The principal components of 0/1 data can fall off slowly or rapidly,
and the PCs of continuous data too —
it depends on the data. Can you describe your data ?

The following picture is intended to compare the PCs of continuous image data
vs. the PCs of the same data quantized to 0/1: in this case, inconclusive.

Look at PCA as a way of getting an approximation to a big matrix,

first with one term: approximate A ~ c U V^{T}, c [Ui Vj].

Consider this a bit, with A say 10k x 500: U 10k long, V 500 long.
The top row is c U1 V, the second row is c U2 V ...
all the rows are proportional to V.
Similarly the leftmost column is c U V1 ...
all the columns are proportional to U.

But if all rows are similar (proportional to each other),
they can't get near an A matix with rows or columns 0100010101 ...

With more terms, A ~ c1 U1 V1^{T} + c2 U2 V2^{T} + ...,
we can get nearer to A: the smaller the higher c_{i}, the faster..
(Of course, all 500 terms recreate A exactly, to within roundoff error.)

The top row is "lena", a well-known 512 x 512 matrix,
with 1-term and 10-term SVD approximations.
The bottom row is lena discretized to 0/1, again with 1 term and 10 terms.
I thought that the 0/1 lena would be much worse -- comments, anyone ?

(U V^{T} is also written U ⊗ V, called a "dyad" or "outer product".)

(The wikipedia articles
Singular value decomposition
and Low-rank approximation
are a bit math-heavy.
An AMS column by
David Austin,
We Recommend a Singular Value Decomposition
gives some intuition on SVD / PCA -- highly recommended.)