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[Collection "European home culture"].

Therapie der Gegenwart

Kuhlmann F.
PMID: 1257914
Ther Ggw. 1976 Jan;115(1):142-5.

No abstract available.

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Kuhlmann F. Sammlung "Europäische Wohnkultur" [Collection "European home culture"]. Ther Ggw. 1976;115(1):142-5
Kuhlmann, F. (1976). Sammlung "Europäische Wohnkultur" [Collection "European home culture"]. Therapie der Gegenwart, 115(1), 142-5.
Kuhlmann, F. "Sammlung "Europäische Wohnkultur"" [Collection "European home culture"]. Therapie der Gegenwart vol. 115,1 (1976): 142-5.
Kuhlmann F. Sammlung "Europäische Wohnkultur" [Collection "European home culture"]. Ther Ggw. 1976 Jan;115(1):142-5. German. PMID: 1257914.
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Homogeneity of doping with paramagnetic ions by NMR.

Physical chemistry chemical physics : PCCP

Li W, Celinski VR, Weber J, Kunkel N, Kohlmann H, Schmedt auf der Günne J.
PMID: 27003194
Phys Chem Chem Phys. 2016 Apr 14;18(14):9752-7. doi: 10.1039/c5cp07606d. Epub 2016 Mar 22.

In NMR, paramagnetic dopants change the relaxation behavior and the chemical shift of the nuclei in their immediate environment. Based on the concept that the "immediate environment" in a diamagnetic host material can be described as a sphere with...

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Li W, Celinski VR, Weber J, et al. Homogeneity of doping with paramagnetic ions by NMR. Phys Chem Chem Phys. 2016;18(14):9752-7doi: 10.1039/c5cp07606d.
Li, W., Celinski, V. R., Weber, J., Kunkel, N., Kohlmann, H., & Schmedt auf der Günne, J. (2016). Homogeneity of doping with paramagnetic ions by NMR. Physical chemistry chemical physics : PCCP, 18(14), 9752-7. https://doi.org/10.1039/c5cp07606d
Li, Wenyu, et al. "Homogeneity of doping with paramagnetic ions by NMR." Physical chemistry chemical physics : PCCP vol. 18,14 (2016): 9752-7. doi: https://doi.org/10.1039/c5cp07606d
Li W, Celinski VR, Weber J, Kunkel N, Kohlmann H, Schmedt auf der Günne J. Homogeneity of doping with paramagnetic ions by NMR. Phys Chem Chem Phys. 2016 Apr 14;18(14):9752-7. doi: 10.1039/c5cp07606d. Epub 2016 Mar 22. PMID: 27003194.
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Key differences between 13 KRAS mutation detection technologies and their relevance for clinical practice.

ESMO open

Sherwood JL, Brown H, Rettino A, Schreieck A, Clark G, Claes B, Agrawal B, Chaston R, Kong BSG, Choppa P, Nygren AOH, Deras IL, Kohlmann A.
PMID: 29018576
ESMO Open. 2017 Sep 28;2(4):e000235. doi: 10.1136/esmoopen-2017-000235. eCollection 2017.

INTRODUCTION: This study assessed METHODS: Five distinct RESULTS: Overall 406/728 data points across all 13 technologies were identified correctly. Successful genotyping of admixtures ranged from 0% (Sanger sequencing) to 100% (NGS). 5/6 NGS platforms reported similar allelic frequency for...

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Sherwood JL, Brown H, Rettino A, et al. Key differences between 13 KRAS mutation detection technologies and their relevance for clinical practice. ESMO Open. 2017;2(4):e000235doi: 10.1136/esmoopen-2017-000235.
Sherwood, J. L., Brown, H., Rettino, A., Schreieck, A., Clark, G., Claes, B., Agrawal, B., Chaston, R., Kong, B. S. G., Choppa, P., Nygren, A. O. H., Deras, I. L., & Kohlmann, A. (2017). Key differences between 13 KRAS mutation detection technologies and their relevance for clinical practice. ESMO open, 2(4), e000235. https://doi.org/10.1136/esmoopen-2017-000235
Sherwood, James L, et al. "Key differences between 13 KRAS mutation detection technologies and their relevance for clinical practice." ESMO open vol. 2,4 (2017): e000235. doi: https://doi.org/10.1136/esmoopen-2017-000235
Sherwood JL, Brown H, Rettino A, Schreieck A, Clark G, Claes B, Agrawal B, Chaston R, Kong BSG, Choppa P, Nygren AOH, Deras IL, Kohlmann A. Key differences between 13 KRAS mutation detection technologies and their relevance for clinical practice. ESMO Open. 2017 Sep 28;2(4):e000235. doi: 10.1136/esmoopen-2017-000235. eCollection 2017. PMID: 29018576; PMCID: PMC5623342.
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Electronic structure of ternary rhodium hydrides with lithium and magnesium.

Inorganic chemistry

Becker JN, Bauer J, Giehr A, Chu PI, Kunkel N, Springborg M, Kohlmann H.
PMID: 24372174
Inorg Chem. 2014 Jan 21;53(2):1135-43. doi: 10.1021/ic402687p. Epub 2013 Dec 27.

Chemical bonding in and electronic structure of lithium and magnesium rhodium hydrides are studied theoretically using DFT methods. For Li3RhH4 with planar complex RhH4 structural units, Crystal Orbital Hamilton Populations reveal significant Rh−Rh interactions within infinite one-dimensional ∞ 1...

