Designing and facilely synthesizing a series of cobalt nitride (CoN) nanocatalysts as non-enzymatic glucose sensors: A comparative study toward the influences of material structures on electrocatalytic activities.

Title Designing and facilely synthesizing a series of cobalt nitride (CoN) nanocatalysts as non-enzymatic glucose sensors: A comparative study toward the influences of material structures on electrocatalytic activities.
Authors T. Liu; M. Li; L. Guo
Journal Talanta
DOI 10.1016/j.talanta.2017.12.082
Abstract

Designing high-efficiency electrocatalysts for glucose concentration detection plays a pivotal role in developing various non-enzymatic glucose detection devices. Herein, we have successfully designed and synthesized various cobalt nitrides (CoN) by using different weak bases (i.e. hexamethylenetetramine (HMT), urea, and ammonium hydroxide (AH)) through nitridation treatment in ammonia (NH) atmosphere. Physical characterization results demonstrate that CoN-NSs (nanosheets) with vast meso/macropores and large BET surface are successfully constructed once adding carbon paper and HMT into precursors. As the synergistic effect of metallic character of CoN phaseexcellent electroconductibility of pyrolytic carbon, and large surface area, CoN-NSs surfaces can form more Coactive sites in electrochemical reaction processes. Meanwhile, the abundant meso/macroporous structures constructed in CoN-NSs further promoted its mass transfer ability. Benefitting from the above mentioned advantages, CoN-NSs therefore exhibit more excellent glucose oxidation ability than another three control samples (i.e. CoN-HMT, CoN-Urea and CoN-AH). When used for glucose detection, the optimal CoN-NSs display excellent detection parameters as well, such as: a wide linear range of 0.6-10.0mM, a large sensitivity of 1137.2uAcmmMglucose, a low detection limit of 0.1µM, a small response time of 1.7s, good reproducibility and stability, and the excellent anti-interference to other electroactive molecules and Cl. Upon utilized for measuring glucose concentrations in human blood serum samples, the detection results on CoN-NSs are accurate and satisfying as well. This work opens a new possibility for boosting electrochemical catalysis abilities of CoN samples by the structure design.

Citation T. Liu; M. Li; L. Guo.Designing and facilely synthesizing a series of cobalt nitride (CoN) nanocatalysts as non-enzymatic glucose sensors: A comparative study toward the influences of material structures on electrocatalytic activities.. Talanta. 2018;181:154164. doi:10.1016/j.talanta.2017.12.082

Related Elements

Cobalt

See more Cobalt products. Cobalt (atomic symbol: Co, atomic number: 27) is a Block D, Group 9, Period 4 element with an atomic weight of 58.933195. Cobalt Bohr ModelThe number of electrons in each of cobalt's shells is 2, 8, 15, 2 and its electron configuration is [Ar]3d7 4s2. The cobalt atom has a radius of 125 pm and a Van der Waals radius of 192 pm. Cobalt was first discovered by George Brandt in 1732. In its elemental form, cobalt has a lustrous gray appearance. Cobalt is found in cobaltite, erythrite, glaucodot and skutterudite ores. Elemental CobaltCobalt produces brilliant blue pigments which have been used since ancient times to color paint and glass. Cobalt is a ferromagnetic metal and is used primarily in the production of magnetic and high-strength superalloys. Co-60, a commercially important radioisotope, is useful as a radioactive tracer and gamma ray source. The origin of the word Cobalt comes from the German word "Kobalt" or "Kobold," which translates as "goblin," "elf" or "evil spirit.

Nitrogen

See more Nitrogen products. Nitrogen is a Block P, Group 15, Period 2 element. Its electron configuration is [He]2s22p3. Nitrogen is an odorless, tasteless, colorless and mostly inert gas. It is the seventh most abundant element in the universe and it constitutes 78.09% (by volume) of Earth's atmosphere. Nitrogen was discovered by Daniel Rutherford in 1772.

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