Fusi Nuklir

Fuelling the Fusion Reaction

Although different isotopes of light elements can be paired to achieve fusion, the Deuterium-Tritium (D-T) reaction has been identified as the most efficient for fusion devices. ITER and the future demonstration power plant DEMO will use this combination of elements to fuel the fusion reaction.

Deuterium can be distilled from all forms of water. It is a widely available, harmless, and virtually inexhaustible resource. In every litre of seawater, for example, there are 33 milligrams of Deuterium. Deuterium is routinely produced for scientific and industrial applications.

Tritium is a fast-decaying radioelement of Hydrogen which occurs only in trace quantities in nature. It is produced during operation in a certain type of fission reactor (Candu). It can also be produced during the fusion reaction through contact with Lithium: Tritium is produced, or 'bred', when neutrons escaping the plasma interact with Lithium contained in the blanket wall of the tokamak.

Global inventory for Tritium is presently around twenty kilos, which ITER will draw upon during its operational phase. The concept of 'breeding' Tritium within the fusion reaction is an important one for the future needs of a large-scale fusion power plant.

Test Breeding Modules

In a tokamak, blanket modules coat the inside of the chamber and directly face the hot plasma. In ITER, certain modules will be used to test Tritium breeding concepts. Photo: Tore Supra Tokamak, CEA Cadarache.

In the Deuterium-Tritium (D-T) fusion reaction, high energy neutrons are released along with Helium atoms. These electrically-neutral particles escape the plasma contained within the magnetic fields of the tokamak and are absorbed by the 'blanket modules' of the surrounding walls. If these blanket modules contain Lithium, a reaction occurs: the incoming neutron is absorbed by the Lithium atom, which recombines into an atom of Tritium and an atom of Helium. The Tritium can then be removed from the blanket and recycled into the plasma as fuel.

Blankets containing Lithium are thus considered "Breeding Blankets". Within the fusion reaction, Tritium can be 'bred' indefinitely. Once the fusion reaction is established in the ITER tokamak, Deuterium and Lithium are the external fuels required to sustain it. Both of these fuels are readily available.

Deuterium can be supplied by industry. Lithium is plentiful in the Earth's crust: if fusion were to provide electricity for the entire world, known reserves of Lithium would last for at least one thousand years.

A future fusion plant producing large amounts of power will be required to breed all of its own Tritium. ITER will test this essential concept of Tritium self-sustainment.

Small quantities of fuel

Some of the key features of fusion make it an attractive option as part of a future energy mix. Fusion fuels are abundantly available and inherently safe. Only tiny amounts of Deuterium and Tritium are necessary to fuel the fusion reaction: just a few grams are present in the plasma at any one time.

In fact, a fusion reaction is about four million times more energetic than a chemical reaction such as the burning of coal, oil or gas. While a 1 000 MW coal-fired power plant requires 2.7 million tons of coal per year, a fusion plant of the kind envisioned for the second half of this century will only require 250 kilos of fuel per year, half of it Deuterium, half of it Tritium.

In addition, fusion emits no pollution or greenhouse gases. Its major by-product is Helium: an inert, non-toxic gas. There is no possibility of a 'run-away' reaction because the conditions for fusion are precise - any alteration in these conditions and the plasma cools within seconds and the reaction stops. Fusion has the capacity to furnish large-scale quantities of energy, with a low burden of waste for future generations.

Sumber:

Web Resmi ITER

Teknokimia Nuklir

Ruang lingkup atau bidang kerja sarjana teknokimia adalah penelitian proses, pengembangan proses, rekayasa proses dan analisis ekonomi, proyek keteknikan, teknik konstruksi, teknik operasi dan teknik pemasaran hasil (dari Harper, J.I., 1954, “Chemical Engineering in Practice)

Tujuan Pendidikan Program Teknokimia Nuklir bertujuan untuk:

1. Mendidik dan memberi bekal kemampuan keilmuan dalam bidang proses kimia yang menerapkan teknologi nuklir (teknokimia nuklir) dan digunakan oleh industri kimia bahan nuklir (instalasi nuklir).

2. Meningkatkan kemampuan/ketrampilan dalam mengerjakan tugas-tugas bidang teknokimia di lembaga penelitian dan industri, meliputi perencanaan, pelaksanaan, dan evaluasi data.

3. Meningkatkan ketrampilan berfikir dalam bidang Teknokimia Nuklir yang meliputi pemilihan dan pengembangan proses, scale up, serta pemilihan dan perawatan peralatan proses

4. Meningkatkan kemampuan untuk menyesuaikan dengan perkembangan ilmu pengetahuan dan teknologi.

5. Meningkatkan kemampuan berkomunikasi secara efektif.

6. Mengembangkan sikap dan kebiasaan-kebiasaan sebagai berikut :

1. Bekerja secara efisien dan efektif;

2. Bekerja sesuai prosedur yang benar, memperhatikan keselamatan diri dan lingkungan;

3. Keingintahuan (curiousity) informasi, spesifikasi, metode, dan hasil;

4. Bertanggung jawab untuk memperoleh hasil yang bermanfaat;

5. Bekerja sama untuk tujuan dan hasil yang lebih baik dan benar;

6. Eksperimen adalah arbiter yang terakhir;

7. Menjunjung tinggi etika profesi dan moral.