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Becker JN, Bauer J, Giehr A, et al. Electronic structure of ternary rhodium hydrides with lithium and magnesium. Inorg Chem. 2013;53(2):1135-43doi: 10.1021/ic402687p.
Becker, J. N., Bauer, J., Giehr, A., Chu, P. I., Kunkel, N., Springborg, M., & Kohlmann, H. (2014). Electronic structure of ternary rhodium hydrides with lithium and magnesium. Inorganic chemistry, 53(2), 1135-43. https://doi.org/10.1021/ic402687p
Becker, Jonas Nils, et al. "Electronic structure of ternary rhodium hydrides with lithium and magnesium." Inorganic chemistry vol. 53,2 (2014): 1135-43. doi: https://doi.org/10.1021/ic402687p
Becker JN, Bauer J, Giehr A, Chu PI, Kunkel N, Springborg M, Kohlmann H. Electronic structure of ternary rhodium hydrides with lithium and magnesium. Inorg Chem. 2014 Jan 21;53(2):1135-43. doi: 10.1021/ic402687p. Epub 2013 Dec 27. PMID: 24372174.
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Drive-field Frequency Dependent MPI Performance of Single-Core Magnetite Nanoparticle Tracers.

IEEE transactions on magnetics

Kuhlmann C, Khandhar AP, Ferguson RM, Kemp S, Wawrzik T, Schilling M, Krishnan KM, Ludwig F.
PMID: 26052157
IEEE Trans Magn. 2015 Feb;51(2). doi: 10.1109/TMAG.2014.2329772.

The drive-field frequency of Magnetic Particle Imaging (MPI) systems plays an important role for system design, safety requirements and tracer selection. Because the commonly utilized MPI drive-field frequency of 25 kHz might be increased in future system generations to...

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Kuhlmann C, Khandhar AP, Ferguson RM, et al. Drive-field Frequency Dependent MPI Performance of Single-Core Magnetite Nanoparticle Tracers. IEEE Trans Magn. 2015;51(2)doi: 10.1109/TMAG.2014.2329772.
Kuhlmann, C., Khandhar, A. P., Ferguson, R. M., Kemp, S., Wawrzik, T., Schilling, M., Krishnan, K. M., & Ludwig, F. (2015). Drive-field Frequency Dependent MPI Performance of Single-Core Magnetite Nanoparticle Tracers. IEEE transactions on magnetics, 51(2), . https://doi.org/10.1109/TMAG.2014.2329772
Kuhlmann, C, et al. "Drive-field Frequency Dependent MPI Performance of Single-Core Magnetite Nanoparticle Tracers." IEEE transactions on magnetics vol. 51,2 (2015). doi: https://doi.org/10.1109/TMAG.2014.2329772
Kuhlmann C, Khandhar AP, Ferguson RM, Kemp S, Wawrzik T, Schilling M, Krishnan KM, Ludwig F. Drive-field Frequency Dependent MPI Performance of Single-Core Magnetite Nanoparticle Tracers. IEEE Trans Magn. 2015 Feb;51(2). doi: 10.1109/TMAG.2014.2329772. PMID: 26052157; PMCID: PMC4454424.
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Negative priming for threatening vs. non-threatening information in body dysmorphic disorder.

Acta neuropsychiatrica

Wilhelm S, Buhlmann U, McNally RJ.
PMID: 26983565
Acta Neuropsychiatr. 2003 Aug;15(4):180-3. doi: 10.1034/j.1601-5215.2003.00037.x.

BACKGROUND: Individuals with body dysmorphic disorder (BDD) suffer from unpleasant, repetitive thoughts about imagined defects in appearance which are difficult to control.OBJECTIVE: The purpose of this study was to test for deficits in cognitive inhibition in BDD.METHODS: To test...

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Wilhelm S, Buhlmann U, McNally RJ. Negative priming for threatening vs. non-threatening information in body dysmorphic disorder. Acta Neuropsychiatr. 2003;15(4):180-3doi: 10.1034/j.1601-5215.2003.00037.x.
Wilhelm, S., Buhlmann, U., & McNally, R. J. (2003). Negative priming for threatening vs. non-threatening information in body dysmorphic disorder. Acta neuropsychiatrica, 15(4), 180-3. https://doi.org/10.1034/j.1601-5215.2003.00037.x
Wilhelm, Sabine, et al. "Negative priming for threatening vs. non-threatening information in body dysmorphic disorder." Acta neuropsychiatrica vol. 15,4 (2003): 180-3. doi: https://doi.org/10.1034/j.1601-5215.2003.00037.x
Wilhelm S, Buhlmann U, McNally RJ. Negative priming for threatening vs. non-threatening information in body dysmorphic disorder. Acta Neuropsychiatr. 2003 Aug;15(4):180-3. doi: 10.1034/j.1601-5215.2003.00037.x. PMID: 26983565.
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Identification and validation of Aeluropus littoralis reference genes for Quantitative Real-Time PCR Normalization.

Journal of biological research (Thessalonike, Greece)

Hashemi SH, Nematzadeh G, Ahmadian G, Yamchi A, Kuhlmann M.
PMID: 27437194
J Biol Res (Thessalon). 2016 Jul 19;23:18. doi: 10.1186/s40709-016-0053-8. eCollection 2016 Dec.

BACKGROUND: The use of stably expressed genes as normalizers has crucial role in accurate and reliable expression analysis estimated by quantitative real-time polymerase chain reaction (qPCR). Recent studies have shown that, the expression levels of common housekeeping genes are...

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Hashemi SH, Nematzadeh G, Ahmadian G, et al. Identification and validation of Aeluropus littoralis reference genes for Quantitative Real-Time PCR Normalization. J Biol Res (Thessalon). 2016;23:18doi: 10.1186/s40709-016-0053-8.
Hashemi, S. H., Nematzadeh, G., Ahmadian, G., Yamchi, A., & Kuhlmann, M. (2016). Identification and validation of Aeluropus littoralis reference genes for Quantitative Real-Time PCR Normalization. Journal of biological research (Thessalonike, Greece), 2318. https://doi.org/10.1186/s40709-016-0053-8
Hashemi, Seyyed Hamidreza, et al. "Identification and validation of Aeluropus littoralis reference genes for Quantitative Real-Time PCR Normalization." Journal of biological research (Thessalonike, Greece) vol. 23 (2016): 18. doi: https://doi.org/10.1186/s40709-016-0053-8
Hashemi SH, Nematzadeh G, Ahmadian G, Yamchi A, Kuhlmann M. Identification and validation of Aeluropus littoralis reference genes for Quantitative Real-Time PCR Normalization. J Biol Res (Thessalon). 2016 Jul 19;23:18. doi: 10.1186/s40709-016-0053-8. eCollection 2016 Dec. PMID: 27437194; PMCID: PMC4950632.
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Evaluation of drift gas selection in complex sample analyses using a high performance drift tube ion mobility-QTOF mass spectrometer.

