410441
*6/ pack *12/ case 410451
*6/ pack *12/ case 410461
*6/ pack *12/ case 410471
*4/ case *8/ load 410481
*2/ case *4/ load 410491
*2/ load *4/ load 410501
*2/ skid *4/ skid 410511
*2/ skid *4/ skid 410521
*2/ load *3/ load
🔆
63
56
50
34
30
27
22
16
13
.15
.03
.82
.01
.35
.27
.80
.30
.75
239 212 192 128 114 103 86 61 52
.04 .08 .36 .73 .87 .22 .32 .72 .03
💧
60
54
49
32
29
25
22
16
13
.62
.91
.80
.95
.29
.86
.24
.20
.72
229 207 188 124 110 97 84 61 51
.48 .84 .51 .73 .87 .89 .19 .32 .95
🍅
48
42
38
27
24
21
18
16
13
.50
.83
.35
.40
.85
.41
.35
.09
.70
183 162 145 103 94 81 69 60 51
.58 .11 .15 .73 .07 .06 .46 .92 .86
🌱
You're likely to be among the 91.7% of growers who use bloom boosters every bloom cycle, so it's natural for you to want to be sure that your boosters give you the biggest yields possible for your garden.
To be precise, you look for bloom booster effects that include:
Larger, heavier, denser flowers
Flowers with more essential oils, aromatics, terpenoids, phenols and other potency factors.
Measurable, significant increases in overall harvest weight and market value.
How do most bloom boosters stack up in meeting these goals? Not as well as they could. In fact, until recently poorly-absorbed forms of phosphorus and potassium (P and K) were the main ingredients in most bloom boosters.
Worse yet, almost all bloom boosters have incorrect ratios or types of phosphorus and potassium. Most bloom boosters provide double the amount of phosphorus to potassium. That's not useful. Your plants are much hungrier for potassium than for phosphorus during bloom phase.