Solid-state NMR spectroscopy has played a significant role in elucidating the structure and dynamics of materials and biological solids at a molecular level for decades. In particular, the H-1 double-quantum/single-quantum (DQ/SQ) chemical shift correlation experiment is widely used for probing the proximity of protons, rendering it a powerful tool for elucidating the hydrogen-bonding interactions and molecular packing of various complex molecular systems. Two factors, namely, the DQ filtering efficiency and t(1)-noise, dictate the quality of the 2D H-1 DQ/SQ spectra. Experimentally different recoupling sequences show varied DQ filtering efficiencies and t(1) noise. Herein, after a systematic search of symmetry-based DQ recoupling sequences, we report that the symmetry-based gamma-encoded RN(n)(nu)sequences show superior performance to other DQ recoupling sequences, which not only have a higher DQ recoupling efficiency but can also significantly reduce t(1)-noise. The origin of t(1)-noise is further discussed in detail via extensive numerical simulations. We envisage that such gamma-encoded RN nu n sequences are superior candidates for DQ recoupling in proton based solid-state NMR spectroscopy due to its capability of efficiently exciting DQ coherences and suppressing t(1)-noise.

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