Difference between revisions of "TIE Rhodium"

TIE/rh Rhodium
Production Information
Manufacturer:	EH Science Office & Tusorix Government Engineers
Product Line:	TIE Series
Model:	Modified TIE Interceptor
Class:	Interceptor
Technical Specifications
Length:	7.7 m
Width:	8.9 m
Height & Depth:	4.8 m
Engine Units:	SFS P-sz9.7 Twin Ion Engines
Hyperdrive Rating:	Class 1.5
Power Output:	180 MGLT
Armaments:	SFS L-s9.3 Laser Cannons (4) SFS M-g-2 General-Purpose Warhead Launchers (2)
Crew:	1
Passengers:	0
Fleet Information
Affiliation:	Rho Squadron
[ Source ]

The TIE/rh Rhodium is a modified version of the TIE/IN Interceptor that was specially created for Rho Squadron. With a hull plated in a custom alloy of quadanium steel and rhodium, a rare metal found on Tusorix, the TIE Rhodium has several unique characteristics that make it one of the deadliest craft in the Emperor's Hammer fleet. During it’s service history, Rho Squadron has been the only user of the Rhodium, with only 12 such craft being built.

Characteristics

Hull

The TIE/rh Rhodium’s hull is plated in an alloy of rhodium metal and quadanium steel. Quadanium is the typical metal used in TIE construction. Rhodium is a rare metal with a vast array of properties and characteristics, including: - Alloys with other metals without detriment to characteristics - Strong, resisting physical damage - Special molecular lattice that dissipates energy - High heat resistance

The unique traits of rhodium allow for multiple abilities and characteristics that, when alloyed with quadanium, alter the behavior and capabilities of the TIE/rh. Some of these include:

1. The craft can disperse ionization and laser cannon energy, taking less damage. Due to the energy dispersion characteristic of rhodium, the ship is entirely unable to be impaired by ion lasers, scattering the constituent ions through the unique molecular lattice and rendering the effects negligible. This allows for easier assaults on craft with ion weaponry and prevents the TIE/rh from being disabled. This energy dispersion also affects laser cannon energy to a lesser effect. Partial amounts of the laser energy are scattered through the lattice, specifically the ion elements, somewhat lessening the damage inflicted and increasing the ship’s survivability.

2. The craft has a much stronger hull plating. Because of the rhodium alloy, the ship’s hull has significantly increased durability and is capable of withstanding greater laser and missile damage than a comparable vessel. The hull is rated an astounding 32 RU due to this breakthrough rhodium alloy, thus allowing pilots to focus more energy management to strike patterns than defensive patterns, and restore the system balance during retreat maneuvers.

3. The craft suffers less heat-related impairments to both hull and modules. The rhodium alloy has been used in both the hull and the heat-sensitive modules of the TIE/rh. As rhodium is an exquisitely efficient heat-resistant insulator, the craft can fly closer to sources of heat without worry. Examples include nebulae, stars, and planetary re-entry. In addition, the fighter’s weapon systems, twin ion engines, and other systems also suffer less heat-related wear and tear which allows for increased thruster performance, boosted thruster output and speed, and increased firing duration of the laser cannons.

4. The rhodium alloy adds no mass to the ship. Normally, a stronger metal plating on the chassis of a craft would increase mass dramatically, which could be detrimental to an interceptor-styled craft. Thanks to precision engineering, the rhodium and quadanium alloy has been crafted to be consistent with the payload of the average TIE craft.

Chassis Structure

The custom chassis of the TIE/rh is inspired by Tusorixian origins. When compared to its closest visual relative, the TIE/IN Interceptor, the craft sports four extra wings. This modification provides a massive amount of solar-collecting area which is critical to the performance of the TIE/rh. The extra solar-collection wings supply additional power for a shield generator, boosted thrusters, and increased laser performance, as well as a navigational computer subroutine to monitor the flight plan and hyperspace adjustments relative to the current orientation. These ancillary wings, borne of the traditional Tusorizian designs, also contribute to heightened in-atmosphere maneuvering stability, allowing for tighter roll maneuvers, a higher opportunity for firing solutions, and less overall time with the craft's flanks exposed.

Role

The TIE/rh’s unique rhodium-based characteristics allow for increased hull strength and superb heat and energy dissipation, leading to the craft’s improved durability, resistance to energy weapons, ion neutralization, increased firing duration, and superior thruster performance. These features give the craft a remarkable edge in combat situations. Moreover, the heat-dissipating properties of the alloy permit the TIE/rh to increase its tolerance for a broader range of engagement scenarios, from interstellar radiation sources to atmospheric entry and escape friction.

The chassis design and additional solar energy collection allow the craft to achieve a standard of performance that is unrivaled. This affords the TIE/rh maneuverability, reaction time, and power management that outperforms any standard issue ship. Likewise, the custom navigation computer’s realtime hyperlane computations equip the TIE/rh with the fastest theater of operation extraction times available in a fighter craft.

A pilot with mastery of the TIE/rh Rhodium can wield the ship’s unique abilities to become near-unstoppable in dogfights as well as pose a formidable threat against larger ships.

Technical Specifications