F, Wang G, Wang H, Wang JS, Wang XL, Wang Y, Wang Y, Webb G, Webb JC, Westfall GD, Wieman H, Wissink SW, Witt R, Wu YF, Xiao Z, Xie W, Xin K, Xu H, Xu N, Xu QH, Xu Y, Xu Z, Yan W, Yang C, Yang Y, Yang Y, Ye Z, Yepes P, Yi L, Yip K, Yoo IK, Zawisza Y, Zbroszczyk H, Zha W, Zhang JB, Zhang JL, Zhang S, Zhang XP, Zhang Y, Zhang ZP, Zhao F, Zhao J, Zhong C, Zhu X, Zhu YH, Zoulkarneeva Y, Zyzak M. Dielectron mass spectra from Au+Au collisions at √[s(NN)]=200  GeV. Phys Rev Lett. 2014 Jul 11;113(2):022301. doi: 10.1103/PhysRevLett.113.022301. Epub 2014 Jul 09. PMID: 25062167.
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