TY - JOUR
T1 - Anomalous Resistivity and Electron Heating by Lower Hybrid Drift Waves during Magnetic Reconnection with a Guide Field
AU - Yoo, Jongsoo
AU - Ng, Jonathan
AU - Ji, Hantao
AU - Bose, Sayak
AU - Goodman, Aaron
AU - Alt, Andrew
AU - Chen, Li Jen
AU - Shi, Peiyun
AU - Yamada, Masaaki
N1 - Publisher Copyright:
© 2024 American Physical Society. American Physical Society.
PY - 2024/4/5
Y1 - 2024/4/5
N2 - The lower hybrid drift wave (LHDW) has been a candidate for anomalous resistivity and electron heating inside the electron diffusion region of magnetic reconnection. In a laboratory reconnection layer with a finite guide field, quasielectrostatic LHDW (ES-LHDW) propagating along the direction nearly perpendicular to the local magnetic field is excited in the electron diffusion region. ES-LHDW generates large density fluctuations (δne, about 25% of the mean density) that are correlated with fluctuations in the out-of-plane electric field (δEY, about twice larger than the mean reconnection electric field). With a small phase difference (∼30°) between two fluctuating quantities, the anomalous resistivity associated with the observed ES-LHDW is twice larger than the classical resistivity and accounts for 20% of the mean reconnection electric field. After we verify the linear relationship between δne and δEY, anomalous electron heating by LHDW is estimated by a quasilinear analysis. The estimated electron heating is about 2.6±0.3 MW/m3, which exceeds the classical Ohmic heating of about 2.0±0.2 MW/m3. This LHDW-driven heating is consistent with the observed trend of higher electron temperatures when the wave amplitude is larger. Presented results provide the first direct estimate of anomalous resistivity and electron heating power by LHDW, which demonstrates the importance of wave-particle interactions in magnetic reconnection.
AB - The lower hybrid drift wave (LHDW) has been a candidate for anomalous resistivity and electron heating inside the electron diffusion region of magnetic reconnection. In a laboratory reconnection layer with a finite guide field, quasielectrostatic LHDW (ES-LHDW) propagating along the direction nearly perpendicular to the local magnetic field is excited in the electron diffusion region. ES-LHDW generates large density fluctuations (δne, about 25% of the mean density) that are correlated with fluctuations in the out-of-plane electric field (δEY, about twice larger than the mean reconnection electric field). With a small phase difference (∼30°) between two fluctuating quantities, the anomalous resistivity associated with the observed ES-LHDW is twice larger than the classical resistivity and accounts for 20% of the mean reconnection electric field. After we verify the linear relationship between δne and δEY, anomalous electron heating by LHDW is estimated by a quasilinear analysis. The estimated electron heating is about 2.6±0.3 MW/m3, which exceeds the classical Ohmic heating of about 2.0±0.2 MW/m3. This LHDW-driven heating is consistent with the observed trend of higher electron temperatures when the wave amplitude is larger. Presented results provide the first direct estimate of anomalous resistivity and electron heating power by LHDW, which demonstrates the importance of wave-particle interactions in magnetic reconnection.
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U2 - 10.1103/PhysRevLett.132.145101
DO - 10.1103/PhysRevLett.132.145101
M3 - Article
C2 - 38640378
AN - SCOPUS:85189329959
SN - 0031-9007
VL - 132
JO - Physical review letters
JF - Physical review letters
IS - 14
M1 - 145101
ER -