The Analyst

Kurulugama RT, Darland E, Kuhlmann F, Stafford G, Fjeldsted J.
PMID: 26178817
Analyst. 2015 Oct 21;140(20):6834-44. doi: 10.1039/c5an00991j.

A recently developed uniform-field high resolution ion mobility (IM) quadrupole time of flight (Q-TOF) mass spectrometer is used for evaluating the utility of alternate drift gases for complex sample analyses. This study provides collision cross section comparison for 275...

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Kurulugama RT, Darland E, Kuhlmann F, et al. Evaluation of drift gas selection in complex sample analyses using a high performance drift tube ion mobility-QTOF mass spectrometer. Analyst. 2015;140(20):6834-44doi: 10.1039/c5an00991j.
Kurulugama, R. T., Darland, E., Kuhlmann, F., Stafford, G., & Fjeldsted, J. (2015). Evaluation of drift gas selection in complex sample analyses using a high performance drift tube ion mobility-QTOF mass spectrometer. The Analyst, 140(20), 6834-44. https://doi.org/10.1039/c5an00991j
Kurulugama, Ruwan T, et al. "Evaluation of drift gas selection in complex sample analyses using a high performance drift tube ion mobility-QTOF mass spectrometer." The Analyst vol. 140,20 (2015): 6834-44. doi: https://doi.org/10.1039/c5an00991j
Kurulugama RT, Darland E, Kuhlmann F, Stafford G, Fjeldsted J. Evaluation of drift gas selection in complex sample analyses using a high performance drift tube ion mobility-QTOF mass spectrometer. Analyst. 2015 Oct 21;140(20):6834-44. doi: 10.1039/c5an00991j. PMID: 26178817.
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Variation of the Eu(II) emission wavelength by substitution of fluoride by hydride in fluorite-type compounds EuH(x)F(2-x) (0.20 ≤ x ≤ 0.67).

Inorganic chemistry

Kunkel N, Meijerink A, Kohlmann H.
PMID: 24806073
Inorg Chem. 2014 May 19;53(10):4800-2. doi: 10.1021/ic500744s. Epub 2014 May 07.

Mixed-hydride fluorides EuHxF2-x were prepared by the solid-state reaction of EuF2 and EuH2 under hydrogen gas pressure in an autoclave. Eu(II) luminescence is observed for 0.20 ≤ x ≤ 0.67, while pure EuF2 does not show any emission. The...

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Kunkel N, Meijerink A, Kohlmann H. Variation of the Eu(II) emission wavelength by substitution of fluoride by hydride in fluorite-type compounds EuH(x)F(2-x) (0.20 ≤ x ≤ 0.67). Inorg Chem. 2014;53(10):4800-2doi: 10.1021/ic500744s.
Kunkel, N., Meijerink, A., & Kohlmann, H. (2014). Variation of the Eu(II) emission wavelength by substitution of fluoride by hydride in fluorite-type compounds EuH(x)F(2-x) (0.20 ≤ x ≤ 0.67). Inorganic chemistry, 53(10), 4800-2. https://doi.org/10.1021/ic500744s
Kunkel, Nathalie, et al. "Variation of the Eu(II) emission wavelength by substitution of fluoride by hydride in fluorite-type compounds EuH(x)F(2-x) (0.20 ≤ x ≤ 0.67)." Inorganic chemistry vol. 53,10 (2014): 4800-2. doi: https://doi.org/10.1021/ic500744s
Kunkel N, Meijerink A, Kohlmann H. Variation of the Eu(II) emission wavelength by substitution of fluoride by hydride in fluorite-type compounds EuH(x)F(2-x) (0.20 ≤ x ≤ 0.67). Inorg Chem. 2014 May 19;53(10):4800-2. doi: 10.1021/ic500744s. Epub 2014 May 07. PMID: 24806073.
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A self-improved water-oxidation catalyst: is one site really enough?.

Angewandte Chemie (International ed. in English)

López I, Ertem MZ, Maji S, Benet-Buchholz J, Keidel A, Kuhlmann U, Hildebrandt P, Cramer CJ, Batista VS, Llobet A.
PMID: 24259487
Angew Chem Int Ed Engl. 2014 Jan 03;53(1):205-9. doi: 10.1002/anie.201307509. Epub 2013 Nov 20.

The homogeneous catalysis of water oxidation by transition-metal complexes has experienced spectacular development over the last five years. Practical energy-conversion schemes, however, require robust catalysts with large turnover frequencies. Herein we introduce a new oxidatively rugged and powerful dinuclear...

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López I, Ertem MZ, Maji S, et al. A self-improved water-oxidation catalyst: is one site really enough?. Angew Chem Int Ed Engl. 2013;53(1):205-9doi: 10.1002/anie.201307509.
López, I., Ertem, M. Z., Maji, S., Benet-Buchholz, J., Keidel, A., Kuhlmann, U., Hildebrandt, P., Cramer, C. J., Batista, V. S., & Llobet, A. (2014). A self-improved water-oxidation catalyst: is one site really enough?. Angewandte Chemie (International ed. in English), 53(1), 205-9. https://doi.org/10.1002/anie.201307509
López, Isidoro, et al. "A self-improved water-oxidation catalyst: is one site really enough?." Angewandte Chemie (International ed. in English) vol. 53,1 (2014): 205-9. doi: https://doi.org/10.1002/anie.201307509
López I, Ertem MZ, Maji S, Benet-Buchholz J, Keidel A, Kuhlmann U, Hildebrandt P, Cramer CJ, Batista VS, Llobet A. A self-improved water-oxidation catalyst: is one site really enough?. Angew Chem Int Ed Engl. 2014 Jan 03;53(1):205-9. doi: 10.1002/anie.201307509. Epub 2013 Nov 20. PMID: 24259487.
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Electroluminescent zinc(II) bis(8-hydroxyquinoline): structural effects on electronic states and device performance.

