Triglycine sulfate

Triglycine sulfate
Names
	IUPAC name Glycine sulfate (3:1)
	Other names Glycine sulfate; TGS
Identifiers
CAS Number	513-29-1 ;
3D model (JSmol)	Interactive image;
ChemSpider	10111;
ECHA InfoCard	100.007.414
EC Number	208-154-2;
PubChem CID	10551;
UNII	NEQ4Q0R0YA ;
CompTox Dashboard (EPA)	DTXSID40883415 ;
	InChI InChI=1S/3C2H5NO2.H2O4S/c33-1-2(4)5;1-5(2,3)4/h31,3H2,(H,4,5);(H2,1,2,3,4);
	SMILES O=C(O)CN.O=S(=O)(O)O.O=C(O)CN.O=C(O)CN;
Properties
Chemical formula	C6H17N3O10S
Molar mass	323.27 g·mol−1
Appearance	White powder
Density	1.69 g/cm3
Structure
Crystal structure	Monoclinic
Space group	P21
Lattice constant	a = 0.9417 nm, b = 1.2643 nm, c = 0.5735 nm α = 90°, β = 110°, γ = 90°
	Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa). Infobox references

Triglycine sulfate (TGS) is a chemical compound with a formula (NH₂CH₂COOH)₃·H₂SO₄. The empirical formula of TGS does not represent the molecular structure, which contains protonated glycine moieties and sulfate ions. TGS with protons replaced by deuterium is called deuterated TGS or DTGS; alternatively, DTGS may refer to doped TGS. By doping the DTGS with the amino acid L-Alanine, the crystal properties are improved and the new material is called Deuterated L-Alanine doped Triglycine Sulfate (DLATGS or DLTGS). These crystals are pyroelectric and ferroelectric which allows their use as photodetector elements in infrared spectroscopy and night vision applications.^[3] TGS detectors have also been used as the target in vidicon cathode ray imager tubes.

TGS has a critical point for the order parameter of polarization, at 322.5 K.^[4]

Crystal structure and properties

Crystal structure of TGS. Hydrogen atoms are not shown.^[2]

TGS crystals may be formed by evaporation of an aqueous solution of sulfuric acid and a greater than three-fold excess of glycine.^[5] They belong to the polar space group P2₁ and therefore are pyroelectric and ferroelectric at room temperature, exhibiting spontaneous polarization along the b-axis ([010] direction). The Curie temperature of the ferroelectric transition is 49 °C for TGS and 62 °C for DTGS. The crystal structure consists of SO₄²⁻, 2(N⁺H₃CH₂COOH) (G1 and G2 in the crystal-structure diagram), and ⁺NH₃CH₂COO⁻ (G3) species held together by hydrogen bonds.^[6] These bonds are easily broken by the polar molecules of water, which leads to the hygroscopicity of TGS – its crystals are easily etched by water. Along the b-axis, the G1-SO₄ and G2-G3 layers are stacked alternately. The nearest two neighboring layers with identical chemical composition are rotated 180° around the b-axis against each other.^[2]^[7] DTGS and DLATGS materials are derivatives of TGS which have better pyroelectric properties and give less detector noise as can be shown in the following table.

Ferroelectric properties of pure and doped triglycine sulfate crystal^[8]^[9]^[10]^[11]^[12]
Material	TGS	DTGS	DLATGS
Doping	-	D₂O as a solvent	20% wt. L-Alanine
Temperature of measurement (^oC)	25
Curie temperature (^oC)	49	57-62	58-62
Dielectric Constant at 1 kHz	22-35	18-22.5	18-22
Spontaneous Polarization (μC/cm²)	2.75	2.6	-
Coercive electric field (V/cm)	165 V/cm
Inherent bias field (kV/cm)	0.664-5	0.664-5	2-5
Dielectric loss tan δ	~1×10⁻³-10×10⁻³
Figure of Merits (FOMs) F_i =p (nC/cm².^oK) F_V =p/ε´ (nC/cm².^oK) F_D = p/√ε ′′ (nC/cm².^oK)	16-45 0.5-1.14 0.4-121	25-70 1.4 -	25 1.13 -
Volume Specific Heat (J/ cm³.^oK)	2.5	2.5	2.7
Density (g/cm³)	1.66	1.7	1.7
AC Resistivity at 1 kHz (Ω.cm×10¹⁰)	1.7	5	2.4

