TY - JOUR
T1 - Assessment of cathode active materials from the perspective of integrating environmental impact with electrochemical performance
AU - Yu, Yajuan
AU - Wang, Dong
AU - Huang, Kai
AU - Wang, Xiang
AU - Liang, Yuhan
AU - Sun, Weijun
AU - Chen, Bo
AU - Chen, Shi
PY - 2014/11/1
Y1 - 2014/11/1
N2 - A method was brought forward for assessing cathode active materials from a perspective that accounts for the environmental impact and the electrochemical performance. Then the integrated performance, referred to as the "final environmental impact", was quantified into a dimensionless score, EI c (see Eq. (2)). Subsequently, four types of cathode active materials- LiFePO4/C, LiFe0.98Mn0.02PO 4/C, LiFe0.98Ti0.02PO4/C, and FeF3(H2O)3/C- were assessed. The results were: (1) the EIc sequence was LiFePO4/C (1.76E-02Pt) > LiFe0.98Ti 0.02PO4/C (1.74E-02 Pt) > LiFe0.98Ti 0.02PO4/C (1.66E-02Pt) >FeF3(H 2O)3/C (4.98E-03 Pt), which meant FeF3(H 2O)3/C was the optimal material and had the minimal final environmental impact. (2) With regard to the eleven impact categories, the category respiratory effects exerted by inorganics made up the largest percentage of the EIc for the four materials. (3) In the aspects of EIm (EI (Eco-indicator) value of a 1 kg cathode active material), average specific discharge capacity, and cycle life, the sub-optimal materials' sequence of theoretical potential for optimization was as follows: LiFe 0.98Ti0.02PO4/C > LiFe0.98Mn 0.02PO4/C > LiFePO4/C. This meant that the final environmental impact of LiFePO4/C was the most difficult to reduce, and the impact of LiFe0.98Ti0.02PO4/C could not be reduced very easily. (4) To reduce the final environmental impact, the following concrete measures were recommended: (a) the optimization of the synthesis processes for smaller particle diameters; (b) the adoption of other surface-coating agents, utilizing (other) dopants; (c) the substitution of the energy-efficient instruments for the energy-intensive instruments; (d) the optimization of the synthesis processes to contain fewer electricity-intensive steps.
AB - A method was brought forward for assessing cathode active materials from a perspective that accounts for the environmental impact and the electrochemical performance. Then the integrated performance, referred to as the "final environmental impact", was quantified into a dimensionless score, EI c (see Eq. (2)). Subsequently, four types of cathode active materials- LiFePO4/C, LiFe0.98Mn0.02PO 4/C, LiFe0.98Ti0.02PO4/C, and FeF3(H2O)3/C- were assessed. The results were: (1) the EIc sequence was LiFePO4/C (1.76E-02Pt) > LiFe0.98Ti 0.02PO4/C (1.74E-02 Pt) > LiFe0.98Ti 0.02PO4/C (1.66E-02Pt) >FeF3(H 2O)3/C (4.98E-03 Pt), which meant FeF3(H 2O)3/C was the optimal material and had the minimal final environmental impact. (2) With regard to the eleven impact categories, the category respiratory effects exerted by inorganics made up the largest percentage of the EIc for the four materials. (3) In the aspects of EIm (EI (Eco-indicator) value of a 1 kg cathode active material), average specific discharge capacity, and cycle life, the sub-optimal materials' sequence of theoretical potential for optimization was as follows: LiFe 0.98Ti0.02PO4/C > LiFe0.98Mn 0.02PO4/C > LiFePO4/C. This meant that the final environmental impact of LiFePO4/C was the most difficult to reduce, and the impact of LiFe0.98Ti0.02PO4/C could not be reduced very easily. (4) To reduce the final environmental impact, the following concrete measures were recommended: (a) the optimization of the synthesis processes for smaller particle diameters; (b) the adoption of other surface-coating agents, utilizing (other) dopants; (c) the substitution of the energy-efficient instruments for the energy-intensive instruments; (d) the optimization of the synthesis processes to contain fewer electricity-intensive steps.
KW - Cathode active material
KW - Electrochemical performance
KW - Li-ion battery
KW - Life cycle assessment
UR - http://www.scopus.com/inward/record.url?scp=84905912300&partnerID=8YFLogxK
U2 - 10.1016/j.jclepro.2014.06.069
DO - 10.1016/j.jclepro.2014.06.069
M3 - Article
AN - SCOPUS:84905912300
SN - 0959-6526
VL - 82
SP - 213
EP - 220
JO - Journal of Cleaner Production
JF - Journal of Cleaner Production
ER -