Journal of the American Chemical Society

Sapochak LS, Benincasa FE, Schofield RS, Baker JL, Riccio KK, Fogarty D, Kohlmann H, Ferris KF, Burrows PE.
PMID: 12022846
J Am Chem Soc. 2002 May 29;124(21):6119-25. doi: 10.1021/ja0201909.

We present direct evidence for stable oligomers in vacuum-deposited thin films of zinc(II) bis(8-hydroxyquinoline) (Znq(2)). The tetramer [(Znq(2))(4)] is the energetically favored configuration in both the single crystal and the vacuum-deposited thin film. Oligomerization leads to distinct, symmetry-driven differences...

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Sapochak LS, Benincasa FE, Schofield RS, et al. Electroluminescent zinc(II) bis(8-hydroxyquinoline): structural effects on electronic states and device performance. J Am Chem Soc. 2002;124(21):6119-25doi: 10.1021/ja0201909.
Sapochak, L. S., Benincasa, F. E., Schofield, R. S., Baker, J. L., Riccio, K. K., Fogarty, D., Kohlmann, H., Ferris, K. F., & Burrows, P. E. (2002). Electroluminescent zinc(II) bis(8-hydroxyquinoline): structural effects on electronic states and device performance. Journal of the American Chemical Society, 124(21), 6119-25. https://doi.org/10.1021/ja0201909
Sapochak, Linda S, et al. "Electroluminescent zinc(II) bis(8-hydroxyquinoline): structural effects on electronic states and device performance." Journal of the American Chemical Society vol. 124,21 (2002): 6119-25. doi: https://doi.org/10.1021/ja0201909
Sapochak LS, Benincasa FE, Schofield RS, Baker JL, Riccio KK, Fogarty D, Kohlmann H, Ferris KF, Burrows PE. Electroluminescent zinc(II) bis(8-hydroxyquinoline): structural effects on electronic states and device performance. J Am Chem Soc. 2002 May 29;124(21):6119-25. doi: 10.1021/ja0201909. PMID: 12022846.
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Diffractive dijet production at sqrt[s] = 630 and 1800 GeV at the Fermilab Tevatron.

