A single column is (usually) a pandas Series, and as EdChum mentioned, `DataFrame.apply`

has `axis`

argument but `Series.apply`

hasn't, so `apply`

on `axis=1`

wouldn't work on columns.

The following works:

```
df['col'].apply(lambda x, y: (x - y).total_seconds(), args=(d1,))
```

For applying a function for each element in a row, `map`

can also be used:

```
df['col'].map(lambda x: (x - d1).total_seconds())
```

As `apply`

is just a syntactic sugar for a Python loop, a list comprehension may be more efficient than both of them because it doesn't have the pandas overhead:

```
[(x - d1).total_seconds() for x in df['col'].tolist()]
```

For a single column DataFrame, `axis=1`

may be passed:

```
df[['col']].apply(lambda x, y: (x - y).dt.total_seconds(), args=[d1], axis=1)
```

#### PSA: Avoid `apply`

if you can

`apply`

is not even needed *most of the time*. For the case in the OP (and most other cases), a vectorized operation exists (just subtract `d1`

from the column - the value is broadcast to match the column) and is much faster than `apply`

anyway:

```
(df['col'] - d1).dt.total_seconds()
```

#### Timings

The vectorized subtraction is about 150 times faster than `apply`

on a column and over 7000 times faster than `apply`

on a single column DataFrame for a frame with 10k rows. As `apply`

is a loop, this gap gets bigger as the number of rows increase.

```
df = pd.DataFrame({'col': pd.date_range('2000', '2023', 10_000)})
d1 = df['col'].min()
%timeit df['col'].apply(lambda x, y: (x - y).total_seconds(), args=[d1])
# 124 ms ± 7.57 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)
%timeit df['col'].map(lambda x: (x - d1).total_seconds())
# 127 ms ± 16.8 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)
%timeit [(x - d1).total_seconds() for x in df['col'].tolist()]
# 107 ms ± 4.14 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)
%timeit (df['col'] - d1).dt.total_seconds()
# 851 µs ± 189 µs per loop (mean ± std. dev. of 7 runs, 1,000 loops each)
%timeit df[['col']].apply(lambda x, y: (x - y).dt.total_seconds(), args=[d1], axis=1)
# 6.07 s ± 419 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
```