Complex thermal kinetic study of calcium phosphate biomaterial CaHPO4 using the asymmetric deconvolution approach

“…In this application, “deconvolution” refers to the resolution of overlapping rate peaks into individual rate peaks that may be assumed to reflect individual response steps [44] . The shoulder peak in AP, AP+BCC, and AP+BCC/rGO was deconvoluted and the average activation energy of the decomposition of various compositions is reported in Figure 10 [45] . The conversion of decomposition of pure AP and NTO was completed within temperatures 571–698 K and 537–549 K, respectively.…”

“…[44] The shoulder peak in AP, AP + BCC, and AP + BCC/rGO was deconvoluted and the average activation energy of the decomposition of various compositions is reported in Figure 10. [45] The conversion of decomposition of pure AP and NTO was completed within temperatures 571-698 K and 537-549 K, respectively. Compared to the conversion of pure AP and NTO the conversion of the decomposition of NTO + BCC, NTO + BCC/rGO, AP + BCC, and AP + BCC/rGO was completed at a lower temperature which was also evident from TG analysis.…”

Effects of Barium‐Copper‐Cobalt oxide composites supported on reduced graphene oxide in the thermolysis of ammonium perchlorate and 3‐nitro‐1,2,4‐triazol‐5‐one

“…In this application, “deconvolution” refers to the resolution of overlapping rate peaks into individual rate peaks that may be assumed to reflect individual response steps [44] . The shoulder peak in AP, AP+BCC, and AP+BCC/rGO was deconvoluted and the average activation energy of the decomposition of various compositions is reported in Figure 10 [45] . The conversion of decomposition of pure AP and NTO was completed within temperatures 571–698 K and 537–549 K, respectively.…”

“…[44] The shoulder peak in AP, AP + BCC, and AP + BCC/rGO was deconvoluted and the average activation energy of the decomposition of various compositions is reported in Figure 10. [45] The conversion of decomposition of pure AP and NTO was completed within temperatures 571-698 K and 537-549 K, respectively. Compared to the conversion of pure AP and NTO the conversion of the decomposition of NTO + BCC, NTO + BCC/rGO, AP + BCC, and AP + BCC/rGO was completed at a lower temperature which was also evident from TG analysis.…”

Effects of Barium‐Copper‐Cobalt oxide composites supported on reduced graphene oxide in the thermolysis of ammonium perchlorate and 3‐nitro‐1,2,4‐triazol‐5‐one

“…On further heating, the produced DCPA dehydrates to form calcium diphosphate (Ca 2 P 2 O 7 ; calcium pyrophosphate (CPP)). [17][18][19][20][21][22] Some studies have reported a single-step process of the thermal dehydration of DCPA, 17,21 whereas some others have reported a two-step mass loss process. [18][19][20]22 Hazzat et al explained the cause of the two-step mass loss process and attributed it to the different sizes and morphologies of sample particles in commercially available DCPA.…”

“…[17][18][19][20][21][22] Some studies have reported a single-step process of the thermal dehydration of DCPA, 17,21 whereas some others have reported a two-step mass loss process. [18][19][20]22 Hazzat et al explained the cause of the two-step mass loss process and attributed it to the different sizes and morphologies of sample particles in commercially available DCPA. 22 Irrespective of different reaction behaviors, the solid product was identified as γ-CPP.…”

“…[18][19][20]22 Hazzat et al explained the cause of the two-step mass loss process and attributed it to the different sizes and morphologies of sample particles in commercially available DCPA. 22 Irrespective of different reaction behaviors, the solid product was identified as γ-CPP. Therefore, the quantitative evaluation of changes in multistep reaction behavior occurring during the thermal dehydration of DCPD and subsequent dehydration of DCPA using an advanced kinetic approach could provide more insight into the complex reaction behaviors of the thermally induced transformations of DCPD.…”

Physico-geometrical kinetic insight into multistep thermal dehydration of calcium hydrogen phosphate dihydrate

Thermal dehydration kinetics of 4CaO·5B2O3·7H2O with different phases and morphologies