Physical review letters

Acosta D, Affolder T, Akimoto H, Albrow MG, Amaral P, Ambrose D, Amidei D, Anikeev K, Antos J, Apollinari G, Arisawa T, Artikov A, Asakawa T, Ashmanskas W, Azfar F, Azzi-Bacchetta P, Bacchetta N, Bachacou H, Bailey S, de Barbaro P, Barbaro-Galtieri A, Barnes VE, Barnett BA, Baroiant S, Barone M, Bauer G, Bedeschi F, Belforte S, Bell WH, Bellettini G, Bellinger J, Benjamin D, Bensinger J, Beretvas A, Berge JP, Berryhill J, Bhatti A, Binkley M, Bisello D, Bishai M, Blair RE, Blocker C, Bloom K, Blumenfeld B, Blusk SR, Bocci A, Bodek A, Bolla G, Bonushkin Y, Borras K, Bortoletto D, Boudreau J, Brandl A, van den Brink S, Bromberg C, Brozovic M, Brubaker E, Bruner N, Buckley-Geer E, Budagov J, Budd HS, Burkett K, Busetto G, Byon-Wagner A, Byrum KL, Cabrera S, Calafiura P, Campbell M, Carithers W, Carlson J, Carlsmith D, Caskey W, Castro A, Cauz D, Cerri A, Chan AW, Chang PS, Chang PT, Chapman J, Chen C, Chen YC, Cheng MT, Chertok M, Chiarelli G, Chirikov-Zorin I, Chlachidze G, Chlebana F, Christofek L, Chu ML, Chung JY, Chung YS, Ciobanu CI, Clark AG, Colijn AP, Connolly A, Convery ME, Conway J, Cordelli M, Cranshaw J, Cropp R, Culbertson R, Dagenhart D, D'Auria S, DeJongh F, Dell'Agnello S, Dell'Orso M, Demers S, Demortier L, Deninno M, Derwent PF, Devlin T, Dittmann JR, Dominguez A, Donati S, Done J, D'Onofrio M, Dorigo T, Eddy N, Einsweiler K, Elias JE, Engels E, Erbacher R, Errede D, Errede S, Fan Q, Fang HC, Feild RG, Fernandez JP, Ferretti C, Field RD, Fiori I, Flaugher B, Foster GW, Franklin M, Freeman J, Friedman J, Fukui Y, Furic I, Galeotti S, Gallas A, Gallinaro M, Gao T, Garcia-Sciveres M, Garfinkel AF, Gatti P, Gay C, Gerdes DW, Giannetti P, Glagolev V, Glenzinski D, Gold M, Goldstein J, Gorelov I, Goshaw AT, Gotra Y, Goulianos K, Green C, Grim G, Gris P, Grosso-Pilcher C, Guenther M, Guillian G, Guimaraes da Costa J, Haas RM, Haber C, Hahn SR, Hall C, Handa T, Handler R, Hao W, Happacher F, Hara K, Hardman AD, Harris RM, Hartmann F, Hatakeyama K, Hauser J, Heinrich J, Heiss A, Herndon M, Hill C, Hocker A, Hoffman KD, Hollebeek R, Holloway L, Huffman BT, Hughes R, Huston J, Huth J, Ikeda H, Incandela J, Introzzi G, Ivanov A, Iwai J, Iwata Y, James E, Jones M, Joshi U, Kambara H, Kamon T, Kaneko T, Karr K, Kartal S, Kasha H, Kato Y, Keaffaber TA, Kelley K, Kelly M, Khazins D, Kikuchi T, Kilminster B, Kim BJ, Kim DH, Kim HS, Kim MJ, Kim SB, Kim SH, Kim YK, Kirby M, Kirk M, Kirsch L, Klimenko S, Koehn P, Kondo K, Konigsberg J, Korn A, Korytov A, Kovacs E, Kroll J, Kruse M, Kuhlmann SE, Kurino K, Kuwabara T, Laasanen AT, Lai N, Lami S, Lammel S, Lancaster J, Lancaster M, Lander R, Lath A, Latino G, LeCompte T, Lee AM, Lee K, Leone S, Lewis JD, Lindgren M, Liss TM, Liu JB, Liu YC, Litvintsev DO, Lobban O, Lockyer NS, Loken J, Loreti M, Lucchesi D, Lukens P, Lusin S, Lyons L, Lys J, Madrak R, Maeshima K, Maksimovic P, Malferrari L, Mangano M, Mariotti M, Martignon G, Martin A, Matthews JA, Mayer J, Mazzanti P, McFarland KS, McIntyre P, Menguzzato M, Menzione A, Merkel P, Mesropian C, Meyer A, Miao T, Miller R, Miller JS, Minato H, Miscetti S, Mishina M, Mitselmakher G, Miyazaki Y, Moggi N, Moore C, Moore E, Moore R, Morita Y, Moulik T, Mulhearn M, Mukherjee A, Muller T, Munar A, Murat P, Murgia S, Nachtman J, Nagaslaev V, Nahn S, Nakada H, Nakano I, Nelson C, Nelson T, Neu C, Neuberger D, Newman-Holmes C, Ngan CY, Niu H, Nodulman L, Nomerotski A, Oh SH, Oh YD, Ohmoto T, Ohsugi T, Oishi R, Okusawa T, Olsen J, Orejudos W, Pagliarone C, Palmonari F, Paoletti R, Papadimitriou V, Partos D, Patrick J, Pauletta G, Paulini M, Paus C, Pellett D, Pescara L, Phillips TJ, Piacentino G, Pitts KT, Pompos A, Pondrom L, Pope G, Popovic M, Prokoshin F, Proudfoot J, Ptohos F, Pukhov O, Punzi G, Rakitine A, Ratnikov F, Reher D, Reichold A, Renton P, Ribon A, Riegler W, Rimondi F, Ristori L, Riveline M, Robertson WJ, Robinson A, Rodrigo T, Rolli S, Rosenson L, Roser R, Rossin R, Rott C, Roy A, Ruiz A, Safonov A, St Denis R, Sakumoto WK, Saltzberg D, Sanchez C, Sansoni A, Santi L, Sato H, Savard P, Savoy-Navarro A, Schlabach P, Schmidt EE, Schmidt MP, Schmitt M, Scodellaro L, Scott A, Scribano A, Sedov A, Segler S, Seidel S, Seiya Y, Semenov A, Semeria F, Shah T, Shapiro MD, Shepard PF, Shibayama T, Shimojima M, Shochet M, Sidoti A, Siegrist J, Sill A, Sinervo P, Singh P, Slaughter AJ, Sliwa K, Smith C, Snider FD, Solodsky A, Spalding J, Speer T, Sphicas P, Spinella F, Spiropulu M, Spiegel L, Steele J, Stefanini A, Strologas J, Strumia F, Stuart D, Sumorok K, Suzuki T, Takano T, Takashima R, Takikawa K, Tamburello P, Tanaka M, Tannenbaum B, Tecchio M, Tesarek RJ, Teng PK, Terashi K, Tether S, Thompson AS, Thomson E, Thurman-Keup R, Tipton P, Tkaczyk S, Toback D, Tollefson K, Tollestrup A, Tonelli D, Toyoda H, Trischuk W, de Troconiz JF, Tseng J, Tsybychev D, Turini N, Ukegawa F, Vaiciulis T, Valls J, Vejcik S, Velev G, Veramendi G, Vidal R, Vila I, Vilar R, Volobouev I, von der Mey M, Vucinic D, Wagner RG, Wagner RL, Wallace NB, Wan Z, Wang C, Wang MJ, Wang SM, Ward B, Waschke S, Watanabe T, Waters D, Watts T, Webb R, Wenzel H, Wester WC, Wicklund AB, Wicklund E, Wilkes T, Williams HH, Wilson P, Winer BL, Winn D, Wolbers S, Wolinski D, Wolinski J, Wolinski S, Worm S, Wu X, Wyss J, Yao W, Yeh GP, Yeh P, Yoh J, Yosef C, Yoshida T, Yu I, Yu S, Yu Z, Zanetti A, Zetti F, Zucchelli S.
PMID: 11955190
Phys Rev Lett. 2002 Apr 15;88(15):151802. doi: 10.1103/PhysRevLett.88.151802. Epub 2002 Mar 29.

We report a measurement of the diffractive structure function F(D)(jj) of the antiproton obtained from a study of dijet events produced in association with a leading antiproton in pp collisions at sqrt[s] = 630 GeV at the Fermilab Tevatron....

