Boron-doped few-layer graphene nanosheet gas sensor for enhanced ammonia sensing at room temperature

Abstract: A boron-doped few-layer LPCVD graphene sensor is successfully designed and demonstrated for enhanced NH3 gas sensing applications.

“…Foreign dopant atoms can alter the properties of graphene. Hence, doping has further opened the door to many graphene-based applications including electronics [38] and sensing [39] owing to the distinct nature of each dopant. [40,41] These impurity atoms display unique bonding configurations in the graphene lattice (see Figure 1i), endowing the graphene with distinctive properties.…”

“…For highly sensitive sensors of ammonia, Srivastava et al found that B-doped graphene exhibited speedy response (high sensitivity) to ammonia and immediate recovery. [39] The determination of hydrogen peroxide (H 2 O 2 ) has significance in both the industry and biological reactions. Zhang et al proposed a composite system (Co 3 O 4 decorated N-doped graphene) for fast, accurate, and reliable detection of H 2 O 2 .…”

“…The as‐grown sample was few‐layered according to Raman analysis, whereas the XPS result revealed two dominant bonding configurations (BC 3 (graphitic form) and BC 4 ) with a doping concentration up to 4.9 at%. [ 39 ] Incorporation of boron into the graphene framework has also been achieved via a two‐step CVD procedure. Pristine graphene is deposited by CVD, transferred to a target substrate, and then treated with a boron source solution.…”

“…found that B‐doped graphene exhibited speedy response (high sensitivity) to ammonia and immediate recovery. [ 39 ] The determination of hydrogen peroxide (H 2 O 2 ) has significance in both the industry and biological reactions. Zhang et al.…”

Advances and Trends in Chemically Doped Graphene

“…Foreign dopant atoms can alter the properties of graphene. Hence, doping has further opened the door to many graphene-based applications including electronics [38] and sensing [39] owing to the distinct nature of each dopant. [40,41] These impurity atoms display unique bonding configurations in the graphene lattice (see Figure 1i), endowing the graphene with distinctive properties.…”

“…For highly sensitive sensors of ammonia, Srivastava et al found that B-doped graphene exhibited speedy response (high sensitivity) to ammonia and immediate recovery. [39] The determination of hydrogen peroxide (H 2 O 2 ) has significance in both the industry and biological reactions. Zhang et al proposed a composite system (Co 3 O 4 decorated N-doped graphene) for fast, accurate, and reliable detection of H 2 O 2 .…”

“…The as‐grown sample was few‐layered according to Raman analysis, whereas the XPS result revealed two dominant bonding configurations (BC 3 (graphitic form) and BC 4 ) with a doping concentration up to 4.9 at%. [ 39 ] Incorporation of boron into the graphene framework has also been achieved via a two‐step CVD procedure. Pristine graphene is deposited by CVD, transferred to a target substrate, and then treated with a boron source solution.…”

“…found that B‐doped graphene exhibited speedy response (high sensitivity) to ammonia and immediate recovery. [ 39 ] The determination of hydrogen peroxide (H 2 O 2 ) has significance in both the industry and biological reactions. Zhang et al.…”

Advances and Trends in Chemically Doped Graphene

“…The results obtained indicated a new strategy to construct handy and quick gas sensing devices based on BFLGr. 51 2.1.4 Biosensors. Mannan et al synthesized GO using a modied Hummers method and successful boron doping (1.64-1.83%) was executed with boric acid as a precursor by hydrothermal reaction.…”

Heteroatom-doped graphene as sensing materials: a mini review

Spectroscopic Characterization of Graphitic Nanomaterials and Metal Oxides for Gas Sensing