Typical performance of DLATGS detectors

The typical performance and pyroelectric properties of DLATGS detectors of 1.3 and 2.0 mm in diameter of the element size are shown in the table below.

Typical performance and pyroelectric properties of DLATGS detector^[13]^[14]^[15]
Element size (mm)		V_out at 1 kHz	Voltage responsivity V/W at 1 kHz	V_n at 1 kHz (1 Hz BW)	D* at 1 kHz Detectivity (cmHz1/2/W)	C (pF)	tan δ	NEP (W/√Hz)
1.3	Typical	3.20E-5	50	3.00E-8 Maximum	2.70E+8	10.6 (at 20 μm)	0.003	4.50E-10
2.0	Typical	3.20E-5	30	2.00E-8 Maximum	3.50E+8	25 (at 25 μm)	0.003	4.50E-10

References

^ Kwan-Chi Kao (2004). Dielectric phenomena in solids: with emphasis on physical concepts of electronic processes. Academic Press. pp. 318–. ISBN 978-0-12-396561-5. Retrieved 12 May 2011.
^ ^a ^b ^c Subramanian Balakumar and Hua C. Zeng (2000). "Water-assisted reconstruction on ferroelectric domain ends of triglycine sulfate (NH₂CH₂COOH)₃·H₂SO₄ crystals". J. Mater. Chem. 10 (3): 651–656. doi:10.1039/A907937H.
^ "Pyroelectric Detectors: Materials, Applications, and Working Principle" (PDF).
^ Gonzalo, J. A. (1966-04-15). "Critical Behavior of Ferroelectric Triglycine Sulfate". Physical Review. 144 (2): 662–665. Bibcode:1966PhRv..144..662G. doi:10.1103/PhysRev.144.662.
^ Pandya, G. R.; Vyas, D.D (1980). "Crystallization of glycine-sulfate". Journal of Crystal Growth. 5 (4): 870–872. Bibcode:1980JCrGr..50..870P. doi:10.1016/0022-0248(80)90150-5.
^ Choudhury, Rajul Ranjan; Chitra, R. (2008). "Single crystal neutron diffraction study of triglycine sulphate revisited". Pramana. 71 (5): 911–915. Bibcode:2009Prama..71..911C. doi:10.1007/s12043-008-0199-5. S2CID 122953651.
^ Wood, E.A.; Holden, A.N. (1957). "Monoclinic glycine sulfate: crystallographic data". Acta Crystallogr. 10 (2): 145–146. Bibcode:1957AcCry..10..145W. doi:10.1107/S0365110X57000481.
^ Aggarwal, M.D. (2010). Pyroelectric materials for uncooled infrared detectors : processing, properties, and applications. National Aeronautics and Space Administration, Marshall Space Flight Center. OCLC 754804811.
^ "Development of improved Pyroelectric Detectors" (PDF). ntrs.nasa.gov. 1972-02-29. Retrieved 2024-07-24.
^ "Pyroelectric materials" (PDF). www.ias.ac.in. Retrieved 2024-07-26.
^ Aravazhi, S; Jayavel, R; Subramanian, C (1997-10-15). "Growth and stability of pure and amino doped TGS crystals". Materials Chemistry and Physics. 50 (3): 233–237. doi:10.1016/S0254-0584(97)01939-1. ISSN 0254-0584.
^ Aggarwal, M.D.; Batra, A.K.; Guggilla, P.; Edwards, M.E.; Penn, B.G.; Currie Jr, J.R. "Pyroelectric materials for uncooled infrared detectors: processing, properties, and applications" (PDF). NASA Technical Memorandum.
^ Srinivasan, M. R. (1984-05-01). "Pyroelectric materials". Bulletin of Materials Science. 6 (2): 317–325. doi:10.1007/BF02743905. ISSN 0973-7669. S2CID 189911723.
^ Company, Leonardo. "DLATGS Detectors" (PDF). {{cite web}}: |last= has generic name (help)
^ Components, Laser. "D31 / LT31 Series Single Channel Voltage Mode Pyroelectric Detectors".

