Mercury sulfide Names IUPAC name Other names Identifiers ChemSpider ECHA InfoCard 100.014.270 EC Number UNII UN number 2025 Properties HgS Molar mass 232.66 g/mol Density 8.10 g/cm3 Melting point 580 °C (1,076 °F; 853 K) decomposes insoluble Band gap 2.1 eV (direct, α-HgS) [1] −55.4·10−6 cm3/mol w=2.905, e=3.256, bire=0.3510 (α-HgS) [2] Thermochemistry 78 J·mol−1·K−1[3] −58 kJ·mol−1[3] Hazards GHS labelling: Danger H300, H310, H317, H330, H373, H410 P261, P272, P280, P302+P352, P321, P333+P313, P363, P501 NFPA 704 (fire diamond) Flash point Non-flammable Safety data sheet (SDS) Fisher Scientific Related compounds Mercury oxidemercury selenidemercury telluride Zinc sulfidecadmium sulfide
Mercury sulfide or mercury(II) sulfide is a chemical compound composed of the chemical elements mercury and sulfur. It is represented by the chemical formula HgS. It is virtually insoluble in water.[4]
HgS is dimorphic with two crystal forms:
- red cinnabar (α-HgS, trigonal, hP6, P3221) is the form in which mercury is most commonly found in nature. Cinnabar has rhombohedral crystal system. Crystals of red are optically active. This is caused by the Hg-S helices in the structure.[5]
- black metacinnabar (β-HgS) is less common in nature and adopts the zinc blende crystal structure (T2d-F43m).
β-HgS precipitates as a black solid when Hg(II) salts are treated with H2S. The reaction is conveniently conducted with an acetic acid solution of mercury(II) acetate. With gentle heating of the slurry, the black polymorph converts to the red form.[6] β-HgS is unreactive to all but concentrated acids.[4]
Mercury is produced from the cinnabar ore by roasting in air and condensing the vapour.[4]
HgS → Hg + S
When α-HgS is used as a red pigment, it is known as cinnabar. The tendency of cinnabar to darken has been ascribed to conversion from red α-HgS to black β-HgS. However β-HgS was not detected at excavations in Pompeii, where originally red walls darkened, and was attributed to the formation of Hg-Cl compounds (e.g., corderoite, calomel, and terlinguaite) and calcium sulfate, gypsum.[7]
As the mercury cell as used in the chlor-alkali industry (Castner-Kellner process) is being phased out over concerns over mercury emissions, the metallic mercury from these setups is converted into mercury sulfide for underground storage.
With a band gap of 2.1 eV and its stability, it is possible to be used as photoelectrochemical cell.[8]
Neutralization with sulfur has been suggested to clean mercury spills, but the reaction does not proceed rapidly and completely enough for emergencies.[9]
- Mercury poisoning
- Mercury(I) sulfide (mercurous sulfide, Hg2S), hypothetical