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Abstract

We present James Webb Space Telescope (JWST) near-infrared (NIRCam) Br$\alpha$, H$_2$, [Fe II], and PAH imaging of the molecule-rich, high-excitation bipolar planetary nebula (PN) NGC 6537 (the Red Spider), complemented by new ALMA and Chandra observations and archival HST images. The resulting multiwavelength view of the Red Spider establishes the detailed lobe/torus structure of the nebula and the mass-loss history of its progenitor star. The extinction-penetrating JWST/NIRCam Br$\alpha$ and PAH and ALMA 3 mm continuum imaging exposes the complexity of the ionized inner nebula. JWST/NIRCam H$_2$ imaging traces the full, $\sim$1.1 pc extent of the bubble-like lobes formed by fast ($\sim$300-400 km s$^{-1}$) polar outflows, while ALMA $^{13}$CO(1-0) mapping reveals a point-symmetric, slowly ($\sim$10 km s$^{-1}$) expanding equatorial torus of radius $\sim$0.13 pc. In striking contrast, the [Fe II] image displays an extended S-shaped emission morphology that traces collisions between an active, collimated wind and slower-moving material along the lobe rims. No X-rays are detected from the nebula or its central star in deep Chandra/HRC-I imaging. However, the combined HST and JWST imaging reveals a near-IR excess at the central star indicative of emission from hot ($\sim$1000 K) circumstellar dust. We propose that interactions between the nebular progenitor star and a close companion are responsible for the ejection of NGC 6537's molecular torus, the formation of a circumbinary dust disk, and the launching of fast, wandering, collimated outflows that have inflated the polar lobe bubbles traced by near-IR H$_2$ emission and are presently generating the [Fe II]-emitting shocks.