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Acosta D, Affolder T, Akimoto H, et al. Diffractive dijet production at sqrt[s] = 630 and 1800 GeV at the Fermilab Tevatron. Phys Rev Lett. 2002;88(15):151802doi: 10.1103/PhysRevLett.88.151802.
Acosta, D., Affolder, T., Akimoto, H., Albrow, M. G., Amaral, P., Ambrose, D., Amidei, D., Anikeev, K., Antos, J., Apollinari, G., Arisawa, T., Artikov, A., Asakawa, T., Ashmanskas, W., Azfar, F., Azzi-Bacchetta, P., Bacchetta, N., Bachacou, H., Bailey, S., de Barbaro, P., Barbaro-Galtieri, A., Barnes, V. E., Barnett, B. A., Baroiant, S., Barone, M., Bauer, G., Bedeschi, F., Belforte, S., Bell, W. H., Bellettini, G., Bellinger, J., Benjamin, D., Bensinger, J., Beretvas, A., Berge, J. P., Berryhill, J., Bhatti, A., Binkley, M., Bisello, D., Bishai, M., Blair, R. E., Blocker, C., Bloom, K., Blumenfeld, B., Blusk, S. R., Bocci, A., Bodek, A., Bolla, G., Bonushkin, Y., Borras, K., Bortoletto, D., Boudreau, J., Brandl, A., van den Brink, S., Bromberg, C., Brozovic, M., Brubaker, E., Bruner, N., Buckley-Geer, E., Budagov, J., Budd, H. S., Burkett, K., Busetto, G., Byon-Wagner, A., Byrum, K. L., Cabrera, S., Calafiura, P., Campbell, M., Carithers, W., Carlson, J., Carlsmith, D., Caskey, W., Castro, A., Cauz, D., Cerri, A., Chan, A. W., Chang, P. S., Chang, P. T., Chapman, J., Chen, C., Chen, Y. C., Cheng, M. T., Chertok, M., Chiarelli, G., Chirikov-Zorin, I., Chlachidze, G., Chlebana, F., Christofek, L., Chu, M. L., Chung, J. Y., Chung, Y. S., Ciobanu, C. I., Clark, A. G., Colijn, A. P., Connolly, A., Convery, M. E., Conway, J., Cordelli, M., Cranshaw, J., Cropp, R., Culbertson, R., Dagenhart, D., D'Auria, S., DeJongh, F., Dell'Agnello, S., Dell'Orso, M., Demers, S., Demortier, L., Deninno, M., Derwent, P. F., Devlin, T., Dittmann, J. R., Dominguez, A., Donati, S., Done, J., D'Onofrio, M., Dorigo, T., Eddy, N., Einsweiler, K., Elias, J. E., Engels, E., Erbacher, R., Errede, D., Errede, S., Fan, Q., Fang, H. C., Feild, R. G., Fernandez, J. P., Ferretti, C., Field, R. D., Fiori, I., Flaugher, B., Foster, G. W., Franklin, M., Freeman, J., Friedman, J., Fukui, Y., Furic, I., Galeotti, S., Gallas, A., Gallinaro, M., Gao, T., Garcia-Sciveres, M., Garfinkel, A. F., Gatti, P., Gay, C., Gerdes, D. W., Giannetti, P., Glagolev, V., Glenzinski, D., Gold, M., Goldstein, J., Gorelov, I., Goshaw, A. T., Gotra, Y., Goulianos, K., Green, C., Grim, G., Gris, P., Grosso-Pilcher, C., Guenther, M., Guillian, G., Guimaraes da Costa, J., Haas, R. M., Haber, C., Hahn, S. R., Hall, C., Handa, T., Handler, R., Hao, W., Happacher, F., Hara, K., Hardman, A. D., Harris, R. M., Hartmann, F., Hatakeyama, K., Hauser, J., Heinrich, J., Heiss, A., Herndon, M., Hill, C., Hocker, A., Hoffman, K. D., Hollebeek, R., Holloway, L., Huffman, B. T., Hughes, R., Huston, J., Huth, J., Ikeda, H., Incandela, J., Introzzi, G., Ivanov, A., Iwai, J., Iwata, Y., James, E., Jones, M., Joshi, U., Kambara, H., Kamon, T., Kaneko, T., Karr, K., Kartal, S., Kasha, H., Kato, Y., Keaffaber, T. A., Kelley, K., Kelly, M., Khazins, D., Kikuchi, T., Kilminster, B., Kim, B. J., Kim, D. H., Kim, H. S., Kim, M. J., Kim, S. B., Kim, S. H., Kim, Y. K., Kirby, M., Kirk, M., Kirsch, L., Klimenko, S., Koehn, P., Kondo, K., Konigsberg, J., Korn, A., Korytov, A., Kovacs, E., Kroll, J., Kruse, M., Kuhlmann, S. E., Kurino, K., Kuwabara, T., Laasanen, A. T., Lai, N., Lami, S., Lammel, S., Lancaster, J., Lancaster, M., Lander, R., Lath, A., Latino, G., LeCompte, T., Lee, A. M., Lee, K., Leone, S., Lewis, J. D., Lindgren, M., Liss, T. M., Liu, J. B., Liu, Y. C., Litvintsev, D. O., Lobban, O., Lockyer, N. S., Loken, J., Loreti, M., Lucchesi, D., Lukens, P., Lusin, S., Lyons, L., Lys, J., Madrak, R., Maeshima, K., Maksimovic, P., Malferrari, L., Mangano, M., Mariotti, M., Martignon, G., Martin, A., Matthews, J. A., Mayer, J., Mazzanti, P., McFarland, K. S., McIntyre, P., Menguzzato, M., Menzione, A., Merkel, P., Mesropian, C., Meyer, A., Miao, T., Miller, R., Miller, J. S., Minato, H., Miscetti, S., Mishina, M., Mitselmakher, G., Miyazaki, Y., Moggi, N., Moore, C., Moore, E., Moore, R., Morita, Y., Moulik, T., Mulhearn, M., Mukherjee, A., Muller, T., Munar, A., Murat, P., Murgia, S., Nachtman, J., Nagaslaev, V., Nahn, S., Nakada, H., Nakano, I., Nelson, C., Nelson, T., Neu, C., Neuberger, D., Newman-Holmes, C., Ngan, C. Y., Niu, H., Nodulman, L., Nomerotski, A., Oh, S. H., Oh, Y. D., Ohmoto, T., Ohsugi, T., Oishi, R., Okusawa, T., Olsen, J., Orejudos, W., Pagliarone, C., Palmonari, F., Paoletti, R., Papadimitriou, V., Partos, D., Patrick, J., Pauletta, G., Paulini, M., Paus, C., Pellett, D., Pescara, L., Phillips, T. J., Piacentino, G., Pitts, K. T., Pompos, A., Pondrom, L., Pope, G., Popovic, M., Prokoshin, F., Proudfoot, J., Ptohos, F., Pukhov, O., Punzi, G., Rakitine, A., Ratnikov, F., Reher, D., Reichold, A., Renton, P., Ribon, A., Riegler, W., Rimondi, F., Ristori, L., Riveline, M., Robertson, W. J., Robinson, A., Rodrigo, T., Rolli, S., Rosenson, L., Roser, R., Rossin, R., Rott, C., Roy, A., Ruiz, A., Safonov, A., St Denis, R., Sakumoto, W. K., Saltzberg, D., Sanchez, C., Sansoni, A., Santi, L., Sato, H., Savard, P., Savoy-Navarro, A., Schlabach, P., Schmidt, E. E., Schmidt, M. P., Schmitt, M., Scodellaro, L., Scott, A., Scribano, A., Sedov, A., Segler, S., Seidel, S., Seiya, Y., Semenov, A., Semeria, F., Shah, T., Shapiro, M. D., Shepard, P. F., Shibayama, T., Shimojima, M., Shochet, M., Sidoti, A., Siegrist, J., Sill, A., Sinervo, P., Singh, P., Slaughter, A. J., Sliwa, K., Smith, C., Snider, F. D., Solodsky, A., Spalding, J., Speer, T., Sphicas, P., Spinella, F., Spiropulu, M., Spiegel, L., Steele, J., Stefanini, A., Strologas, J., Strumia, F., Stuart, D., Sumorok, K., Suzuki, T., Takano, T., Takashima, R., Takikawa, K., Tamburello, P., Tanaka, M., Tannenbaum, B., Tecchio, M., Tesarek, R. J., Teng, P. K., Terashi, K., Tether, S., Thompson, A. S., Thomson, E., Thurman-Keup, R., Tipton, P., Tkaczyk, S., Toback, D., Tollefson, K., Tollestrup, A., Tonelli, D., Toyoda, H., Trischuk, W., de Troconiz, J. F., Tseng, J., Tsybychev, D., Turini, N., Ukegawa, F., Vaiciulis, T., Valls, J., Vejcik, S., Velev, G., Veramendi, G., Vidal, R., Vila, I., Vilar, R., Volobouev, I., von der Mey, M., Vucinic, D., Wagner, R. G., Wagner, R. L., Wallace, N. B., Wan, Z., Wang, C., Wang, M. J., Wang, S. M., Ward, B., Waschke, S., Watanabe, T., Waters, D., Watts, T., Webb, R., Wenzel, H., Wester, W. C., Wicklund, A. B., Wicklund, E., Wilkes, T., Williams, H. H., Wilson, P., Winer, B. L., Winn, D., Wolbers, S., Wolinski, D., Wolinski, J., Wolinski, S., Worm, S., Wu, X., Wyss, J., Yao, W., Yeh, G. P., Yeh, P., Yoh, J., Yosef, C., Yoshida, T., Yu, I., Yu, S., Yu, Z., Zanetti, A., Zetti, F., Zucchelli, S. (2002). Diffractive dijet production at sqrt[s] = 630 and 1800 GeV at the Fermilab Tevatron. Physical review letters, 88(15), 151802. https://doi.org/10.1103/PhysRevLett.88.151802
Acosta, D, et al. "Diffractive dijet production at sqrt[s] = 630 and 1800 GeV at the Fermilab Tevatron." Physical review letters vol. 88,15 (2002): 151802. doi: https://doi.org/10.1103/PhysRevLett.88.151802
Acosta D, Affolder T, Akimoto H, Albrow MG, Amaral P, Ambrose D, Amidei D, Anikeev K, Antos J, Apollinari G, Arisawa T, Artikov A, Asakawa T, Ashmanskas W, Azfar F, Azzi-Bacchetta P, Bacchetta N, Bachacou H, Bailey S, de Barbaro P, Barbaro-Galtieri A, Barnes VE, Barnett BA, Baroiant S, Barone M, Bauer G, Bedeschi F, Belforte S, Bell WH, Bellettini G, Bellinger J, Benjamin D, Bensinger J, Beretvas A, Berge JP, Berryhill J, Bhatti A, Binkley M, Bisello D, Bishai M, Blair RE, Blocker C, Bloom K, Blumenfeld B, Blusk SR, Bocci A, Bodek A, Bolla G, Bonushkin Y, Borras K, Bortoletto D, Boudreau J, Brandl A, van den Brink S, Bromberg C, Brozovic M, Brubaker E, Bruner N, Buckley-Geer E, Budagov J, Budd HS, Burkett K, Busetto G, Byon-Wagner A, Byrum KL, Cabrera S, Calafiura P, Campbell M, Carithers W, Carlson J, Carlsmith D, Caskey W, Castro A, Cauz D, Cerri A, Chan AW, Chang PS, Chang PT, Chapman J, Chen C, Chen YC, Cheng MT, Chertok M, Chiarelli G, Chirikov-Zorin I, Chlachidze G, Chlebana F, Christofek L, Chu ML, Chung JY, Chung YS, Ciobanu CI, Clark AG, Colijn AP, Connolly A, Convery ME, Conway J, Cordelli M, Cranshaw J, Cropp R, Culbertson R, Dagenhart D, D'Auria S, DeJongh F, Dell'Agnello S, Dell'Orso M, Demers S, Demortier L, Deninno M, Derwent PF, Devlin T, Dittmann JR, Dominguez A, Donati S, Done J, D'Onofrio M, Dorigo T, Eddy N, Einsweiler