Speed Haze by Black Skull Seeds
Haze × Sativa-dominant hybrids
Speed Haze is a sativa-dominant strain from Black Skull Seeds, recognized for its rapid onset and stimulating effects. It offers a balanced profile that appeals to both recreational and medical users seeking enhanced energy and mental clarity.
Appearance
Speed Haze buds are visually appealing, characterized by a frosty coating of trichomes that give them a shimmering appearance. They typically exhibit shades of green, often with streaks of purple and orange pistils. The buds are moderately dense, contributing to efficient energy transfer during flowering.
Aroma & Flavor
The aroma of Speed Haze is a complex blend, starting with invigorating notes of citrus and spice, layered over earthy undertones. Upon tasting, users often experience a dominant citrus tanginess, followed by subtle herbal nuances and a lingering earthy richness, reminiscent of classic Haze strains.
Effects
This strain is known for its fast-acting and energizing impact, providing a significant mental uplift shortly after consumption. Users report experiencing heightened creativity and a sense of euphoria, making it suitable for daytime use when a boost in focus and inspiration is desired.
Terpenes & Cannabinoids
Speed Haze typically contains around 18% THC, with CBD levels below 1%. Its terpene profile often includes myrcene, limonene, and pinene, contributing to its distinct aroma and effects. Limonene is frequently noted as a dominant terpene, lending a strong citrus character.
Growing
Cultivating Speed Haze involves a flowering period of approximately 9-10 weeks. It is capable of producing substantial yields, potentially reaching up to 550 grams per square meter in indoor settings. The strain is noted for its robust growth and resin production.
Origins & Lineage
Bred by Black Skull Seeds, Speed Haze emerged in the mid-2010s, combining robust sativa genetics with classic Haze traits. It is estimated to be composed of 70-80% sativa and 20-30% indica, carefully selected to enhance energizing properties while minimizing potential over-stimulation.