Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
November 6, 2025 at 6:22 PM
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
October 27, 2025 at 6:22 PM
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
October 19, 2025 at 5:22 PM
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
October 13, 2025 at 12:04 PM
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
October 6, 2025 at 12:03 PM
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
September 29, 2025 at 12:03 PM
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
September 20, 2025 at 5:22 PM
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
September 15, 2025 at 12:03 PM
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
September 11, 2025 at 12:03 PM
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
September 7, 2025 at 5:22 PM
Are there invisible (and long-lived) undiscovered particles produced in the decays of B mesons? Those would be super rare, so we use a huge dataset of B mesons with dedicated data taking techniques. We didn't see any new particles though, this #CMSPaper is a #nullresult arxiv.org/abs/2508.06363
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
August 11, 2025 at 12:03 PM
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
August 4, 2025 at 5:22 PM
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
July 26, 2025 at 12:03 PM
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
July 24, 2025 at 5:22 PM
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
July 14, 2025 at 5:22 PM
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
July 5, 2025 at 5:22 PM
Supersymmetry is a significant theory as well as a benchmark, because at the LHC, supersymmetry helps predict the behaviour of undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions arxiv.org/abs/2506.08825
Supersymmetry is a significant theory, primarily if string theory exists, as it implies the existence of supersymmetry. At the LHC, supersymmetry helps model undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions.
June 24, 2025 at 12:03 PM
Supersymmetry is a significant theory, primarily if string theory exists, as it implies the existence of supersymmetry. At the LHC, supersymmetry helps model undiscovered particles. This #nullresult #CMSPaper focused on the supersymmetry partner of the top quark, expected to cause busy collisions.
"No significant excess is observed over the standard model backgrounds."
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#nullresult on suurenergiafysiikassa ihan tavallinen, ettei peräti yleisin tulos. Ei näistä tietenkään otsikkoja lehtiin revitä, sillä ketäpä se kiinnostaa. Paitsi tutkijoita. Ja joitain harvoja muita. Kuten minua :)
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#nullresult on suurenergiafysiikassa ihan tavallinen, ettei peräti yleisin tulos. Ei näistä tietenkään otsikkoja lehtiin revitä, sillä ketäpä se kiinnostaa. Paitsi tutkijoita. Ja joitain harvoja muita. Kuten minua :)
#CMSpaper: Search for nonresonant new physics signals in high-mass dilepton events produced in association with b-tagged jets in proton-proton collisions at √s = 13 TeV (arXiv:2506.13565) https://arxiv.org/abs/2506.13565 #NewPhysics
June 18, 2025 at 6:24 AM
"No significant excess is observed over the standard model backgrounds."
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#nullresult on suurenergiafysiikassa ihan tavallinen, ettei peräti yleisin tulos. Ei näistä tietenkään otsikkoja lehtiin revitä, sillä ketäpä se kiinnostaa. Paitsi tutkijoita. Ja joitain harvoja muita. Kuten minua :)
—
#nullresult on suurenergiafysiikassa ihan tavallinen, ettei peräti yleisin tulos. Ei näistä tietenkään otsikkoja lehtiin revitä, sillä ketäpä se kiinnostaa. Paitsi tutkijoita. Ja joitain harvoja muita. Kuten minua :)
#CMSPaper 1391 is a #nullresult that looks for undiscovered particles that travel halfway through the CMS detector before they decay to standard model particles. As these particles normally don't make it to the muon system, we look for photons in the muon system arxiv.org/abs/2503.16699
April 18, 2025 at 10:27 AM
#CMSPaper 1391 is a #nullresult that looks for undiscovered particles that travel halfway through the CMS detector before they decay to standard model particles. As these particles normally don't make it to the muon system, we look for photons in the muon system arxiv.org/abs/2503.16699
#CMSpaper 1386 examines deviations in extra quark/gluon jet production in lepton-rich collisions, expected to follow a power law decline. The study focuses on Z+W boson signatures plus up to 5+ extra jets. We use this #nullresult to constrain supersymmetry predictions arxiv.org/abs/2503.06726
April 16, 2025 at 12:04 PM
#CMSpaper 1386 examines deviations in extra quark/gluon jet production in lepton-rich collisions, expected to follow a power law decline. The study focuses on Z+W boson signatures plus up to 5+ extra jets. We use this #nullresult to constrain supersymmetry predictions arxiv.org/abs/2503.06726
#CMSPaper 1391 is a #nullresult that looks for undiscovered particles that travel halfway through the CMS detector before they decay to standard model particles. As these particles normally don't make it to the muon system, we look for photons in the muon system arxiv.org/abs/2503.16699
April 12, 2025 at 5:22 PM
#CMSPaper 1391 is a #nullresult that looks for undiscovered particles that travel halfway through the CMS detector before they decay to standard model particles. As these particles normally don't make it to the muon system, we look for photons in the muon system arxiv.org/abs/2503.16699
#CMSpaper 1386 examines deviations in extra quark/gluon jet production in lepton-rich collisions, expected to follow a power law decline. The study focuses on Z+W boson signatures plus up to 5+ extra jets. We use this #nullresult to constrain supersymmetry predictions arxiv.org/abs/2503.06726
April 10, 2025 at 5:22 PM
#CMSpaper 1386 examines deviations in extra quark/gluon jet production in lepton-rich collisions, expected to follow a power law decline. The study focuses on Z+W boson signatures plus up to 5+ extra jets. We use this #nullresult to constrain supersymmetry predictions arxiv.org/abs/2503.06726
#CMSpaper 1386 examines deviations in extra quark/gluon jet production in lepton-rich collisions, expected to follow a power law decline. The study focuses on Z+W boson signatures plus up to 5+ extra jets. We use this #nullresult to constrain supersymmetry predictions arxiv.org/abs/2503.06726
April 1, 2025 at 12:03 PM
#CMSpaper 1386 examines deviations in extra quark/gluon jet production in lepton-rich collisions, expected to follow a power law decline. The study focuses on Z+W boson signatures plus up to 5+ extra jets. We use this #nullresult to constrain supersymmetry predictions arxiv.org/abs/2503.06726
CMSPaper 1367 looks for extra resonances in the tau-tau invariant mass spectrum (effectively extra heavy Z bosons, these are predicted in connection to grand unification theories). Taus are not easy, but this analysis is the world's most sensitive (but still a #nullresult) buff.ly/3D8gpyL
March 13, 2025 at 6:22 PM
CMSPaper 1367 looks for extra resonances in the tau-tau invariant mass spectrum (effectively extra heavy Z bosons, these are predicted in connection to grand unification theories). Taus are not easy, but this analysis is the world's most sensitive (but still a #nullresult) buff.ly/3D8gpyL
CMSPaper 1367 looks for extra resonances in the tau-tau invariant mass spectrum (effectively extra heavy Z bosons, these are predicted in connection to grand unification theories). Taus are not easy, but this analysis is the world's most sensitive (but still a #nullresult) buff.ly/3D8gpyL
March 7, 2025 at 7:16 PM
CMSPaper 1367 looks for extra resonances in the tau-tau invariant mass spectrum (effectively extra heavy Z bosons, these are predicted in connection to grand unification theories). Taus are not easy, but this analysis is the world's most sensitive (but still a #nullresult) buff.ly/3D8gpyL