[1] Kwan-Chi Kao (2004). Dielectric phenomena in solids: with emphasis on physical concepts of electronic processes. Academic Press. pp. 318–. ISBN 978-0-12-396561-5. Retrieved 12 May 2011.

[j1-2] Subramanian Balakumar and Hua C. Zeng (2000). "Water-assisted reconstruction on ferroelectric domain ends of triglycine sulfate (NH₂CH₂COOH)₃·H₂SO₄ crystals". J. Mater. Chem. 10 (3): 651–656. doi:10.1039/A907937H.

[3] "Pyroelectric Detectors: Materials, Applications, and Working Principle" (PDF).

[4] Gonzalo, J. A. (1966-04-15). "Critical Behavior of Ferroelectric Triglycine Sulfate". Physical Review. 144 (2): 662–665. Bibcode:1966PhRv..144..662G. doi:10.1103/PhysRev.144.662.

[5] Pandya, G. R.; Vyas, D.D (1980). "Crystallization of glycine-sulfate". Journal of Crystal Growth. 5 (4): 870–872. Bibcode:1980JCrGr..50..870P. doi:10.1016/0022-0248(80)90150-5.

[6] Choudhury, Rajul Ranjan; Chitra, R. (2008). "Single crystal neutron diffraction study of triglycine sulphate revisited". Pramana. 71 (5): 911–915. Bibcode:2009Prama..71..911C. doi:10.1007/s12043-008-0199-5. S2CID 122953651.

[7] Wood, E.A.; Holden, A.N. (1957). "Monoclinic glycine sulfate: crystallographic data". Acta Crystallogr. 10 (2): 145–146. Bibcode:1957AcCry..10..145W. doi:10.1107/S0365110X57000481.

[8] Aggarwal, M.D. (2010). Pyroelectric materials for uncooled infrared detectors : processing, properties, and applications. National Aeronautics and Space Administration, Marshall Space Flight Center. OCLC 754804811.

[development-9] "Development of improved Pyroelectric Detectors" (PDF). ntrs.nasa.gov. 1972-02-29. Retrieved 2024-07-24.

[10] "Pyroelectric materials" (PDF). www.ias.ac.in. Retrieved 2024-07-26.

[11] Aravazhi, S; Jayavel, R; Subramanian, C (1997-10-15). "Growth and stability of pure and amino doped TGS crystals". Materials Chemistry and Physics. 50 (3): 233–237. doi:10.1016/S0254-0584(97)01939-1. ISSN 0254-0584.

[12] Aggarwal, M.D.; Batra, A.K.; Guggilla, P.; Edwards, M.E.; Penn, B.G.; Currie Jr, J.R. "Pyroelectric materials for uncooled infrared detectors: processing, properties, and applications" (PDF). NASA Technical Memorandum.

[13] Srinivasan, M. R. (1984-05-01). "Pyroelectric materials". Bulletin of Materials Science. 6 (2): 317–325. doi:10.1007/BF02743905. ISSN 0973-7669. S2CID 189911723.

[14] Company, Leonardo. "DLATGS Detectors" (PDF). {{cite web}}: |last= has generic name (help)

[15] Components, Laser. "D31 / LT31 Series Single Channel Voltage Mode Pyroelectric Detectors".

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Triglycine sulfate

Crystal structure and properties

Typical performance of DLATGS detectors

References

Information related to Triglycine sulfate

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