K, Elias JE, Engels E, Erbacher R, Errede D, Errede S, Fan Q, Fang HC, Feild RG, Fernandez JP, Ferretti C, Field RD, Fiori I, Flaugher B, Foster GW, Franklin M, Freeman J, Friedman J, Fukui Y, Furic I, Galeotti S, Gallas A, Gallinaro M, Gao T, Garcia-Sciveres M, Garfinkel AF, Gatti P, Gay C, Gerdes DW, Giannetti P, Glagolev V, Glenzinski D, Gold M, Goldstein J, Gorelov I, Goshaw AT, Gotra Y, Goulianos K, Green C, Grim G, Gris P, Grosso-Pilcher C, Guenther M, Guillian G, Guimaraes da Costa J, Haas RM, Haber C, Hahn SR, Hall C, Handa T, Handler R, Hao W, Happacher F, Hara K, Hardman AD, Harris RM, Hartmann F, Hatakeyama K, Hauser J, Heinrich J, Heiss A, Herndon M, Hill C, Hocker A, Hoffman KD, Hollebeek R, Holloway L, Huffman BT, Hughes R, Huston J, Huth J, Ikeda H, Incandela J, Introzzi G, Ivanov A, Iwai J, Iwata Y, James E, Jones M, Joshi U, Kambara H, Kamon T, Kaneko T, Karr K, Kartal S, Kasha H, Kato Y, Keaffaber TA, Kelley K, Kelly M, Khazins D, Kikuchi T, Kilminster B, Kim BJ, Kim DH, Kim HS, Kim MJ, Kim SB, Kim SH, Kim YK, Kirby M, Kirk M, Kirsch L, Klimenko S, Koehn P, Kondo K, Konigsberg J, Korn A, Korytov A, Kovacs E, Kroll J, Kruse M, Kuhlmann SE, Kurino K, Kuwabara T, Laasanen AT, Lai N, Lami S, Lammel S, Lancaster J, Lancaster M, Lander R, Lath A, Latino G, LeCompte T, Lee AM, Lee K, Leone S, Lewis JD, Lindgren M, Liss TM, Liu JB, Liu YC, Litvintsev DO, Lobban O, Lockyer NS, Loken J, Loreti M, Lucchesi D, Lukens P, Lusin S, Lyons L, Lys J, Madrak R, Maeshima K, Maksimovic P, Malferrari L, Mangano M, Mariotti M, Martignon G, Martin A, Matthews JA, Mayer J, Mazzanti P, McFarland KS, McIntyre P, Menguzzato M, Menzione A, Merkel P, Mesropian C, Meyer A, Miao T, Miller R, Miller JS, Minato H, Miscetti S, Mishina M, Mitselmakher G, Miyazaki Y, Moggi N, Moore C, Moore E, Moore R, Morita Y, Moulik T, Mulhearn M, Mukherjee A, Muller T, Munar A, Murat P, Murgia S, Nachtman J, Nagaslaev V, Nahn S, Nakada H, Nakano I, Nelson C, Nelson T, Neu C, Neuberger D, Newman-Holmes C, Ngan CY, Niu H, Nodulman L, Nomerotski A, Oh SH, Oh YD, Ohmoto T, Ohsugi T, Oishi R, Okusawa T, Olsen J, Orejudos W, Pagliarone C, Palmonari F, Paoletti R, Papadimitriou V, Partos D, Patrick J, Pauletta G, Paulini M, Paus C, Pellett D, Pescara L, Phillips TJ, Piacentino G, Pitts KT, Pompos A, Pondrom L, Pope G, Popovic M, Prokoshin F, Proudfoot J, Ptohos F, Pukhov O, Punzi G, Rakitine A, Ratnikov F, Reher D, Reichold A, Renton P, Ribon A, Riegler W, Rimondi F, Ristori L, Riveline M, Robertson WJ, Robinson A, Rodrigo T, Rolli S, Rosenson L, Roser R, Rossin R, Rott C, Roy A, Ruiz A, Safonov A, St Denis R, Sakumoto WK, Saltzberg D, Sanchez C, Sansoni A, Santi L, Sato H, Savard P, Savoy-Navarro A, Schlabach P, Schmidt EE, Schmidt MP, Schmitt M, Scodellaro L, Scott A, Scribano A, Sedov A, Segler S, Seidel S, Seiya Y, Semenov A, Semeria F, Shah T, Shapiro MD, Shepard PF, Shibayama T, Shimojima M, Shochet M, Sidoti A, Siegrist J, Sill A, Sinervo P, Singh P, Slaughter AJ, Sliwa K, Smith C, Snider FD, Solodsky A, Spalding J, Speer T, Sphicas P, Spinella F, Spiropulu M, Spiegel L, Steele J, Stefanini A, Strologas J, Strumia F, Stuart D, Sumorok K, Suzuki T, Takano T, Takashima R, Takikawa K, Tamburello P, Tanaka M, Tannenbaum B, Tecchio M, Tesarek RJ, Teng PK, Terashi K, Tether S, Thompson AS, Thomson E, Thurman-Keup R, Tipton P, Tkaczyk S, Toback D, Tollefson K, Tollestrup A, Tonelli D, Toyoda H, Trischuk W, de Troconiz JF, Tseng J, Tsybychev D, Turini N, Ukegawa F, Vaiciulis T, Valls J, Vejcik S, Velev G, Veramendi G, Vidal R, Vila I, Vilar R, Volobouev I, von der Mey M, Vucinic D, Wagner RG, Wagner RL, Wallace NB, Wan Z, Wang C, Wang MJ, Wang SM, Ward B, Waschke S, Watanabe T, Waters D, Watts T, Webb R, Wenzel H, Wester WC, Wicklund AB, Wicklund E, Wilkes T, Williams HH, Wilson P, Winer BL, Winn D, Wolbers S, Wolinski D, Wolinski J, Wolinski S, Worm S, Wu X, Wyss J, Yao W, Yeh GP, Yeh P, Yoh J, Yosef C, Yoshida T, Yu I, Yu S, Yu Z, Zanetti A, Zetti F, Zucchelli S. Diffractive dijet production at sqrt[s] = 630 and 1800 GeV at the Fermilab Tevatron. Phys Rev Lett. 2002 Apr 15;88(15):151802. doi: 10.1103/PhysRevLett.88.151802. Epub 2002 Mar 29. PMID: 11955190.
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