Controlling collective electronic states through clean and reversible external stimuli is crucial for realizing functional quantum materials. Here, we report a study on temperature (𝑇) and pressure (𝑃) -tuned charge-density-wave (CDW) orders in the quasi-one-dimensional system of NbSe₃, through single-crystal x-ray diffraction, and electric and magnetotransport measurements. A refined and extended phase diagram is presented, prompting a reevaluation of earlier claims regarding the coexistence of CDW and superconductivity (SC). Here, SC is found to emerge only once all long-range CDWs are suppressed. Notably, the anomalous Hall and magnetoresistance (MR) effects observed at low pressure (LP∼0. 8GPa) may arise from distinct carrier types associated with the two competing CDWs, CDW1 and CDW2. These two coexisting CDWs, characterized by distinct modulation vectors, 𝒒_𝟏 and 𝒒_𝟐, show pressure-induced opposing shifts in their 𝑏* axis projections (denoted as 𝑞^𝑏*₁ and 𝑞^𝑏*₂), while preserving a phase-coupling relationship 2 (𝒒_𝟏+𝒒_𝟐) ∼111. Upon gradual suppression of the long range order CDW2 order, 𝑞^𝑏*₁ of CDW1 stabilizes and enters a decoupled regime within ∼0. 8−1. 3 GPa, followed by a pronounced change in its periodicity between ∼1. 3 and 2. 9 GPa. Above 2. 9 GPa, all long-range CDW orders vanish, giving way to emergent superconductivity (SC).
Zhao et al. (Thu,) studied this question.
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