as for as iam concerned i think albert sir multiply m with C2 becoz when a mass moves with this velocity then it become in the form of energy.
a2 + b2 = c2. 62 + 82=c2. 36+64=c2. 100=c2. sqrt(100)=sqrt(c2). c=10. So the diagonal is 10 m. long.
E=m*c2
Multiply m by m.
The formula you use depends upon what you are trying to calculate. If you want to multiply two cells (e.g. A1 and C2), the formula would be =A1*C2.
Remember there are 1000 mm in 1 m To change 'mm' to 'm' multiply by its reciprocal. algebraically mm X 1/m
a2 + b2 = c2. 62 + 82=c2. 36+64=c2. 100=c2. sqrt(100)=sqrt(c2). c=10. So the diagonal is 10 m. long.
The full form isE = m c2
E=m*c2
Yes, and m= hf/c2 = h/cw.
The c2, which is the speed of light squared, is the conversion factor when making the conversion between mass and energy or vice versa. We see that E = mc2 and we can move the c2 to the other side. It will then be E/c2 = m. Whatever you're going to do, that is, whatever conversion you make, the c2 is the conversion factor in the operation.
Equivalence of mass and energy. E = m c2
e = m c2
It does, in the form of matter. E = m*c2
Multiply m by m.
Basically, you get less matter after both processes. The energy achieved can be calculated by E = m*c2. E = Energy. m = the mass "disappeared". c2 = speed of light squared.
The formula you use depends upon what you are trying to calculate. If you want to multiply two cells (e.g. A1 and C2), the formula would be =A1*C2.
Remember there are 1000 mm in 1 m To change 'mm' to 'm' multiply by its reciprocal. algebraically mm X 1/m