Upper limits on Einstein's weak equivalence principle placed by uncertainties of dispersion measures of fast radio bursts
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Upper limits on Einstein's weak equivalence principle placed by uncertainties of dispersion measures of fast radio bursts. / Hashimoto, Tetsuya; Goto, Tomotsugu; Santos, Daryl Joe D.; Ho, Simon C. -C.; Hsiao, Tiger Y. -Y.; Wong, Yi Hang Valerie; On, Alvina Y. L.; Kim, Seong Jin; Lu, Ting-Yi; Kilerci-Eser, Ece.
I: Physical Review D, Bind 104, Nr. 12, 124026, 16.12.2021.Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt
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TY - JOUR
T1 - Upper limits on Einstein's weak equivalence principle placed by uncertainties of dispersion measures of fast radio bursts
AU - Hashimoto, Tetsuya
AU - Goto, Tomotsugu
AU - Santos, Daryl Joe D.
AU - Ho, Simon C. -C.
AU - Hsiao, Tiger Y. -Y.
AU - Wong, Yi Hang Valerie
AU - On, Alvina Y. L.
AU - Kim, Seong Jin
AU - Lu, Ting-Yi
AU - Kilerci-Eser, Ece
PY - 2021/12/16
Y1 - 2021/12/16
N2 - Fast radio bursts (FRBs) are astronomical transients with millisecond timescales occurring at cosmological distances. The observed time lag between different energies of each FRB is well described by the inverse-square law of the observed frequency, i.e., dispersion measure. Therefore, FRBs provide one of the ideal laboratories to test Einstein's weak equivalence principle (WEP): the hypothetical time lag between photons with different energies under a gravitational potential. If WEP is violated, such evidence should be exposed within the observational uncertainties of dispersion measures, unless the WEP violation also depends on the inverse-square of the observed frequency. In this work, we constrain the difference of gamma parameters (Delta gamma) between photons with different energies using the observational uncertainties of FRB dispersion measures, where Delta gamma = 0 for Einstein's general relativity. Adopting the averaged 'Shapiro time delay' for cosmological sources, FRB 121002 at z = 1.6 1 0.3 and FRB 180817.J1533 + 42 at z = 1.0 1 0.2 place the most stringent constraints of log Delta gamma < -20.8 1 0.1 and log(Delta(gamma)/r(E)) < -20.9 1 0.2, respectively, where rE is the energy ratio between the photons. The former is about three orders of magnitude lower than those of other astrophysical sources in previous works under the same formalization of the Shapiro time delay while the latter is comparable to the tightest constraint so far.
AB - Fast radio bursts (FRBs) are astronomical transients with millisecond timescales occurring at cosmological distances. The observed time lag between different energies of each FRB is well described by the inverse-square law of the observed frequency, i.e., dispersion measure. Therefore, FRBs provide one of the ideal laboratories to test Einstein's weak equivalence principle (WEP): the hypothetical time lag between photons with different energies under a gravitational potential. If WEP is violated, such evidence should be exposed within the observational uncertainties of dispersion measures, unless the WEP violation also depends on the inverse-square of the observed frequency. In this work, we constrain the difference of gamma parameters (Delta gamma) between photons with different energies using the observational uncertainties of FRB dispersion measures, where Delta gamma = 0 for Einstein's general relativity. Adopting the averaged 'Shapiro time delay' for cosmological sources, FRB 121002 at z = 1.6 1 0.3 and FRB 180817.J1533 + 42 at z = 1.0 1 0.2 place the most stringent constraints of log Delta gamma < -20.8 1 0.1 and log(Delta(gamma)/r(E)) < -20.9 1 0.2, respectively, where rE is the energy ratio between the photons. The former is about three orders of magnitude lower than those of other astrophysical sources in previous works under the same formalization of the Shapiro time delay while the latter is comparable to the tightest constraint so far.
KW - REIONIZATION HISTORY
KW - TESTS
U2 - 10.1103/PhysRevD.104.124026
DO - 10.1103/PhysRevD.104.124026
M3 - Journal article
VL - 104
JO - Physical Review D
JF - Physical Review D
SN - 2470-0010
IS - 12
M1 - 124026
ER -
ID: 297015870